COLD CATHODES FOR APPLICATIONS IN POOR VACUUM AND LOW 
PRESSURE GAS ENVIRONMENTS: CARBON NANOTUBES 
VERSUS ZINC OXIDE NANONEEDLES 
 
 
                                         
                                         
Except where reference is made to the work of others, the work described in this thesis is 
my own or was done in collaboration with my advisory committee. This thesis does not 
include proprietary or classified information. 
 
 
 
 
 
 
 
An-jen Cheng 
 
 
Certificate of Approval: 
 
 
 
 
 
Richard C. Jaeger                                                   Yonhua Tzeng, Chair 
Distinguished University Professor                        Professor 
Electrical and Computer Engineering                    Electrical and Computer Engineering 
 
 
 
                        
Minseo Park                                                            Stephen L. McFarland 
Assistant Professor                                                 Acting Dean 
Physics                                                                   Graduate School 
 
COLD CATHODES FOR APPLICATIONS IN POOR VACUUM AND LOW 
PRESSURE GAS ENVIRONMENTS: CARBON NANOTUBES 
VERSUS ZINC OXIDE NANONEEDLES 
 
 
 
 
An-jen Cheng 
 
 
A Thesis 
Submitted to 
the Graduate Faculty of 
Auburn University 
in Partial Fulfillment of the 
Requirement for the 
Degree of 
Master of Science 
 
 
 
Auburn, Alabama 
May 11, 2006 
COLD CATHODES FOR APPLICATIONS IN POOR VACUUM AND LOW 
PRESSURE GAS ENVIRONMENTS: CARBON NANOTUBES 
VERSUS ZINC OXIDE NANONEEDLES 
 
 
An-jen Cheng 
 
Permission is granted to Auburn University to make copies of this thesis at its direction, 
upon the request of individuals or institutions and at their expense. The author reserves 
all the publication rights 
 
 
 
                                                                                                 Signature of Author 
 
 
                                                                                                 Date of Graduation 
 
 
 
 
 
 iii
 iv
VITA 
    An-jen Cheng, son of En-Jer Jang (Cheng) and Chin-hua Chen, was born on April 26, 
1980, in Tainan, Republic of China, Taiwan. He entered Physics Department, Chun-Yuan 
Christian University in September, 1999, and graduate with the degree of Bachelor of 
Science in June, 2003. He entered the graduate program in the Electrical and Computer 
Engineering Department in Auburn University in January, 2004.  
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 v
THESIS ABSTRACT 
COLD CATHODES FOR APPLICATIONS IN POOR VACUUM AND LOW 
PRESSURE GAS ENVIRONMENTS: CARBON NANOTUBES 
VERSUS ZINC OXIDE NANONEEDLES 
 
An-jen Cheng 
Master of Science, May 11, 2006 
(B.S. Chun-Yuan Christian University, R.O.C Taiwan, June 2003) 
 
131 Typed Pages 
Directed by Yonhua Tzeng 
    Effects of gas pressure on the electron field emission (FE) properties of zinc oxide 
(ZnO) nanoneedles and carbon nanotubes (CNTs) were investigated. The FE properties 
for ZnO nanoneedles almost fully recovered after being subjected to FE tests in poor 
vacuum and low pressure gas environments and then characterized again in better 
vacuum around 1?10
-6
 Torr. In the contrast, the FE properties for CNTs did not recover 
after being subjected to FE tests in poor vacuum and low pressure gas environments.  
Reversibility and sensitivity of the FE of ZnO and CNTs to air pressures were studied 
for potential applications to field emission display (FED) and vacuum microelectronic 
devices. The pressure-dependent, time-dependent, and pressure-time-dependent field 
emission behaviors of ZnO nanoneedles and CNTs will be compared and discussed. 
 
 vi
ACKNOWLEDGEMENTS 
The author would like to extend his deepest thanks to Dr. Yonhua Tzeng for his 
supervising this thesis and being a great academic advisor during the author?s graduate 
study in Auburn University. 
The author would like to express his appreciation to Mr. Yan-Kang Liu, Mr. Chao Liu, 
Mr. Dake Wang, Ms. Hee Won Seo, Dr. Minseo Park, and Dr. An-Ban Chen for their 
great help and discussion. 
Finally the author would like to thanks his family, especially his mother Chin-hua 
Chen, for their love, encouragement, dedication, and support. 
   
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 vii
Style manual or journal used: Bibliography conforms to those of the transactions of the 
Institute of Electrical and Electronics Engineers  
 
 
Computer software used: Microsoft Word 2000 for Windows 
 
 
 
 
TABLE OF CONTENTS 
 
 
 
LIST OF FIGURES???????????????????????????xi  
 
LIST OF TABLES???????????????????????????.xv 
 
 
CHAPTER 1 INTRODUCTION?....??????.??????????????1 
     
    1.1 Introduction of carbon nanotubes??????????.?????????1 
 
    1.2 Introduction of a functional oxide-zinc oxide.................................................6 
 
    1.3 Purpose of research????????????????????????9 
 
 
CHAPTER 2 LITERATURE REVIEW???????????...............................10 
                                                                  
2.1 Structure and material properties of carbon nanotubes???????????10 
 
2.1.1 Basic structure concept of carbon nanotubes???????????..10 
           
2.1.2 Electrical properties of carbon nanotube?????????????16 
           
2.1.3 Mechanical properties of carbon nanotubes???????...????22 
           
2.1.4 Magnetic properties of carbon nanotubes????????????24 
 
        2.1.5 Chemical properties of carbon nanotubes????????????25 
      
2.2 Growth techniques of carbon nanotube???????????????..27 
            
           2.2.1 Carbon nanotubes growth by arc discharge???????????27 
????????????????...????????????.27 
           2.2.2 Carbon nanotubes growth by laser ablation???????????...32 
            
 2.2.3 Carbon nanotubes growth by chemical vapor deposition??????36 
            
           2.2.4 Carbon nanotubes growth mechanisms?????????????.39    
 
 viii
2.3 Structure and material properties of zinc oxide nanostructure???????43 
                 
            2.3.1 Structure of ZnO?????????????????????43 
             
2.3.2 Electrical properties of ZnO?????????????????.49 
  
            2.3.3 Optical properties of ZnO??????????????????.53 
             
2.3.4 Other properties of ZnO???????????????????57 
                      
       2.4 Growth techniques of ZnO????????????????????59 
                                                                                  
            2.4.1 ZnO synthesis by metal organic chemical vapor deposition????59 
              
            2.4.2 ZnO synthesis by laser ablation???????????????62 
 
            2.4.3 ZnO synthesis by vapor transport??????????????..64 
 
 
       2.5 Field Emission of Electrons from Solid Surface???????????..68 
               
             2.5.1 Field Emission form metal surface??????????????..68 
                                                                    
             2.5.2 Field emission form semiconductor surface???????????70 
 
             2.5.3 Field emission form carbon nanotubes?????????????72 
 
             2.5.4 I-V instabilities and arcing protection?????????????..75 
 
  CHAPTER 3 SPECIMEN PREPARATIONS AND CHARACTERIZATION???.77 
      
         3.1 Growth process????????????????????????77 
              
3.1.1 ZnO nanostructures growth?????????????????77 
 
              3.1.2 Carbon nanotubes growth?????????????????80 
         
3.2 Electron field emission measurement and setup???????????.82 
 
  CHAPTER 4 RESULTS AND DISCUSSION?????????????.85 
                                                                                         
4.1 Growth of carbon nanotube and its field emission????????85 
  
              4.1.1 Growth and field emission property of  
multi-walled carbon nanotubes???????????????.85 
               
 ix
4.1.2 Growth and field emission property of  
single-walled carbon nanotubes???????????????88 
         
4.2 Growth of ZnO and its field emission???????????????.91 
         
4.3 Field emission measurements under diverse pressures?????????97 
                  
4.3.1 ZnO nanoneedles field emission measurement  
under diverse pressures??????????????????.98 
                  
4.3.2 SWCNT & MWCNTs field emission measurement 
 under diverse pressures?????????????????..100 
                     
                  4.3.3 Field emission pressure effect of ZnO nanoneedles and CNTs???103 
 
4.4.4 Low and high pressure current stability of ZnO and CNTs????..105 
    
  CHAPTER 5 SUMMARY AND FUTURE DIRECTION?????????..109 
 
BIBLIOGRAPHY??????????????????????????.112 
 
 
             
 
 
   
          
 x
 
 
LIST OF FIGURES 
1.1 Schematic diagram of the formation of a single-walled carbon nanotube. (a) The 
projection of C
140
 molecule on a hexagonal lattice. (b) A C
140
 molecule. (c) A carbon 
nanotube one layer in thickness. ??????????????????????.2 
 
1.2 Bonding structures of diamond, graphite, nanotubes, and fullerenes: when a graphite 
sheet is rolled over to form a nanotube, the sp
2
 hybrid orbital is deformed for 
rehybridization of sp
2
 toward sp
3
 orbital or ?-? bond mixing. This rehybridization 
structural feature, together with ? electron confinement, gives nanotubes unique, 
extraordinary electronic, mechanical, chemical, thermal, magnetic, and optical properties.  
???.????????????????????????????????.5 
 
2.1 Chiral vectors (n, m) of a carbon nanotube which can be indexed by a planar 
honeycomb graphite sheet. The location and the length of the lattice vector are used to 
determine the chirality, electrical properties, and diameter of a nanotube. a
1
 and a
2 
are the 
real space unit vector of the hexagonal matrix network?????????????12  
 
2.2 Since a graphite sheet can be folded in different directions, typically two special 
genres of nanotubes can be obtained: (1) zigzag (n, 0), and (2) armchair (m, m), the rest 
of them are classified as chiral (n, m) nanotubes where n>m>0 by definition????..14 
 
2.3 Schematic of sectional hexagonal lattice network of a graphite sheet with its real 
space unit vector????????????????????????????16 
 
2.4 The two types of orbital are represented by red (orbital 1) and blue (orbital 2) in the 
schematic diagram above, where one orbital is neighbored by three orbitals of the other 
type?????????????????????????????????19 
 
2.5 Schematic diagram of the arc discharge apparatus where carbon nanotubes are formed 
from the plasma between the two black carbon rods. All the arrows indicate for the 
vacuum and the He lines are water-cooling system??????????????..29 
 
2.6 Schematic of laser ablation setup for carbon nanotubes growth????????.33 
 
2.7 Schematic of commonly used laser ablation reactor for SWCNTs growth????.35 
 
2.8 Schematic diagram of a PECVD setup for carbon nanotubes growth??????.38 
 
 
 
 xi
2.9 Schematic of tip and base carbon nanotubes growth mechanisms. On the left hand 
side, the nanoparticle is detached from the substrate on the tip of nanotube, catalyzing 
growth and preventing nanotubes closure. On the right hand side, the nanoparticle 
remains on the substrate, severing as an initial template for nanotubes nucleation.  Figure 
(a) shows the nanoparticle is saturated by carbon species (b) stage of nanotubes 
nucleation (c) post-nucleation growth???????????????????42   
 
2.10 The wurtzite structure model of ZnO. The tetrahedral coordination  
of Zn-O is shown??????????????????????????.45 
 
2.11 ((a), (b)) SEM images of the hierarchical ZnO nanowire junction arrays, (c) the 
growth model of the hierarchical structure??????????????????47 
 
2.12 Typical growth morphologies of one-dimensional ZnO nanostructures and the 
corresponding facets??????????????????????????.48 
 
2.13 (a) Schematic of ZnO nanowire transistor, a single ZnO nanowire is connects to the 
two electrodes (source and drain) (b) I
SD
-V
SD 
characteristics at different gate voltages as 
V
SD 
varies from 0 to 2V. (c) transfer characteristics as V
G
 varies from -20 V to 20 V at 
V
SD
=2V (d) Change of the transfer characteristics of two nanowires grown at the same 
time but different locations. Nanowire A has a mobility of 80 cm
2
/Vs and carrier 
concentration ~10
6
cm
-1
; and nanowire B has a mobility of 22 cm
2
/Vs and carrier 
concentration ~10
7
cm
-1
?????????????????????????.52 
 
2.14 Schematic illustration of utilizing MOCVD for ZnO growth????????..60 
 
2.15 SEM cross section images of ZnO grown at various growth temperature (a) T
g
? 
200?C, (b) 200?C< T
g
 ?260?C, (c) 260?C<T
g
 ?320?C  (d) 320?C < T
g
 ?380?C, and (e) 
T
g
> 380?C. The ZnO morphologies grown at those temperature regimes are 
schematically described?????????????????????????.61 
 
2.16 Growth model of NAPLD (a) at low substrate temperature (b) at high substrate 
temperature??????????????????????????????64 
 
2.17  Schematic of different ZnO nanostructures growth 
         at different temperature zone????????????????????65 
 
2.18 Schematic of ZnO nanowire growth by VLS process???????????67 
 
2.19 (a) Schematic diagram of the band bending neat the semiconductor surface by strong 
electric field (b) An internal barrier generated by an internal retarding field????..71 
 
3.1 Schematic diagram for thermal CVD ZnO nanostructures growth???????.79 
 
3.2 Figure 3.2: Schematic diagram for thermal CVD carbon nanotubes growth???..81 
 
 xii
3.3 Schematic diagram for the field emission measurement setup????????..84 
 
4.1 SEM image crosssectional view of  
the side wall of multi-walled carbon nanotubes??????????????..86 
 
4.2 TEM photograph of multi-walled carbon nanotubes on silicon with e-beam 
evaporation of Ti/Fe/Si metal catalysts. The magnification is 100k????????87 
 
4.3 Field emission measurement of multi-walled carbon nanotubes????????88 
 
4.4 (a) Cross section SEM image of SWCNT bundles (b) Top view of SWCNT???89 
 
4.5 Field emission measurement of single-walled carbon nanotubes????????90 
 
4.6 (a) higher resolution of SEM image for ZnO nanoneedles. Image size: 6?6 ?m (b) 
lower resolution of SEM image for ZnO nanoneedles. Image size: 20?20 ?m????91 
 
4.7 SEM images of ZnO nanostructure grow on Si (111) wafer, (a) is the magnification of 
10K (image size 5?5 ?m), (b) is the magnification of 20K (image size 2.5?2.5 ?m) and (c) 
is the edge view of the sample with the magnification of 10K  
(image size 6?6 ?m)??????????????????????????.93 
 
4.8 SEM images of ZnO nanostructure grow on Si (100) wafer, (a) is the magnification of 
10K (image size 5?5 ?m) and (b) is the magnification of 5K  
(image size 10?10 ?m)?????????????????????????94  
 
4.9 PL spectrum measured at room temperature, (a) is the PL spectrum of Si (111) 
sample, which shows no green emission and (b) is the PL spectrum of Si (100) sample, 
which shows strong green emission at 510nm????????????????..95  
 
4.10 Field emission measurement of ZnO nanoneedles?????????????96 
 
4.11 Fowler-Nordheim plot of ZnO????????????????????96 
 
4.12 I-E curves of field emission of ZnO nanoneedles measurement at varied air 
pressures: (a) 1x10
-6 
Torr, with the cross marks (b) 0.5mTorr, with the asterisk marks (c) 
3.5 mTorr, with the plus marks, (d) 30mTorr, with the diamond marks (e) 60mTorr, 
which is the curve that overlapped with curve (d) up to 3V/?m?????????.100 
 
4.13 I-E curves of field emission of MWCNTs measurements at varied pressures (a) 
1x10
-6
 Torr, with the cross marks (b) 0.5mTorr, with the asterisk marks (c) 3.5 mTorr, 
with the plus marks, (d) 30mTorr, with the diamond marks (e) 60mTorr, with the dark 
circles???????????????????????????????..102 
 
 
 
 xiii
4.14 I-E curves of electron field emission of  SWCNTs measured at varied pressures  (a) 
1x10
-6
 Torr, with the cross marks (b) 0.5mTorr, with the asterisk marks (c) 3.5 mTorr, 
with the plus marks, (d) 30mTorr, with the diamond marks (e) 60mTorr, with the dark 
circles???????????????????????????????.102 
 
4.15 I-E curves of field emission measurements for ZnO nanoneedles at low pressure 
before (a) and after (b) measurements carried out at higher pressures???????104 
 
4.16 I-E curves of field emission measurements for MWCNTs at low pressure before (a) 
and after (b) measurements carried out at higher pressures???????????104 
 
4.17 I-E curves for Field emission measurements for SWCNTs at low pressure before (a) 
and after (b) measurements carried out at high pressures???????????..105 
 
4.18 Stability measurements for both MWCNTs and ZnO nanoneedles in vacuum at 
1x10
-6
 Torr and a higher pressure at 0.5mTorr at a constant applied electric field of 
4V/?m:(a) MWCNTs stability test in vacuum (b) MWCNTs stability test at 0.5 mTorr (c) 
ZnO nanoneedles stability test in vacuum (d) ZnO nanoneedles stability test 
at 0.5 mTorr??????????????????????????..?..108 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 xiv
 
 
LIST OF TABLES 
2.1 Isomers made of carbon???????????????????????..11 
 
2.2 Classification of carbon nanotubes???????????????????..14 
 
2.3 Mechanical properties of carbon nanotubes????????????????24 
 
2.4 Parameters of the MWCNT arc synthesis with 6-mm diameter anode rods????30 
2.5 Metals and metal compounds catalysts for SWCNT synthesis (Modified from ref.      
[82])????????????????????????????????..31 
 
2.6 Physical properties of wurtzite ZnO???????????????????44 
 
2.7 Electron density and mobility measurement under diverse oxygen pressures???49 
 
2.8 Lattice parameter of several epitaxy substrates??????????????.67 
 
2.9 Emission threshold electric fields for various emitter materials????????.73 
 
 
 
 
 
 
 
 
. 
 
 
 
 xv
 1
 
 
CHAPTER 1 
 
INTRODUCTION 
 
 
1.1 Introduction of carbon nanotubes 
 
 
Carbon-based nanostructured materials, such as nano-crystalline diamond, fullerenes 
( by Kroto et al. in 1985) [1], carbon nanotubes ( by Iijima in 1991) [2], as well as II-VI 
metal oxide or III-V compound metal oxide nanostructures have attracted considerable 
attention due to their unique structural and electrical properties. Carbon nanotubes (CNTs) 
are quasi-one-dimensional (Q1D) cylindrical structure with a typical diameter ranging 
from 1 nanometer (nm) to several nanometers and length of up to tens of micrometers, 
and with properties close to those of an ideal graphite fiber. There are two main factors 
when the uniqueness of the nanotubes structure is characterized. One is helicity, which is 
defined by symmetry and the tube diameter. Another one is topology, which is defined by 
the uniformity of the tube in each layers through growing process [2]. The change in 
helicity introduces a significant change in the electric density of states, providing unique 
electrical characters for the nanotubes. The topology, on the other hand, has a profound 
effect on physical properties.  
Among the carbon nanotubular structures, two categories exist with different 
appearances, structures, and graphitizations. One is single-walled carbon nanotubes 
(SWCNTs), the other is multi-walled carbon nanotubes (MWCNTs). It is simple to image 
a single-walled carbon nanotube. Ideally, it is suitable to consider it as a perfect graphene 
sheet, in which a graphene being the same polyaromatic mono-atomic layer made of a 
hexagonal network of sp
2
 hybridized carbon atoms that genuine graphite is built up with, 
to roll it into a cylinder. The hexagonal rings put in contact join coherently. Then the two 
ends are closed by two caps. The caps are hemi-fullerenes with an appropriate diameter 
(Figure 1.1).  The number of cylindrical layers could be more than one; hence forming so 
called multi-walled carbon nanotubes.  
                                                                                                                            
 
 
 
 
  
 
Figure 1.1: Schematic diagram of the formation of a single-walled carbon 
nanotube. (a) The projection of C
140
 molecule on a hexagonal lattice. (b) A C
140
 molecule. 
(c) A carbon nanotube one layer in thickness. [3] 
 
     
 
 2
 3
    The ideal structure of CNTs, in terms of bonding of carbon atoms (sp
2
) and 
hybridization of orbital, is essentially graphitic (Figure 1.2). The feature of this structure 
is an inside hollow tubular surrounded by the basal plane(s) (002) of graphite, which 
curved symmetrically geometry and remaining parallel to the tube axis. The formation of 
the tubular morphology of CNTs is that the free energy of the basal plane in graphite is 
exceptionally low and stable. The free energy required for nanotubes growth is 
minimized when the outer surface is a curved basal plane rather than precipitated a highly 
strained prismatic plane. 
 However, the circular curvature of CNT causes quantum confinement and ?-? 
rehybridization in which three ? bonds are slightly out of the plane; for compensation, the 
? orbital is more delocalized outside the tube. This makes nanotubes mechanically 
stronger, electrically and thermally more conductive, and chemically and biologically 
more active than graphite. In addition, they allow topological defects such as pentagons 
and heptagons to be incorporated into the hexagonal network to form capped, bent, 
toroidal and helical nanotubes, whereas electrons can be localized in pentagons and 
heptagons because of the redistribution of ? electrons. Theoretically, a nanotubes is 
defect free if it is of a perfect hexagonal network and defective if it contains topological 
defects such as pentagon and heptagon or other chemical and structural defects [8]. 
    There are several mechanisms for the growth of CNTs; however, the growth 
mechanism is still a far way from well known. One reason is that the growth conditions 
allowing carbon filaments to growth are very diverse, which means that related growth 
mechanisms are many and not controllable. The other reason is that the phenomena are 
quite fast and instantaneously and it is difficult to be observed in situ. It is generally 
 4
agreed that the growth should occur so that the number of dangling bonds is limited, for 
energetic reasons. The growth method of CNTs is usually assisted or driven by 
pyrolyzing hydrocarbon gas mixture, such as acetylene and methane, with selected metal 
particles serve as catalyst during the growing process. 
Several methods for growing CNTs have been achieved, including carbon arc 
discharge method [4], laser ablation [5], DC-arc plasma jet [6], thermal chemical vapor 
deposition [7], and plasma-enhanced chemical vapor deposition (PECVD) [8].   Under 
certain circumstances, bundles of nanotubes with diameters up to 50?m are formed with 
individual nanotubes arranged semi-parallel to each other. The smallest bundle is called a 
microbundle, which is composed of 10 to 100 nanotubes [3]. 
Carbon nanotubes exhibit outstanding electrical, mechanical, and chemical properties. 
They have great potential in small device applications since their dimensions have been 
shrunken down to nanometer scale region, which cause quantum confinement and 
unusual physical and electrical phenomena.  Carbon nanotubes possess small radius of 
curvature that allows electrons to be extracted into vacuum by a relatively low external 
electric field, which makes them suitable for applications such as field emission flat panel 
display (FED), etc... Moreover, CNTs have fairly low turn-on electric field and high 
current density, which is mainly due to the high field enhancement factor (?) caused by 
their extreme high aspect ratio and small curvature.  
 
 
 
 
 
 
 
 
 
 
Figure 1.2 Bonding structures of diamond, graphite, nanotubes, and fullerenes: when a 
graphite sheet is rolled over to form a nanotube, the sp
2
 hybrid orbital is deformed for 
rehybridization of sp
2
 toward sp
3
 orbital or ?-? bond mixing. This rehybridization 
structural feature, together with ? electron confinement, gives nanotubes unique, 
extraordinary electronic, mechanical, chemical, thermal, magnetic, and optical properties 
[8].  
 
 
 
 
 5
 6
1.2 Introduction of a functional oxide-zinc oxide 
     
    A widely accepted definition of a nanostructure is that the structure has least one 
dimension less than 100nm [9], typically including layer-like, wire-like, and particle-like 
structures. Quantum effects due to the size confinement in nanostructured materials 
occurs when the characteristic size of the object is comparable with the critical lengths 
(1-10nm, typically) of the corresponding physical processes, such as mean free path of 
electrons, the coherence length, or the screening length [9]. Two-dimensional (2D) 
quantum wells, one-dimensional quantum wires, and zero-dimensional quantum dots are 
the typical structural forms.  
Functional oxides of several novel nanostructures such as nanobelts, nanowires, 
nanoneedles, nanonsheeets, and nanohelixes are the fundamental of smart devices. Many 
metal oxide materials such as ZnO, SnO
2
, In
2
O
3
, Ga
2
O
3
 and PbO
2
 have been investigated 
and synthesized. Zinc oxide (ZnO), a key technological material, is the metal oxide that 
will be focused in this study. 
Oxides are the basis of smart and functional materials. Synthesis and potential device 
applications using functional oxides have attracted great attention due to the physical 
properties of these oxides can be tuned. Functional oxides have two structural 
characteristics: cations with mixed valence states, and anions with deficiencies (vacancies) 
[10]. By adjusting either or both of these characteristics, the electrical, optical, magnetic, 
and chemical properties can be tuned, giving the possibility of fabricating smart devices. 
The structures of functional oxides are very diverse and varied, and there are everlasting 
new phenomena and applications. According to such unique characteristics make oxides 
 7
one of the most diverse classes materials, covering various of the application fields such 
as semiconductor, superconductor, ferroelectrics, and magnetics. 
Wurtzite ZnO, a wide bandgap (3.37eV) II-V compound semiconductor, has a 
hexagonal structure. The structure of ZnO can be simply described as a number of 
alternating planes composed of tetrahedrally coordinated O
2-
 and Zn
2+
 ions, heaped 
alternatively along the c-axis [11-12]. The tetrahedral coordination in ZnO leads to a non-
central symmetric structure, which is one of the most important structural characteristics 
of wurtzite nanostructured materials. ZnO shows strong electromechanical coupling due 
to its unique structure, resulting in strong piezoelectric and pyroelectric properties. The 
other important structure characteristic of ZnO is polar surfaces. The most common polar 
surface is the basal plane. Finally, ZnO is also a bio-safe and biocompatible material, 
which can be used for biomedical applications without further coating. 
ZnO has attracted intensive research efforts due to its unique properties and versatile 
applications in transparent electronics, ultraviolet (UV) light emitters, piezoelectric 
devices, chemical sensors, and spin electronics. Invisible thin film transistors (TFTs) 
using ZnO as an active channel have achieved much higher field effect mobility then 
amorphous silicon TFTs [13-15]. These transistors can be widely used for display 
applications. ZnO has been proposed as a more promising candidate for UV emitting than 
GaN because of its larger exciton binding energy (60meV). This leads to the reduction of 
UV lasing threshold and the increment of UV emitting efficiency at room temperature 
[16].  
Geometrical morphology of metal oxide nanostructured materials, a diverse 
nanostructures have been synthesized basically by chemical vapor deposition, can be 
 8
classified into: tubes [2, 17-23], cages [24, 25], cylindrical wires [26-33] and rods [34-36], 
co-axial and bi-axial cables, ribbons or belts, sheets [37, 38], and diskettes. 
    The synthetic methods can be generally classified into several categories: (1) vapor-
phase growth, which included thermal evaporation, chemical vapor-phase deposition, 
metal-organic chemical vapor-phase deposition, arc-discharge, laser ablation, etc. (2) 
solution-phase growth, (3) sol-gel, (4) templated-based methods, etc. Among these 
methods, thermal evaporation is the most commonly used method in the investigation of 
oxide nanostructures. Different kinds of nanostructures can be synthesized using thermal 
evaporation technique by adjusting the processing parameters, such as pressure, growth 
temperature, carrier and reactant gases flow rate, and substrates.  
 
 9
1.3 Purpose of Research 
     
CNTs show prominent electrical and mechanical properties for many potential 
applications due to their unique structures and physical dimensions, but several different 
kinds of ZnO nanostructures also manifest outstanding electrical, mechanical, and optical 
properties. One of the most potential applications for these kinds of nanostructured 
materials, regardless of CNTs or ZnO, is the application in field emission flat panel 
display, which nanostructured materials can serve as the cold cathode field electron 
emission sources. Due to the small physical dimensions of the nanostructures, electrons 
can be easily tunneled through the tips of the CNTs and ZnO at a relatively low external 
electric field into vacuum.  Moreover, it is fairly easily and inexpensive for depositing 
large area CNTs and ZnO nanostructures.  
Even though CNT seems to be the most promising candidate for field emission display 
(FED), because of its high aspect ratio that allows a high field for large electron emission 
to be carried out[40, 41]. However, the field emission of CNTs undergoes an irreversible 
degradation under oxygen and air ambient [42, 43].  The degradation of cold cathode 
emitters demonstrated one of the most important hurdles for realizing the successful 
commercialization of FEDs [44].   
The purpose of this research is to characterize the field emission properties of different 
as-deposited ZnO nanostructured materials and CNTs.  Furthermore, it is to find out an 
inexpensive, convenient, and well-controlled method for growing CNTs and ZnO 
nanostructured material as field electron emission sources. 
  
 10
  
 
                                               
                                                 CHAPTER 2 
 
                                         LITERATURE REVIEW 
 
 
2.1 Structure and Material Properties of Carbon Nanotubes 
 
2.1.1 Structural Concept of Carbon Nanotubes 
 
Carbon nanotube is a new nanostructured material made of carbon atoms with the bond 
length of 1.42? between each adjacent carbon-carbon bonds. The structure of carbon 
nanotube is the orientation of the six-membered carbon bonds (called hexagonal) in the 
honeycomb periodic lattice along the axis of the nanotube. One advantage of carbon-based 
material is related to the many possible configurations of the electronic states of a carbon 
atom, which is known as the hybridization of atomic orbitals. Each carbon atom has six 
electrons occupying 1s
2
, 2s
2
, and 2p
2
 atomic orbitals. The 1s
2
 orbital possesses two 
strongly bounded electrons, which is known as core electrons. The other four electrons 
occupy in either the 2s
2
, or 2p
2
 orbitals, and these more weakly bonded electrons are called 
valence electrons. Since the energy difference between the energy level of upper 2p orbital 
and that of lower 2s orbital in carbon is relatively small compared to the binding energy of 
the chemical bonds; therefore, the electric wave functions for these four weakly bounded 
electrons can be easily mixed with each other. The phenomenon of mixing bounds between 
2s and 2p atomic orbital is so called hybridization. Moreover, carbon is the only element in 
the periodic table that has isomers from 0 dimensions (0D) to 3 dimensions (3D), as shown 
in table2.1 [45]. 
 
Table 2.1: Isomers made of carbon [45]. 
Dimension        0-D         1-D         2-D        3-D 
isomer C
60
 fullerene    nanotube      Graphite     diamond 
     carbyne       fiber     amorphous 
hybridization        sp
2 
    sp
2 
(sp)        sp
2
          sp
3
 
density(g/cm
3
)     1.72     1.2-2.0      2.26       3.515 
     2.68-3.13       ~2         2-3 
bond length 
     (?) 
1.40 (C=C) 
1.46(C-C) 
  1.44(C=C) 1.42(C=C) 
1.44(C=C) 
1.54(C-C) 
Electronic 
properties 
semiconductor 
E
g
=1.9eV 
metal or 
semiconductor 
semimetal insulating 
E
g
=5.47eV 
 
 
    A carbon nanotube can be visualized as rolling a graphene sheet into a hollow cylinder 
with both ends capping with a half of the carbon fullerene bulky ball. Thus, the structure is 
in one dimensional with axial symmetry, and, generally, exhibiting a spiral conformation 
so called chirality. Dresselhaus et al. generated a notation of specifying the structure of an 
individual tube [46]. By Dresselhaus notation, the position of each carbon atom, which is 
used to construct a single-walled nanotube, can be specified by the chiral vector. A chiral 
vector, which is generally labeled C
h
, joins two equivalent points on the original graphene 
lattice (Figure 2.1).  Chiral vector can be expressed by the real space unit vector a
1
 and a
2
, 
which is the unit cell base vector of the graphite sheet. And a
1
=a
2
= 3d
c-c
 with indicating 
the c-c bond length of 0.142nm, typically. The chiral vector and real space unit vector a
1
 
and a
2 
can be related by:    
                                                  C
h
=na
1
+ma
2
,    (0?|m|?n)                                         (2.1) 
 11
                                     
 
Figure 2.1: Chiral vectors (n, m) of a carbon nanotube which can be indexed by a planar 
honeycomb graphite sheet. The location and the length of the lattice vector are used to 
determine the chirality, electrical properties, and diameter of a nanotube. a
1
 and a
2 
are the 
real space unit vector of the hexagonal matrix network. [3] 
 
 
The diameter of the carbon nanotube, d
t
, is then evaluated by dividing the absolute value of 
the chiral vector by ?; as:  
                                        d
t
= 
22
an m nm
?
++
, a=|a
1
|=|a
2
|=0.246nm                             (2.2) 
The chiral angle, ?, is defined by the angle between the vectors C
h 
and a
1
 with values of ? in 
the range of 0?|?| ? 30?. The chiral angle ? is physically expressed as the tilting angle of the 
 12
hexagons with respect to the direction of the nanotube axis, and it specifies the spiral 
symmetry. The chiral angle is expressed as: 
                                       ?=
1
22
2
cos
2
nm
nmnm
?
+
++
,    0????/6                                        (2.3) 
Carbon nanotubes can be classified into two groups structure wise, achiral and chiral. An 
achiral carbon nanotube is defined by a carbon nanotube whose mirror image has an 
identical structure to the original one. There are two kinds of achiral nanotubes, one is 
armchair and the other one is zigzag nanotubes. The tubes with n=m are commonly 
denoted as armchair tubes, and with m=0 is implied as zigzag tubes  Chiral nanotubes show 
spiral symmetry whose mirror image cannot be superposed on to the original one (Figure 
2.2) [8]. Table 2.2 is a classification of carbon nanotubes [45].  
The lattice constant and intertube spacing are the two main parameters in constructing a 
SWCNTs, SWCNT bundles, and MWCNTs. These two parameters are also a function of 
tubes diameter and radial direction. The structural model is of special interest to study the 
influence of tube chirality (n, m) from simple structural relation to experimentally 
measurable geometry (D, ?). The chirality (n, m) has many correlations with electric, 
optical, magnetic, and other properties of a nanotube. 
  Simply, the spacing between any two coaxial neighboring zigzag tubes (n, 0), and (m, 0) 
is 
2
D?
= (0.123/?) (n-m) from equation (2.2) and a=0.246. Therefore, the spacing between 
two coaxial MWCNTs cannot be closer than 0.34 nm regardless of value of integer n and m 
[8]. The most important feature of tube chirality (n, m) is that it is directly related to the 
electric properties of a nanotube.  
 
 13
  
 
Figure 2.2: Since a graphite sheet can be folded in different directions, typically two 
special genres of nanotubes can be obtained: (1) zigzag (n, 0), and (2) armchair (m, m), the 
rest of them are classified as chiral (n, m) nanotubes where n>m>0 by definition [8]. 
                              
         type             ?          C
h
  Shape of cross section  
      armchair            30?         (n,n)    cis-type 
 
      zigzag             0?         (n,0) 
  Trans-type  
      chiral       0?<|?|<30?         (n,m) Mixture of cis and trans. 
                      
                         Table 2.2: Classification of carbon nanotubes [45] 
 14
 15
Experimentally observed carbon nanotubes are defective nanotubes. They often present 
in capped, bent, branched (L, Y, and T), and helical MWCNTs and SWCNTs form. Most 
of these defective structures are recognized to have topological defects such as pentagons 
and heptagons incorporated in the hexagonal matrix of the nanotubes. The pentagon 
defects are mostly located in the zenith regions of the tips during the formation of 
fullerene-like caps. The closure of an open cylindrical surface necessarily involves 
topological defects, at atomic level, that would introduce positive Gaussian curvature. For 
a nanotube, the surface lattice is composed by a network of six-membered rings. The 
introduction of positive curvature is achieved by introducing a positive wedged 
disclination [47, 48], or rings with fewer than six members. In carbon nanotubes, the 
structural defects are often in pentagonal rings form, and rings with fewer than five 
members have never been found.  The pentagons in the hexagonal lattice can be thought of 
defects in a sp
2 
bonding configuration.  A heptagon defect, which produces negative 
Gaussian curvature, can be created in the hexagonal carbon lattice by introducing a 
seven-membered ring (-60? disclination) or by cutting and inserting an extra 60? segment 
into the lattice. The heptagons defects can sometimes be observed, but are destroyed in 
most tubes what is according to the general restriction of helical arrangement of the 
hexagonal network [3, 49]. Pentagon-heptagon pairs are believed to be the major 
topological defects, which are the basic structure for constructing different bending 
junction of carbon nanotubes conformations [3]. In order to achieve topological enclosure 
for any single tube, the total number of the pentagons (P) and heptagons (S) should obey 
the relation of P=S+12. 
 Scanning tunneling microscopy (STM) and Raman spectrum are commonly used in 
characterizing the tube geometry (d
t
, ?), which can be used to calculate (n, m). In addition, 
high-resolution transmission electron microscopy (HRTEM) is also used in studying the 
structures, defects, and arrangement of CNTs in details.  
  
2.1.2 Electrical Properties of Carbon Nanotubes 
 
Electrical transport properties of carbon nanotubes are strongly depended on the 
chirality and morphology of the nanotubes. A SWCNT is formed by folding a sheet of 
graphite, which is composed of hexagonal network; therefore, the electrical properties of a 
SWCNT can be either metallic or semiconducting depending on the angle which the 
graphite sheet has been folded. Since graphite sheet consists of periodic hexagonal network 
that the location of each carbon atom can be easily pointed out by utilizing the real space 
unit vector a
1
 and a
2
 (Figure 2.3). Corresponding to real space unit vector, the reciprocal 
lattice vector g
1
 and g
2
 can be related as follow:  
 16
 
a2
a2
1
    Figure 2.3: Schematic of sectional hexagonal lattice network of a graphite sheet with its 
real space unit vector. 
                                     a
1
 = (a, 0), a
2
= (-
1
2
a, 
3
2
a)                                                   (2.4) 
                                     g
1
=
12
(1, )
3
a
?
, g
2
=
22
(0, )
3
a
?
)                                             (2.5) 
The band structure of carbon nanotubes is usually modeled by a zone folding 
approximation of the graphene ? and ?* electron states obtaining from tight-binding 
Hamiltonian [50], which is related to chiral vector. Due to the fact that the ? states of the 
carbon-carbon bonds are fully saturated sp
2
 bonds, the main contribution to the valence 
band and conduction band are from the ?-states which are perpendicular to the plane. 
Therefore, one orbital (?) per atom model can be used to describe the qualitative nature of 
the band structure.    
For a total unit cells and  atomic orbitals in each cell of a periodic lattice structure 
the Bloch function 
N m
j
?  for each atomic orbital j can be written as:  
                                 
)(
1
)(
1
lj
N
l
Rki
j
Re
N
k
l
??
?
=
=
                                           (2.6) 
where )(
lj
R?  is the wave function of the atomic orbital j in the l th unit cell.  These wave 
functions that satisfy the Schr?dinger equation (2.7) can be written as a linear combination 
of all m orbitals (2.8). 
: 
                                                                                (2.7) 
)()()( kkEkH
nnn
?? =
?
                                                                                       (2.8) 
?
=
=
m
j
jjn
kkck
1
)()()( ??
As the linear combination of all m orbitals wave functions is substituted into the 
Schr?dinger equation, the equation of (2.7) can be written as:  
                                          (2.9) 
??
==
?
=
m
j
jjn
m
j
jj
kkckEkHkc
11
)()()()()( ??
 17
Equation (2.9) can also be written in matrix form as: 
                                                            (2.10) 
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
=
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
mn
n
n
mn
n
mmm
m
c
c
E
c
c
HH
HH
11
1
111
where the matrix element  is the Hamiltonian between two orbitals:      
, which can also be expressed as: 
'jj
H
??
?
)(||)'(
'
kHk
jj
??
       
)()()(
)()()(
1
'
*
'
)(
'
'
*
'
'
'
'
'
'
ljlj
R
RRik
kk
R
lj
R
lj
ikRRik
jj
RrrHRrdre
RrrHRrdree
N
H
l
ll
jl
ll
??=
??=
?
?
??
?
?
?
???
??
     (2.11) 
By solving (2.9), we can get m different energy . Thus, the number of energy band is 
determined by the total number of atomic orbital in each unit cell. 
n
E
In the case of graphite, there are two atoms in one unit cell. Each atom contributes one 
orbital so that there are two orbitals in each unit cell. Therefore, it has two energy levels. 
The two types of orbital are denoted in red (triangle) (orbital 1) and blue (diamond) (orbital 
2) color in the schematic diagram 2.4, where one orbital is neighbored by three orbitals of 
the other type.     
 18
                    
a
1 
0
a
2 
a
3 
Figure 2.4: The two types of orbital are represented by triangle (orbital 1) and diamond 
(orbital 2) in the schematic diagram above, where one orbital is neighbored by three 
orbitals of the other type. 
 
11
H  can be calculated by substituting the wave functions made of type 1 orbital into 
(2.11) as: 
                       (2.12) 
)()()(
1'
*
1
)(
11
'
ll
R
RRik
RrrHRrdreH
l
ll
??=
?
?
?
??
Let?s chose the position of atom 0 as  and then sum up all the other orbitals in red 
(triangle). Notice that all the other red orbitals except atom 0 itself are at distance more than 
one neighbor away from atom 0, so they are not counted in the nearest neighbor 
approximation:      
'l
R
                                    (2.13) 0'1'
*
111
)()()( ??? =??=
?
ll
RrrHRrdrH
 
 19
 
For the same approach:  
                                  (2.14)    0'2'
*
222
)()()( ??? =??=
?
ll
RrrHRrdrH
And for : 
12
H
)()()(
2'
*
1
)(
12
'
ll
R
RRik
RrrHRrdreH
l
ll
??=
?
?
?
??
                      (2.15)  If 
we chose atom 0 as  then there are three type 2 orbitals which are the nearest neighbors, 
so we have: 
'l
R
)(
)()()()(
321
321
2'
*
112
aikaikaik
ll
aikaikaik
eeet
RrrHRrdreeeH
++=
??++=
?
??
     (2.16) 
a1, a2, and a3 represent the real space vector positions for the three nearest neighbors of 
atom 0 and k is the reciprocal lattice vector that consists of g
1
 and g
2
.   
For , we have: 
21
H
                                                                                                             (2.17) 
*
1221
HH =
Finally the band energy E is then determined by  
                                              det
0
2212
2111
=
?
?
EHH
HEH
                           (2.18) 
Equation (2.18) can be written as: 
                 
2
2
0
)()(
321
aikaikaik
eeetE ++=??
                      (2.19) 
By applying the tight bonding model calculated above, the electrical band of a seamless 
SWCNT can be derived from the dispersion relation of a graphite sheet as 
 20
                   
1
2
( , ) | | (3 2cos(2 ) 2cos(2 ) 4cos( )2 )
1
hik C
t
e
? ??????
?
?=?+ + + +
=
ruur
??
           (2.20) 
where t=2.5-3.2 eV is the nearest neighbor-hopping parameter. The vector k (k=?g
1
+?g
2
) 
is composed of the reciprocal lattice unit vector g
1
 and g
2, 
which are derived from the real 
space unit vector a
1
 and a
2
. The periodic boundary condition is confined along the tube 
circumference and the C
h
 vector; therefore, the two-dimensional wave vector has to satisfy 
the boundary condition of
2
2
()
e
h
hik C
e
?
r uur
.  This means that it needs to be conformed by the 
equation as followed: 
                                               2( ) 2nmM? ?? ?+ =  (M=integer)   
Explicitly, there is no bandgap, when E (?, ?) =0, only if the electron states are located 
among the six corners of the first Brillouin zone. This results in the creation of metallic 
conductance nanotube where: 
                                               (n-m)=3M (M=integer) 
The rest of the nanotubes which do not follow the above equation will be semiconducting, 
and all armchair nanotubes are metallic. 
It has been experimentally confirmed that SWCNTs [51], SWCNT bundles [52], or  
MWCNTs [53] behave like a quantum wires intrinsically due to the quantum confinement 
which leads to the ballistic transportation condition of carbon nanotubes. The confinement 
of the electrons is along the direction of the tube circumference. The conductance for a 
nanotube is given by G=G
o
M= 
2
2
()
e
M
h
, where G
o
=
2
2
(
e
h
)= (12.9 k?)
-1
 is quantized 
conductance. M is an apparent number of conducting channel. The experimentally 
 21
 22
measured conductance is much lower than the theoretical value. The measured resistance 
for a single SWCNT is ~10 k?, as compared with the 6.45 k? predicted for the ideal 
SWCNT [54].  
 
2.1.3 Mechanical Properties of carbon nanotubes 
 
Carbon nanotubes have distinguished mechanical properties due to their high 
strength-to-weight ratio. Since ? bonding is the strongest bonding in nature; hence, a 
nanotube that is structured with all ? bonding is regarded as the ultimate fiber with the 
strength in its tube axis.  Both experimental measurement and theoretical calculations 
approve that a nanotube is as stiff as or stiffer than diamond with the highest Young?s 
modulus and tensile strength. Table 2.3 is the Young?s modulus and tensile strength of 
nanotube comparing with other materials [8].  Young?s modulus is independent of tube 
chirality, but dependents on tube diameter. Defect free nanotubes are stronger than 
graphite because the axial component of ? bonding is greatly increased when a graphite 
sheet is rolled to form a seamless cylindrical shape structure or a SWCNT. The highest 
value is from tube with diameter between 1 and 2 nm, about 1 TPa. For a coaxial MWCNT 
which consists of different diameter of SWCNTs, the Young?s modulus will take the 
highest value of a SWCNT plus contributions from coaxial intertube coupling or van der 
Waals force. Therefore, the Young?s modulus for MWCNT is higher than a SWCNT, 
typically 1.1 to 1.3 TPa. 
When nanotubes are bent, they buckle up together as reported by Despres et al [55]. The 
number of buckles depends on the degree of curvature and the diameter of the tubes. After 
 23
releasing from the bending force, CNTs straightened out without any damage, indicating 
that nanotubes are not only flexible, but also extremely elastic. A giant elastic response 
occurs when a nanotube is to be deformed. Macroscopically, the stiffest materials fail with 
a strain of approximately 1% because of dislocations and defects. On the other hand, CNTs 
can sustain up to 15% tensile strain before fracture [56]. Thus, the tensile strength of an 
individual nanotube can be as high as 150 GPa, assuming 1 TPA for Young?s modulus.  
The flexibility and elasticity of carbon nanotubes is related to the in-plane flexibility of 
planar graphite sheet and the rehybridization ability of sp
2
-sp
3
 of carbon atoms, where the 
degree of sp2-sp
3
 rehybridization depends on the degree of curvature.  Such a high elastic 
strain for several deformation modes of carbon nanotubes is originated from sp
2
 
rehybridization in nanotubes through which the high strain gets released. 
However, sp
2
 rehybridization will lead to a change in electrical properties of a nanotube. 
In asymmetric tubes (0<?<30?), strain will cause asymmetric ?-? rehybridization and 
therefore the change in electric properties  The armchair nanotubes are intrinsically 
metallic and open a band gap under torsional strain, and the zigzag metallic nanotubes open 
a band gap under tensile strain, not torsional strain [57, 58]. 
 
 
 
 
 
 
 24
 Young?s modulus 
        (GPa) 
   Tensile strength 
          (GPa) 
        Density 
        (g/cm
3
) 
      MWCNT      1200          ~150            2.6 
      SWCNT      1054              75            1.3 
   SWCNT bundle       563          ~150            1.3 
   Graphite (in plane)       350             2.5            2.6 
        Steel       208             0.4            7.8 
 
                  Table 2.3: Mechanical properties of carbon nanotubes [8]. 
 
2.1.4 Magnetic Properties of Carbon Nanotubes 
 
Davids et al. reported that carbon nanotubes should exhibit a paramagnetic- to 
diamagnetic-ordering transition when the radius of nanotubes increases above a critical 
value which estimated to be 6.4 ? [59]. Magnetic properties such as anisotropic g-factor 
and susceptibility of nanotubes are expected to be similar to those for graphite while some 
unusual properties may exist for nanotubes. The magnetic properties can be measured by 
electron spin resonance (ESR). The average observed g-value is 2.012 [60] and spin 
susceptibility is 7?10
-9
 emu/g in MWCNT, which are slightly lower than those in graphite 
(2.018 and 2?10
-8
 emu/g, respectively).  
 An interesting electrical response of the carbon nanotubes under a certain external 
magnetic field is expected. Ajiki et al. have considered the effect on the electronic states 
near the Fermi level of magnetic fields both perpendicular and parallel to the nanotube axis 
 25
[61, 62]. For magnetic field oriented parallel to the nanotube axis, the magnetic moment 
was found to oscillate as a function of magnetic flux. For metallic nanotubes, their results 
indicate that for small flux, the magnetic moment is in the same direction as the flux. For 
the semiconducting nanotubes, the magnetic flux and magnetic moment are in the 
opposing direction. Lu has reported that a metal-insulator transition and a band gap change 
occur for semiconducting tubes under magnetic field parallel to the tube axis [63]. A 
similar electrical response can also be found when magnetic field is perpendicular to the 
tube axis. 
The major magnetic character of carbon nanotube is that the band gap change is 
oscillatory; therefore, the semiconducting and metallic nature of nanotubes can be tuned by 
applying an external magnetic field, which is so called Aharonov-Bohm effect. The 
oscillatory behavior is confirmed by experimental measurements of resistance change in 
MWCNTs with the tube axis parallel to magnetic field [64]. 
 
2.1.5 Chemical Properties of Carbon Nanotubes 
 
Carbon nanotubes have unique properties of small diameter, large surface area, and ?-? 
rehybridization. These make carbon nanotubes very attractive in chemical and biological 
applications. The chemical properties of carbon nanotubes such as opening, wetting, filling, 
absorption, charge transfer, doping, and intercalation have been studied. Carbon nanotubes 
are highly graphitized carbonaceous materials, which result in low chemical reactivity. 
One important chemical reaction is their oxidation at raised temperature. Ajayan et al. 
found that by increasing the temperature above 750?C, the nanotubes start to oxidize from 
 26
the tip inward, layer by layer, which results eventually in open and thinner tubes [65, 3]. 
The increase reactivity of the tip must be due to the strain associated with very high 
curvature. Huira et al. confirmed that the oxidation process covers the nanotubes surface 
with three different oxides: carboxylic (-COOH), carbonyl (-CO), and hydroxylic (-COH) 
groups. These external functional groups in turn improve the chemical reactivity of the 
nanotubes and modify their wetting properties [66]. While nanotubes are able to oxidize in 
a controllable way, nanotubes can exhibit to be very sensitive to chemical reduction.  
Ebbesen et al. introduced alikali metals into nanotubes, and found that the nanotubes 
doped with alikali metals are gradually degraded upon mild heat treatment. It is believed 
that the alikali metals are able to intercalate by entering through dislocations in graphite 
sheet or they react with defects such as 5,7 pairs, which may be much sensitive to reduction 
than oxidation [3, 67].  
Enhanced molecular absorption and charge transfer are also the unique properties of 
carbon nanotubes. The gas adsorption and charge transfer capability are functions of sites 
and gas molecules. The site where a gas molecule can be absorbed included interstitial in 
tube bundles, groove above the gap between either two closest tubes, nanopore inside a 
tube, and surface of a single tube [68]. A conductance change presents as the gas molecules 
are introduced to contact with nanotubes. O
2
 has been studied to be dominantly absorbed 
on the surface of as-grown carbon nanotubes, resulting in a p-type behavior whereas it has 
been argued that water is the major reason [69]. Features of electrical response of carbon 
nanotubes to chemical absorption make them useful for chemical applications and gas 
detection sensor applications.  
 
 27
2.2 Growth Techniques of Carbon Nanotubs 
 
2.2.1 Carbon nanotubes growth by arc discharge 
 
MWCNTs were first found on the cathode surface by Iijima [2], which were produced 
by carbon arc discharge. The carbon arc discharge is a convenient method to produce 
diverse structures of carbon materials due to the high temperature of plasma, which 
approaches 3700? C [70]. Previously, carbon arc has been used to generate structures such 
as carbon whiskers, soot, and fullerenes [71, 72].Although it is convenient for generating 
different sizes of structures, one of the critical parameters that determines the structures is 
the type and pressure of the gas surrounding the arc.  
Basically, arc discharge carbon nanotubes growth can be divided into non-catalyst 
growth and catalyst assisted growth. The shape and the cross section of the cathode which 
has nanotubes deposit on it closely mimic the shape of the consumed anode. For instance, if 
an anode rod with a circle cross section creates a cathode deposit with a similar cross 
section and a circle core. Such cylindrical deposition consists of a hard gray outer shell and 
a soft fibrous black core. During synthesizing MWCNTs, the main by-products are 
multiwall polyhedral particles, and various kinds of graphitic nanoparticles.    
The dc arc discharge method was first optimized by Ebbesen et al. [73]. It becomes a 
common method for synthesizing MWCNTs. A schematic diagram of the arc discharge 
operating apparatus is shown in Figure 2.5 [3].  A long cylindrical-shaped deposit on the 
front of the cathode surface contained gram quantity of MWCNTs, which is produced by 
evaporating anode. The direct current arc, which is usually generated at 20V and 500 Torr, 
 28
operates in a 1- to 4- mm wide gap between two graphite electrodes that are installed in a 
water-cooled chamber filled with helium gas at subatmospheric pressure. The cylindrical 
deposit grows at a rate of about 1 to 2 mm/min. In order to stabilize the discharge, one 
electrode needs to be moved in such way that the gap distance between two electrodes 
remains the same, which can be monitored by the current value. The current is 
experimentally optimized at approximate 150 A/cm
2
 at 20V (i.e. ~50A for a 6mm diameter 
electrode) [3].
  
 
The arc is basically dynamic and the regions where the plasma is generated moved over 
to the electrode surface; therefore, a temperature gradient exists in the plasma which results 
in the size variation of CNTs. Carbon nanotubes are not found to be anywhere in the 
chamber after using carbon arc discharge, for instance, they are absent in the soot where 
fullerenes condense. This indicates that the deposition of nanotubes is only found where 
the current is flowing. It is reported that too much current results in harden materials and 
fewer free nanotubes [70].  On the other hand, lower the current results in a better yield of 
nanotubes deposition [74]. 
Carbon nanotubes produced from carbon vapor generated by arc discharge and laser 
ablation of graphite generally have fewer structural defects than those produced by the 
other techniques. This is due to the higher temperature growth that ensures perfect 
annealing of defects in tubular graphite sheet. High quality of MWCNTs can be obtained 
by arc discharge method, but obtaining high yields of carbon nanotubes is the major 
concern for using this method. Controlling helium gas and dc current are the most 
important parameters to optimize yield. Therefore, a stable and high yield arc process 
requires a constant feed rate and arc current during the synthesis.  Among the various inert 
gases, helium gives the best result probably because of its low ionization energy. Table 2.4 
shows the effect of gas pressure [8]. 
 
 
 
  
  
   Figure 2.5: Schematic diagram of the arc discharge apparatus where carbon nanotubes 
are formed from the plasma between the two black carbon rods. All the arrows indicate for 
the vacuum and the He lines are water-cooling system [3]. 
 
 
 
 29
 30
                                       
N He, 
(Torr) 
I, 
(A) 
Feed rate 
(mm/min)
Gap 
(mm) 
Deposit 
diameter
(mm) 
Growth 
rate 
(mg/min)
MWCNT 
amount   
(%) 
MWCNT 
diameter 
(nm) 
1 100 80      4  3.9    7.8    115         5   8-20 
2 200 65      4  2.2    6.5    170     10   8-22 
3 700 55      4  0.5    7.4    260     20   8-23 
4 500 65      8  0.4    8.0    350     20   5-29 
5 500 65     2.5  3.5    7.6     90     30   5-46 
6 1500 65     1.4  4.2    5.5     20     35   4-60 
7 2000 65     1.4  3.3    5.5     22     30   4-60 
8
a
 500 160    0.65  0.8   11.6    160     30   5-50 
9
b
 500 132     1.0  1.7   10.9    195     30   5-50 
 
    Table 2.4: Parameters of the MWCNT arc synthesis with 6-mm diameter anode rods [8]. 
    
    SWCNTs can also be synthesized by arc discharge process utilizing co-evaporation of 
graphite and metal in a composite anode. The anode is commonly made by drilling an axial 
hole in the graphite rod, and densely packing it with a mixture of metal and graphite 
powders [75, 76]. The amount of catalyst depends on the type of catalyst, but there is clear 
evidence that more nanotubes are formed in the presence of larger amounts of catalysts 
[81]. Several pure elements and mixtures have been used to fill the axial hole of the rod, 
including Fe, Ni, Co, Cu, Pt, Y, Zn, Fe/Ni, Co/Ni, Co/Pt, Co/Ni, Ni/Y, and Ni/Ti [8, 77-80]. 
Among these mixtures, Ni/Y, and Co/Ni catalysts are commonly used in SWCNTs 
synthesis. The metal compounds used as the catalyst in electric arc method at 500 Torr He 
are listed in Table 2.5 [82].  
 
 
Table 2.5: Metals and metal compounds catalysts for SWCNT synthesis (Modified from 
ref. [82]). 
 
   The mixed carbon and metal vapor, which escapes from the gap, condenses into several 
products. Subsequently, these products are traveled to the reactor surfaces and deposited.  
The major products are divided into three distinct structures, depending on the coating 
locations.    (1) Spongy soft belts called collaret, which contains more SWCNTs and metal 
catalysts than other components of products, are formed around the cylindrical deposit,  (2) 
 31
 32
clothlike soot on the chamber walls, and (3) some weblike structure suspended in the 
chamber volume between cathode and walls [8]. All three locations contain different 
amount of SWCNTs, fullerenes, amorphous carbon, and so on.  
SWCNTs are mostly organized in bundles that consist of a few dozen tubes, tightly 
bonded in a honeycomb lattice. The bundles are covered with an amorphous carbon layer, 
which contains embedded fullerenes. The majority of tubes have diameter in the range of 
1.2 to 1.5 nm and the length up to tens of micrometers. The diameter of SWCNT depends 
on the temperature of the catalytic site where the deposition occurs. The temperature is 
regulated by many factors including heating of the reactive zone with an external 
controlled heat source. Takizawa et al. found out that the average diameter of SWCNTs 
increase as the environment temperature increases; moreover, the environment 
temperature also affects the yield of SWCNTs [83, 84]. 
 
2.2.2 Carbon nanotubes growth by laser ablation 
 
    Carbon nanotubes can also be synthesized by laser vaporization apparatus with an 
ablated pure graphite target located in an oven. It was found that closed-ended MWCNTs 
were produced in the gas phase through homogeneous carbon-vapor condensation in a hot 
argon/or helium atmosphere [85]. MWCNTs synthesized by laser ablation are relatively 
short (~300 nm) compare to those by arc discharge. The number of layers deposited by 
laser ablation is ranging between 4 and 24. The inner diameter deposited varies from 1.5 
to 3.5 nm.  The yield and quality of MWCNTs degrade when the oven temperature is 
below 1200?C, and no nanotubes are observed at 200?C. 
Laser system for synthesizing carbon nanotubes can be operated in either pulsed mode 
or continuous mode. Figure 2.6 shows a schematic diagram of the traditional laser ablation 
system for carbon nanotubes growth [86]. A graphite target is loaded in the center of a 
quartz tube furnace that is filled with inert gas. The operating temperature is set at 1200?C. 
The laser beam is focused at the graphite target in order to vaporize and sublime the 
graphite by uniformly bombarding its surface. The carbon species swept by a flow of 
neutral gas are thereafter coated as soot in different regimes: (1) on the conical 
water-cooled copper collector, (2) on the wall of quartz tube, and (3) on the backside of the 
target.  
 
 
 
     Figure 2.6: Schematic of laser ablation setup for carbon nanotubes growth [86]. 
 
 
 33
 34
    Laser ablation is also an efficient route for synthesizing SWCNTs bundles with a narrow 
diameter discrepancy. In the early report of the laser ablation method, high yields with 
conversion of graphite to SWCNTs were reported in the condensing vapor of the heat flow 
tube (>1200?C) [87].Laser ablation can produced SWCNTs by evaporating 
metallic-contained graphite target as well.  
Instead of using furnace-based laser vaporization system, a continuous CO
2 
laser has 
been used. Figure 2.7 is a schematic sketch of a synthesis reactor based system [86]. The 
operating power can be tuned from 100W to 1600W, and the target temperature is 
measured by an optical pyrometer. The floating inert gas acts as a local furnace and creates 
an extended hot zone for enhancing the vaporization of carbon species. The gas was 
extracted through a silica pipe, and the solid products formed are carried away by the gas 
flow through the pipe and then collected on the filter. The synthesis yield can be controlled 
by: (1) the cooling rate of the medium, (2) the residence time, and (3) the temperature at 
which SWCNTs nucleate and grow [86]. The SWCNT yield and properties are reported to 
be relatively sensitive to the processing parameters such as light intensity, type of metal 
catalyst, process temperature, type of carrier gas, flowing dynamic and rate, etc. However, 
laser ablation is able to produce high yield and high quality carbon nanotubes due to 
sufficiently high temperature that rapidly anneal the imperfect fullerene structures into a 
closed form through the incorporation and rearrangement of pentagons [88].  The 
disadvantage of using laser ablation is the lack of large-scale production capability.  
                          
 
      
 
 
 
 
 
                          
  Figure 2.7: Schematic of commonly used laser ablation reactor for SWCNTs growth [86]. 
 
 
 
 
 
 
 35
 36
2.2.3 Carbon nanotubes growth by chemical vapor deposition 
 
Using carbon nanotubes for nanoelectronics, field emission applications require more 
precisely controllable growth on patterned substrate at reasonable rates. This requirement 
can be satisfied by introducing chemical vapor deposition (CVD). One CVD method for 
CNTs growth is thermal chemical vapor deposition, in which a conventional heat source 
such as resistive or inductive heater, furnace or infrared (IR) lamp is used for heating up the 
environment temperature. Another CVD method is so-called plasma-enhanced chemical 
vapor deposition (PECVD), in which the plasma source is used to create a glow discharge 
which contains desirable radicals, electrons, and ions. 
DC, RF (13.56 MHz), or microwave (2.45 GHz) sources can be used to generate plasma 
(Figure 2.8) [8]. A plasma reactor consists of a pair of electrodes in a grounded chamber 
with one grounded and the other connected to a power supply. A breakdown of feed gas 
occurs when a negative bias is applied (>300V) on the cathode. The resulting glow 
discharge composed of electrons, positive and negative ions, atoms, and radicals. The 
separation distance between two electrodes is determined by Pd=constant where P is the 
pressure and d is the distance between two electrodes. This indicates that electrodes need to 
be pulled away further as the pressure is decreased in order to sustain the discharge.  
The electrode holding the substrate needs a separate heat source in order to elevate the 
wafer temperature to a desired growth temperature, and to enhance the nucleation density. 
In carbon nanotubes growth by CVD, precursor dissociation in the gas phase is not 
necessary. However, dissociation at the catalytic particle surface appears to be the key 
point for nanotubes growth. It is necessary to maintain the growth temperature below the 
 37
pyrolysis temperature of the particular hydrocarbon in order to prevent excessive 
production of amorphous carbon [8]. Since the plasma can ionize the hydrocarbon gases 
that create a lot of reactive radicals, pure hydrocarbon feedstock in plasma reactors may 
result in substantial amorphous carbon deposition. It is necessary to dilute the hydrocarbon 
gases with argon, hydrogen, or ammonia. Typical reacting pressures of nanotubes 
deposition is in a range from 1 to 20 Torr. PECVD allows nanotubes to grow at a much 
lower temperature compares to other methods, which makes it attractive for integrating 
carbon nanotubes into the applications of semiconductor device fabrication. Moreover, the 
local electrical field generated between plasma and the substrate holder provides nanotubes 
to grow extremely vertical and high density growth. PECVD enable more vertically 
aligned carbon nanotubes structure growth than thermal CVD does. Whereas any marginal 
alignment nanotubes observed in thermal CVD samples are resulted from crowding effect, 
nanotubes supporting each other by van der Waals attraction. Thus, individual, 
free-standing and vertically oriented structures are possible with PECVD.  
 
 
 
 
 
 
 
 
                   
 
 
                                       
 
      
    Figure 2.8: Schematic diagram of a PECVD setup for carbon nanotubes growth [8].  
 
 
 
 
 
 38
 39
2.2.4 Carbon nanotubes growth mechanisms 
     
Metal catalyst assisted carbon nanotubes growth can be divided into two sections, tip 
growth and base growth. Five major phenomena as followed need to be carefully 
concerned: 
1. Precursors diffusion through a thin boundary layer of the substrate. 
2. Reactive species adsorption at the particle surface. 
3. Surface reactions results in nanotube structure and by-product of hydrocarbon gases. 
4. Desorption of gaseous product species from the surface. 
5. Outgassing species diffusion through the boundary layer into the bulk stream. 
In nanotubes growth, the above steps may proceed differently in thermal CVD and in 
PECVD. For instance, thermal CVD reactor has only a few other species in the gas phase 
besides the feedstock hydrocarbon gases; however, PECVD is specified by a diversity of 
energetic radicals and atomic hydrogen, along with stable higher hydrocarbons and ions in 
the plasma. In low temperature PECVD growth, positive ion bombardment on the substrate 
may provide enough energy for steps (1) and (3) or in aid of desorption in step (4).  In 
thermal CVD or PECVD methods, hydrocarbons or radicals get rid of their hydrogen 
atoms, and eventually breaking some of their C bonds which construct on the particle 
surface to form nanotubes. A hydrocarbon adsorbed on the catalytic particle releases 
carbon upon decomposition, which dissolve and diffuse into the metal particle. When a 
supersaturated state is reached, carbon precipitates in a crystalline tubular form.  At this 
juncture two different situations are possible, one is tip growth and the other one is base 
growth.  The growth and nucleation of carbon nanotubes strongly depend on the diffusion 
process of carbon species through the catalytic metal particles. Louchev?s model gives a 
good explanation of the top and base growth (Figure 2.9) [89]. Two characteristic times are 
defined as (1) the characteristics diffusion time of carbon through the metal nanoparticle to 
the other end, which is the nanotube growing point, given by,  
 40
b                                               
2
/dpR D? =  
where R
p
 is the radius of catalytic metal particle and D
b
 is the diffusion coefficient, and (2) 
the surface saturation time of order 
                                               
22
/sbCD Q? =
where C is the saturation concentration of carbon and Q is the impinging carbon flux. The 
saturation condition of the metal catalytic surface is a function of the carbon species 
contain to the saturation concentration, kindling the carbon precipitation in the outer 
surface of the metal particle. If ?
d 
<< ?
s
, which means the rate of carbon species diffuses 
through the metal particle is much faster than that of the particle surface reaches the 
saturation value, carbon precipitates at the bottom of the catalytic particle, lifting the 
particle during the growing process, resulting in a tip-growth condition. On the other hand, 
if ?
d 
>> ?
s
, which means the rate that  metal particle surface is saturated with carbon is much 
faster than that of carbon diffuses through the body of the particle, a precipitation of carbon 
on the catalytic particle surface occurs, providing a nucleation template for carbon 
nanotubes. Consequently, the nanotube grows out of the surface of the metal particle, and 
the particle remains at the root of the nanotube throughout the growth process, which is 
so-called base growth.  In addition, the diffusion of carbon species also depends on the 
particle adherence to the surface. If the adherence is strong enough, base growth is often 
presented, and if the adherence is weaker, tip growth is mostly occurred.  
 41
    Baker and coworkers [90] implied that carbon filament is formed by decomposing the 
hydrocarbon on the top surface of the metal catalyst. It is then diffuses into the metal 
particle and finally precipitated at the other end of the particle. Mechanisms for carbon 
filament growth depends on the temperature, activation energy, and electron microscopy 
observations. It is generally agreed that carbon nanotube has the same growth mechanism 
as carbon filament due to the visual evidence of catalyst particles on the top or bottom end 
of nanotubes, as they are the case with filament studies.  
Consequently, carbon nanotube growth strongly depends on the nucleation site, the size 
and adhesion of metal particles, and carbon diffusion parameter. The diffusion parameters 
are related to the size and adherence of the metal particles, growth temperature, feeding 
gases, and the character of the metal that used as catalyst.   
 
 
 
 
                                          
 
 
 
 
 
 
 
 
 
 
                     
    Figure 2.9: Schematic of tip and base carbon nanotubes growth mechanisms. On the left 
hand side, the nanoparticle is detached from the substrate on the tip of nanotube, catalyzing 
growth and preventing nanotubes closure. On the right hand side, the nanoparticle remains 
on the substrate, severing as an initial template for nanotubes nucleation.  Figure (a) shows 
the nanoparticle is saturated by carbon species (b) stage of nanotubes nucleation (c) 
post-nucleation growth [89].   
   
 
 
 
 42
 43
2.3 Structure and material properties of zinc oxide nanostructure 
 
2.3.1 Structure of ZnO 
  
ZnO is one of the attractive functional oxides, which is semitransparent. It is also an 
II-VI compound semiconductor. Wurtzite ZnO has a stable hexagonal structure (space 
group C6mc) with lattice spacing a=0.325 nm and c=0.521 nm (Figure 2.10) [12]. Two 
important characteristics of the wurtzite structure are the non-central symmetry and the 
polar surface. ZnO can be simply described as a number of alternating planes consisted of 
tetrahedral coordinated O
2-
 and Zn
2+
 ions, which are stacked alternately along the c-axis. 
ZnO is a wide band gap (3.37eV) compound semiconductor that is suitable for short 
wavelength optoelectronic applications.  ZnO also possesses large exciton binding energy 
(60meV) that ensures efficient excitonic emission at room temperature. Room temperature 
ultraviolet (UV) luminescence has been reported in disordered ZnO nanoparticels and thin 
films. Table 2.6 lists the basic physical properties of bulk ZnO [91].  As the dimension of 
the semiconductor materials continuously shrinks down to nanometer or even smaller 
dimension, some of their physical properties undergo dramatic change known as the 
?quantum size confinement effect?.  The quantum confinement effect leads to an increase 
of the band gap energy of Q1D ZnO, which has already been confirmed by 
photoluminescence [92]. Band gap of ZnO nanoparticles also reported to be size dependent 
[93]   
       Table 2.6: Physical properties of wurtzite ZnO [91]. 
 
The tetrahedral coordination in ZnO leads to a non-central symmetric structure, which is 
one of the most important characteristics of wurtzite nanostructured materials. The lack of 
central of symmetry in wurtzite structure, combined with large electromechanical coupling, 
resulting in strong piezoelectric and pyroelectric properties. The other important structural 
characteristic of ZnO is the polar surfaces. The most common polar surface is the basal 
plane. 
An internal charge of ZnO is created by positively charged Zn-(0001) and negatively 
charged O-(0001
_
) surfaces, resulting in the creation of dipole moment and spontaneous 
polarization along the c-axis as well as a divergence in surface energy [11, 12]. To maintain 
a stable structure, the polar surfaces generally have facets or exhibit massive surface 
reconstructions, but ZnO -+ (0001) are exceptions: they are atomically flat, stable and 
 44
without reconstruction [12, 13]. The other two most commonly observed facets for ZnO 
are {21
_
1
_
0} and {011
_
0}, which are non-polar surfaces and they have lower energy than the 
{0001} facets (Figure 2.11). 
 
 
 
          
Figure 2.10: The wurtzite structure model of ZnO. The tetrahedral coordination of Zn-O is 
shown [12] 
   
    
 
 
 
 45
 46
    Structurally, ZnO has three types of growth directions: <21
-
1
-
0>, <011
-
0>, and ?[0001]. 
Figure 2.9 is the SEM image of the hierarchical ZnO structure [12]. All the growth 
orientations would aggregate together at the center [0001] with the polar surface due to 
atomic terminations; ZnO displays a wide range of novel structures that can be grown by 
tuning the growth rates along these directions. One of the most profound factors 
determining the morphology involves the relative surface activities of various growth 
facets under given conditions. A crystal has different kinetic parameters for different 
crystal planes, which are emphasized under controllable growth conditions. Therefore, 
after an initial period of nucleation and incubation, a crystalline will commonly develop 
into a three dimensional structure with well defined, low index crystallographic faces. 
Figure 2.12 (a)-(c) show a few typical growth morphologies of 1D nanostructures for ZnO 
[12]. These structures lean to maximize the areas of the {21
-
1
-
0} and {011
-
0} facets due to 
the nature of energy minimization. The morphology shown in figure (d) is dominated by 
the polar surface, which can be grown by introducing planar defects parallel to the polar 
surfaces. Planar defects and twins are observed occasionally parallel to the (0001) plane, 
but dislocations are rarely seen [11-13]. 
 
 
 
 
                           
    
 
     
Figure 2.11: ((a), (b)) SEM images of the hierarchical ZnO nanowire junction arrays, (c) 
the growth model of the hierarchical structure [12].  
 
 
 
 
 47
 
 
 
 
 
 
Figure 2.12: Typical growth morphologies of one-dimensional ZnO nanostructures and 
the corresponding facets [12]. 
 
 
 
 
 
 
 
 
 48
 49
2.3.2 Electrical properties of ZnO  
 
Due to the native defects such as oxygen vacancies and zinc interstitials, ZnO 
nanostructured materials are reported to exhibit n-type semiconductor behavior. The 
electrical transport mechanism of ZnO nanowire is still far away from well known; 
however, measurements of electrical properties is in progress.  Li et al. not only reported 
electrical transport measurement of individual nanowires and nanorods but also studied the 
I-V characteristics under diverse oxygen ambient [94-96].  First, ZnO nanowires were 
dispersed and deposited on SiO
2
/Si substrate. Subsequently, photolithography was 
performed to pattern contact electrode arrays. I-V characteristics under different back gate 
voltages, carrier concentration, and mobility have been estimated (Figure 2.13 (a)). Finally, 
the source-drain I
SD
 versus source-drain V
SD
 characteristics are examined for one transistor 
at atmospheric condition (Figure 2.10(b)). As the Gate voltage, V
G,
 increases from -7V to 
3V with1V interval, current increased by 2-3 orders, and the conductivity at 0V of ZnO 
nanowire is calculated to be 2.5S/cm [95]. I
DS
 increases as V
G 
increases from -20 to 20V at 
a fixed V
SD
=2V. This indicates that ZnO exhibits n-type semiconductor behavior (Figure 
2.10(c)) [95]. Further decrease in V
G
 results in little impact on the change current. The 
origin of the n-type ZnO nanowire was related to the presence of the oxygen vacancies 
which demonstrates that a negative gate voltage effectively depletes the electrons in the 
ZnO nanowire and switches the device off [95].  These results indicate that a negative gate 
voltage effectively depletes the electrons in the ZnO nanowire and switches the device off. 
Li et al. also demonstrate the I-V characteristics changed in diverse oxygen ambient, 
which indicates that the absorbed species affect the conductance of the individual ZnO 
nanowire transistors [95]. Measurements were performed in vacuum (10
-4
 Pa), and then the 
oxygen was uniformly introduced into the system. The transfer characteristics were 
executed from -40 to 10 V at a fixed V
SD
 of 2V under different oxygen pressures. The 
results show that the current decreases and the threshold voltage (V
th
) shifts positively as 
oxygen pressure increases. With increasing oxygen pressure, both carrier density and 
mobility decreased; however, the carrier density decreased more rapidly than the mobility 
(Table 2.7) [95]. These phenomena can be explained by the oxygen ions (O
-
, O
2-
, or O
2
-
) 
which are formed by adsorbed oxygen molecules that deprived the electrons in the ZnO 
nanowire. Therefore, more electrons are captured by the oxygen when the oxygen pressure 
increases, which result in the decrease of the carrier density in the ZnO nanowire and the 
expansion of the depletion layer.    
 
                 
Table 2.7 Electron density and mobility measurement under diverse oxygen pressures [95]. 
 
ZnO nanostructures grown by chemical vapor deposition are single crystalline, 
rendering them superior electrical properties than polycrystalline ZnO thin film. Generally, 
an electron field effect mobility of 7 cm
2
/Vs is regarded fairly high for ZnO thin film 
transistors; however, single crystalline ZnO nanowires show mobility as high as 80 cm
2
/Vs 
[14, 97]. A surprising result by Park et al. had reported an electron mobility of 1000 cm
2
/Vs 
 50
 51
after coating the ZnO nanowires with polyimide, which is used for reducing electron 
scattering and trapping at surface [98]. It is believed that ZnO nanostructures device can be 
operated at a faster speed than thin film does. P. Cheng et al. show that vapor trapping 
chemical vapor deposition for ZnO nanostructures growth provides high and tunable 
carrier concentration without incorporating impurities. The carrier concentration can be 
tuned by adjusting the location of ZnO deposition [97]. Depending on the growth location, 
the conductivities of single ZnO nanowires have been estimated to be 8.64?
-1
cm
-1
 and 1.02 
?
-1
cm
-1
, respectively (Figure 2.10(d)) [97]. Not only conductivities, but also carrier 
concentration and mobility show huge difference due to ZnO nanowires growth at different 
locations.   Consequently, using a suitably and uniquely designed synthesis setup, one can 
adjust the carrier concentration and mobility of the ZnO nanowires. 
The major obstacle for ZnO applications rests with the difficulty of p-type doping. 
Joseph et al. obtained low resistivity (0.5 ?-cm) p-type ZnO thin film by using Ga and N 
co-doped method [100]. Look et al. reported nitrogen-doped p-type ZnO with a hole 
mobility of 2 cm
2
/Vs by using molecular beam epitaxy [101]. Successful doping of p-type 
ZnO broadens the application in nanoelectronics and optoelectronics. In addition, 
successful p-type ZnO nanowires can merge with n-type ZnO nanowires for p-n junction 
diodes and light emitting diodes applications. A great improvement of synthesize 
intramolecular p-n junction on ZnO nanowires was demonstrated by Liu et al [102]. 
Anodic aluminum membrane was used as a porous template, and a two step vapor transport 
growth was applied in which boron was introduced as the p-type dopant. Consequently, the 
I-V characteristics demonstrated rectifying behavior due to the formation of p-n junction 
within the nanowire [102]. 
 
 
 
 
(a) 
(b)
(c) 
(d)
 
Figure 2.13: (a) Schematic of ZnO nanowire transistor, a single ZnO nanowire is 
connects to the two electrodes (source and drain) (b) I
SD
-V
SD 
characteristics at different 
gate voltages as V
SD 
varies from 0 to 2V. (c) transfer characteristics as V
G
 varies from -20 
V to 20 V at V
SD
=2V (d) Change of the transfer characteristics of two nanowires grown at 
the same time but different locations. Nanowire A has a mobility of 80 cm
2
/Vs and carrier 
concentration ~10
6
cm
-1
; and nanowire B has a mobility of 22 cm
2
/Vs and carrier 
concentration ~10
7
cm
-1
 [94, 95, 97, 99]. 
 
 
 
 
 52
 53
   2.3.3 Optical properties of ZnO  
 
ZnO exhibits a direct band gap of 3.37 eV at room temperature with a large exciton 
energy of 60meV. This exciton binding energy, which is much larger than that of GaN (25 
meV), and the thermal energy at room temperature (~25meV) can ensure an efficient 
exciton emission at room temperature under relatively low excitation energy. Especially, 
for wide band gap semiconductor materials, a high carrier concentration is usually required 
in order to reach an optical gain that is high enough for lasing action in an electron-hole 
plasma (EHP) process [103]. EHP is typically the key mechanism for conventional laser 
diode operation which needs high lasing threshold. However, an alternative to EHP is the 
excitonic recombination in semiconductors, which can facilitate a lower threshold 
stimulated emission. Due to the high density of free carrier trapping centers usually exist in 
wide-band-gapped semiconductors, the formation of electron-hole pair (exciton) allows 
more efficient radiative process [104, 105]. In order to form stable electron-hole pair at 
room temperature, the binding energy of the exciton must be larger than the thermal energy 
at room temperature, which is why ZnO is regarded as a good candidate for room 
temperature UV lasing. Indeed, when subject to the same excitation condition, the 
photoluminescence of ZnO is much more efficient than that of GaN at room temperature.   
Nanostructured materials are anticipated to further lower the lasing threshold since the 
quantum confinement effect will result in a substantial density of states at the band edges 
and enhance radiative recombination due to carrier confinement [16]. 
Photoluminescence (PL) spectra of ZnO nanostructures have been intensively studied. 
Park et al. have reported excitonic emission from the photoluminescence spectra of ZnO 
 54
nanorods [106]. Gu et al. studied the quantum confinement effect of one dimensional (1D) 
ZnO nanostructures, and shows that the binding energy of excitons in nanorods is 
significantly enhanced due to 1D confinement. The transition responsible for the ?green 
band? often observed in ZnO is seems to be related to free holes [107]. Typical ZnO 
nanorods PL spectra shows fairly strong peak at 380 nm (3.26 eV) due to band-to-band 
transition, which is due to the near-band-edge free exciton emission (3.37 eV) of ZnO. 
Another green-red luminescence band centered at 650 nm (1.92 eV) is also observed, 
which is caused by native defect levels within the band gap, such as structural impurities, 
intrinsic defects due to interstitial Zn ions, ionized oxygen vacancies, and local levels 
composed by oxide antisite defect O
Zn
. It has also been suggested that the green band 
emission is resulted from the singly ionized oxygen vacancy in ZnO and the recombination 
of a photogenerated hole with the singly ionized charge state of this defect [12]. The 
stronger the green luminescence, the more singly ionized oxygen vacancies exist in ZnO 
Recently, red luminescence was also reported, which is contributed by doubly ionized 
oxygen vacancies [108]. Among those defect factors ionized oxygen vacancies is the most 
probably reason for causing the defects. Furthermore, the intensity of green emission 
increases with decreasing the diameter of the nanorods. This observation is contributed by 
the larger surface-to-volume ratio of thinner nanostructures favoring a higher level of 
defects and surface recombination [16,109]. Size reduction causes more atoms to be closer 
to the surface. Hence, as the diameter decreases, the surface approaches the bulk, providing 
a natural energy sink, where defects and impurities can be segregated. Below a certain size, 
the luminescence properties of ZnO nanostructures should be entirely dominated by the 
properties of the surface. In addition, as one of the characteristics of 1D nanostructure, 
 55
quantum confinement was observed to cause a blue shift in the near UV emission peak in 
ZnO nanobelts [110].     
ZnO nanowires/nanorods photoresponse, photoresponse spectrum, and current-voltage 
(I-V) have also been studied for the investigation of photoconduction mechanism of ZnO. 
The photoresponse of the nanowires under the continuous illumination of light with above- 
or below-gap energies was slow, which suggests that photocurrent in the nanowires is 
surface-related rather than bulk-related [111]. The photoresponse spectrum represents the 
above- and below-gap absorption bands for the photocurrents. It is well known that ZnO 
films photoresponse shows a slow delay process in conduction which is controlled by 
surface effects. Since photoconduction of ZnO films is predominantly governed by 
adsorption and desorption of oxygen molecules.  
The photoresponse measurement indicates that the creation of holes by the below-gap 
excitation as well as the above-gap excitation allows chemidesorption of oxygen to occur. 
Hence, the as-grown ZnO nanowires are connected between two electrodes for excited 
electrons to contribute to photoconduction. The photoconduction phenomenon in ZnO 
nanowires reveals that holes generated by both the above-gap and below-gap light 
discharge the negatively charged oxygen ions on the surface of the nanowires. The 
photoexcited electrons are trapped at some centers, and the electrons escaped from the 
centers transit to electrodes [111-113]. Keem et al. reported the photoresponse of the 
nanowires under the illumination modulated at different frequencies of 3, 10, and 30 Hz. 
The intensity of the photoresponse is independent of the illumination time, which indicates 
that the constant number of electrons arrive the electrodes per unit time during the 
illumination modulated at a fixed frequency [111].  
 56
Moreover, they also demonstrated that the intensity of the photoresponse is reduces with 
increased frequency, and no photoresponse was detected at frequencies higher than 100 Hz. 
This reveals that all electrons do not reach the electrodes within 1/100s after 
photoexcitation [111].   
A comparison between photoresponse spectrum and photoluminescence spectrum of 
ZnO nanowires shows that the excitonic band is absent in the photoresponse spectrum even 
though the free-exciton PL peak is presented. This observation implies that excitons 
excited by the above-gap light in the ZnO nanowires do not contribute to the 
photoconduction, but the excitons participate in the recombination to emit the PL signal.  
Keem et al. also shows that the I-V characteristics under the illumination of the 
above-gap light are ohmic, and the characteristics under the illumination of the below-gap 
are Schottky. This indicates that the above-gap light lowers the potential barrier built in the 
contact between the ZnO nanowire and electrodes, while the below-gap light does not. For 
ZnO film, the increase of electron density by photodesorption of oxygen adsorbed on the 
surface of the film narrows the width of the Schottky barrier formed between the film and 
contact electrodes. For ZnO crystallites, photodesorption of oxygens adsorbed on grain 
boundaries lowers the barrier height of the grain boundries [112, 114].  The 
photodesorption of oxygens on the ZnO region contacting the metal may narrow the width 
of the Schottky barrier, or that the photodesorption may lower the height of the barrier. 
This can explain the ohmic behavior for the above-gap light; electrons may have a chance 
to tunnel through the narrowed width of the barrier. However, for the below-gap light, the 
efficiency of the photodesorption of oxygen is lower by four orders of magnitude compare 
 57
to the above-gap light. Consequently, the illumination of the below-gap shows Schottky 
characteristics [111]. 
 
2.3.4 Other properties of ZnO   
 
   Piezoelectricity is one of the important properties of ZnO that has been extensively 
studied for various applications such as acoustic wave resonators, force sensing, 
acousto-optic modulator,etc. The indigenousness of the piezoelectricity lies in its crystal 
structure, in which the oxygen atoms and zinc atoms are tetrahedrally bonded. In such a 
non-centrosymmetric structure, the center of positive charge and negative charge can be 
displaced due to the lattice distortion induced by an external pressure. The displacement 
leads to originate local dipole moments; thus, macroscopic dipole moments appear over the 
whole crystal. Among the tetrahedral bonded semiconductors, ZnO has the highest 
piezoelectric tensor which provides a large eletro-mechanical coupling reponse[115].  
Zhao et al. measured the piezoelectric coefficient of ZnO nanobelts by AFM conductive 
tips [116].  
Another interesting phenomenon of the non-centrosymmetric ZnO structure is the 
spontaneous polarization and polar face dominated nanostructure. The tetrahedral bonds 
were stack at [0001] direction. Due to spontaneous polarization, the positive charge is 
displaced from that of negative charge and the direction of displacement is also [0001]. The 
net result of the spontaneous polarization is a charged (0001) ZnO surface; therefore, in 
order to achieve minimized energy, the charged (0001) surface results in unique nano-ring 
and nano-coil structure [117].  
 58
ZnO has also been found to be the promising host material for ferromagnetic doping. 
Ferromagnetism in ZnO nanowire was reported by Chang et al. Due to its wide band gap, 
ferromagnetic doped ZnO is recognized as an excellent material for short wavelength 
magneto-optical devices [118].  These investigations enable the use of magnetic ZnO 
nanowires as nanoscale spin-based device.  
Functional metal oxide possess oxygen vacancies are electrically and chemically active. 
Oxygen vacancies serve as n-type donors which significantly increase the conductivity of 
oxide. Depends on the adsorption of charged accepting molecules at the vacancy sites, such 
as NO
2
 and O
2
, electrons are effectively depleted from the conduction band, which result in 
a decrease of surface conductivity. However, gases such as CO or H
2
 would interact with 
surface oxygen and consequently remove it, leading to an increase of surface conductivity. 
Fan et al. reported the relationship between oxygen pressure and the performance of ZnO 
nanowire FET and showed that ZnO is relatively sensitive to O
2 
[119]
.  
The gas selectivity 
of NO
2
 and NH
3
 of the ZnO nanowire based FET was also been studied under the gate 
refresh process. Q1D ZnO nanostructures, such as nanorods and nanowires, have the small 
diameter comparable to the Debye length. Therefore, chemisorption induced surface states 
effectively affect the electrical structure of the entire channel, which leads the Q1D ZnO to 
be much more sensitive to chemical reaction, such as oxygen adsorption, than thin film 
[99]. The large surface-to-volume ratio of nanowires not only enhances their gas sensing 
performance, but also facilitates potential hydrogen storage property. 
 
 
 
 59
2.4 Growth techniques of ZnO  
 
2.4.1 ZnO synthesis by metal organic vapor deposition 
 
    Metal organic chemical vapor deposition (MOCVD) is a widely used process for 
synthesizing semiconductor thin film, and has also been used for ZnO nanorod growth. 
Although ZnO thin film and quantum dots growth using MOCVD have been 
well-developed, MOCVD of ZnO nanorods was very recently developed. Yi and 
coworker used catalyst-free MOCVD for synthesizing nanorod and nanoneedle arrays 
[120]. MOCVD provides non-catalyst growth ZnO nanorods, which results in producing 
high purity ZnO nanorods and easy fabricated of nanorod quantum structures. 
    The catalyst free growth mechanism of ZnO nanorods has not been clearly investigated. 
The main reason for anisotropic growth is the anisotropic surface energy in ZnO. 
Moreover, high speed laminar gas flow in a certain growth condition may induce 
turbulent flow between the nanostructures, which results in adsorption of fresh reactant 
gases only on nanorod tips. Since more surface steps exist on nanorod tips, the nanorod 
growth rate is higher on nanorod tips than on side wall. 
     Figure 2.14 is the schematic of MOCVD setup. Diethylzinc (DEZn) is used as the zinc 
precursor and high-purity oxygen is used as the oxidizer [121]. DEZn is introduced into 
the reaction chamber using Ar carrier through a bubbling cylinder kept at constant 
temperature and pressure. Convectional gas flow is suppressed by employing N
2
 as the 
pushing gas forming an annular curtain gas flow around the reactor walls. DEZn and O
2
 
are separately introduced into the reactor through two nozzles and then mixed just above 
the substrate surface to prevent possible gas phase reaction forming powdered 
by-products that may degrade the crystallinity of ZnO nanowires. The operating pressure 
is around 2-3.5 kPa and the substrate temperature needs to be held around 800-900K with 
a desirable growth duration.  
                       
 
                  
                  
            Figure 2.14: Schematic illustration of utilizing MOCVD for ZnO growth [121]. 
    
      
 60
Park et al. have studied the morphology change with respect to the change of growth 
temperature (T
g
) of MOCVD [122].  The morphology of ZnO change dramatically with T
g
. 
At growth temperature lower than 200?C,, no meaningful ZnO structure forms. At 200?C? 
T
g
?260?C, columnar grained, textured ZnO films having a lot of crystalline defects grow. 
At higher growth temperature of 260?C? T
g
?320?C, arrays of vertically well-aligned ZnO 
nanorods grow, and at further higher temperature of 320?C? T
g
?380?C, ZnO of 
nanoneedle shape grows. Finally, at T
g
>380?C, ZnO nanowire start to grow on top of a 
continuous ZnO layer. Figure 2.15 is the cross section SEM images of ZnO grown at 
different growth temperature [122].  T
g
 is one of the key processing parameters and it needs 
to be well-controlled in a narrow regime in order to grow desire ZnO nanostructures by 
MOCVD.   
 
         
 
    Figure 2.15: SEM cross section images of ZnO grown at various growth temperature (a) 
T
g
? 200?C, (b) 200?C< T
g
 ?260?C, (c) 260?C<T
g
 ?320?C  (d) 320?C < T
g
 ?380?C, and (e) 
T
g
> 380?C. The ZnO morphologies grown at those temperature regimes are schematically 
described [122]. 
 
 
 
 61
 62
2.4.2 ZnO synthesis by pulsed-laser deposition 
 
    Pulsed-laser deposition (PLD) is a type of physical deposition, which is usually used for 
semiconductor thin film deposition. PLD have already been widely used for ZnO thin film 
deposition. Okada et al. reported a new method for synthesis ZnO nanorods by applying 
the basic idea of PLD, which is so-called nanoparticle-assisted pulsed-laser deposition 
(NAPLD) [123]. NAPLD, a non-catalyst growth method, is the method that the species 
created by laser ablation are firstly converted into nanoparticles by the condensation in the 
background gas. Then, formed nanoparticles are transported onto a heated substrate where 
nano-structured crystals are synthesized. Since the nanoparticles require a lower melting 
temperature than the same bulk form; therefore, the ZnO nanostructures can be synthesized 
at a relatively lower substrate temperature.  
    A sintered ZnO target or a metal Zn target, which serves as the source for ZnO 
deposition, was ablated using a KrF excimer laser. KrF excimer laser operates at a 
repetition rate of 20 Hz and a fluence of about 3 J/cm2 in a chamber filled with oxygen 
background gas [124]. ZnO thin films have been successfully synthesized in an oxygen 
background gas at a relatively low pressure (approximately 0.1 Torr or less). However, for 
NAPLD, ZnO nanostructures are synthesized in oxygen or He background gas pressure in 
a range from 1 to 10 Torr.  Figure 2.16 shows the schematic of the growth model of crystals 
by NAPLD which can briefly explain the initial growth condition of ZnO nanostructures 
[125].  
     As the nanoparticles formed by condensation of ablated species in gas phase try to 
deposit on a low temperature (~400?C) sapphire substrate, the film is made up of randomly 
 63
aggregated particles. It is suggested that these particles are the trace of the aggregated 
nano-particle in the background gas that can be obviously detected by Rayleigh scattering 
technique. If the nanoparticles were deposited on a high temperature (~700?C) substrate, 
hexagonal ZnO nanocrystal will be uniformly observed and there is no trace of particles. 
Moreover, if the substrate temperature was decreased down to 300?C after the deposition at 
high temperature, the particles were observed to be randomly stuck on the nanorods that 
are deposited at high temperature. Substrate temperature is a key parameter for growing 
nanostructures by NAPLD [123-125].  
    Not only substrate temperature, but also O
2
 background gas pressure and target substrate 
distance affects the nanostructure growth. Micro-sized hexagonal crystals on a uniform 
film are often synthesized at the pressure below 0.1 Torr. At diverse O
2
 pressure form 0.1 
to 10 Torr while the substrate temperature was kept constant, the small size crystals have 
been found at a pressure of 1 Torr. The rod size becomes larger with the increasing pressure. 
When the pressure is increases above 10 Torr, rods fused each other and the top surfaces of 
the rods become flattened.  The reason why the structure change with the changing 
background pressure has not been yet understood; however, it must be corresponded to the 
formation of nanoparticles in the gas phase. At a constant O
2
 pressure, the rods become 
thinner as the substrate-target distance increases In summery, ZnO nanostructures can be 
tuned by suitably adjusting the O
2
 pressure, substrate temperature, and substrate-target 
distance; however, the basic growth mechanisms have not been clarified yet [123-125]. 
     
 
 
 
 
 
    Figure 2.16: Growth model of NAPLD (a) at low substrate temperature (b) at high 
substrate temperature [125]. 
 
 
2.4.3 ZnO synthesis by vapor transport 
  
The growth of ZnO nanostructured materials have been carried out by various 
approaches, such as chemical vapor deposition, physical vapor deposition, molecular beam 
epitaxy, and thermal evaporation. All these methods induce vapor transport and 
vapor-liquid-solid (VLS) mechanism for nanowire, in which a metal or oxide catalyst is 
necessary to dissolve feeding source atoms in the molten state to initiate the growth of 
nanostructured materials [126]. Vapor phase transport means that vapor species are first 
generated by elevated temperature, chemical reduction and gaseous reaction. These source 
species are subsequently transported and condensed onto the surface of a solid substrate 
 64
placed in a zone with a temperature lower than that of the source material. A large quantity 
of 1D nanostructures can be obtained by properly controlled over the supersaturation 
factor. 
Vapor transport techniques can be divided into catalyst free vapor-solid (VS) process 
and catalyst assisted vapor-liquid-solid (VLS) process. VS process usually synthesizes a 
rich variety of nanostructurs, including nanowires, nanorods, nanobelts and other complex 
structures [99]. In this process, ZnO power was decomposed into Zn
2+
 and O
2-
 at ~1350?C, 
the nanostructures are produced by condensing ZnO directly from vapor phase. Yao et al. 
demonstrated that temperature is a critical parameter for the formation of different 
morphologies of ZnO nanostructures by thermal evaporation methods [127]. Figure 2.17 is 
the result of different nanostructures carried out at different temperatures.  Wan et al. 
reported a method of rapid heating zinc pallet at 900?C in air ambient, which is typically 
generates tetrapods like ZnO structure [128, 129].  
 
              
Figure 2.17: Schematic of different ZnO nanostructures growth at different   
temperature zone [127]. 
 
 
VS method obviously provides less geometry control, alignment and precise location of 
ZnO nanostructures. More controllable growth of ZnO nanostructures can be achieved by 
catalyst assisted VLS process. However, different kinds of substrates have different lattice 
 65
 66
mismatch values, which is the key processing parameter for either VS or VLS growth. 
Table 2.8 lists the lattice mismatch of different substrates with respect to ZnO [99].  In VLS 
process, several nanoparticles have been used as catalyst, such as Au, Ni, Cu, and Sn, etc. 
Figure 2.18 shows the schematic of a typical VLS method [99]. The formation of eutectic 
alloy droplet occurs at each catalyst site, followed by the nucleation and growth of 
crystalline ZnO nanowire due to the supersaturation of the liquid droplet. Incremental 
growth of the nanowire taking place at the droplet interface constantly pushes the catalyst 
upwards. Such growth method inherently provides site-specific nucleation at each catalyst 
site. In a VLS synthesis process Zn powder is used as the source material. The substrate is 
coated with Au particles with diameters of tens of nanometers and located adjacent to the 
source. The source and substrate are heated up above the melting point of Zn powder 
(419?C) accompanied with appropriate low concentration of O
2
 flow, resulting in the 
growth of high quality ZnO nanowires.  
There are several controllable parameters such as temperature, pressure (environment 
pressure and wafer (local) pressure), carrier gas (gas species and its flow rate), substrate 
and evaporation time period, which can be controlled and need to be selected properly 
before and/or during the evaporation.  The selection of source temperature depends on the 
volatility of the source material. The pressure is determined according to the evaporation 
rate or vapor pressure of the source material [12]. The substrate temperature usually drops 
with the increasing distance of its location from the position of the source material. The 
local temperature determines the types of product that are originated. Finally, oxygen 
concentration is also a key point for ZnO growth; oxygen affects not only the volatility of 
the source material and the stoichiometry of the vapor phase, but also the formation of the 
products.  
 
 
 
                       Table 2.8: Lattice parameter of several epitaxy substrates [99]. 
     
 
 
   
              Figure 2.18: Schematic of ZnO nanowire growth by VLS process [99]. 
 
 67
2.5 Field Emission of Electrons from Solid Surface 
 
2.5.1 Field emission from metal surface 
     
    Electron field emission is defined by the electrons are extracted form a cold solid surface 
by overcome the surface potential barrier when a negative electric field is applied to the 
solid.  Fowler and Nordheim succeeded in applying wave-mechanical methods to the basic 
theoretical considerations of electron emission from metals under the influence of an 
external electrical field [130]. There are some assumptions for this theoretical model, (1) A 
simple one-band electron distribution using Fermi-Dirac statistics; (2) A smooth, plane 
metal surface where irregularities of atomic dimensions are neglected; (3) A classical 
image force; (4) an uniform distribution of work function. The field emission current 
density can be derived based on the four assumptions, results in 
                                      
3
2
2
( / )exp( / )JAF B F??=?                                    (2.21)                
where A= 1.56?10
-10
 (AV
-2
eV), B=6.83?10
3
 (VeV
-3/2
?m
-1
), ?  is the work function of the 
barrier  that has the unit of eV, F is the applied electric field (V/cm), and the current density 
J is in A/cm
2
. Theoretically, the Fowler-Nordheim theory is applicable only for T=0K. 
However, formula (2.21) is still valid even when T>0K, as long as kT<<? . Sine rarely of 
thermal excitation of electrons diffuses the Fermi level at room temperature; hence, 
formula (2.21) remains valid.  
V is the potential difference applied between two planar electrodes separated by a gap 
distance of d. The macroscopic electric field is found to be E=V/d. However, if the 
 68
electrode surface is not ideally smooth, for example, for a sharp needle, the local electric 
field on the tip is much stronger than the macroscopic field by a factor of ?, so-called the 
field enhancement factor. The local electric field at the emitter surface can be expressed as 
                                         
 
                                                
E
FE
kr
?= =                                                                (2.22) 
where E is the macroscopic electric field between anode and cathode, ? is a function of the 
geometrical shape (geometrical factor); r is the radius, and k~5 at the acme of the emitter. 
Equation (2.21) can be rewritten as  
                                            
3
22
2
( / )exp( / )JA E B E? ???=?                                     (2.23) 
when the local electric field is high enough such that the potential barrier is comparable to 
the wavelength in the solid, electron tunneling through the surface barrier become 
important. The emitted electrons are mostly come from the Fermi level and are affected by 
the work function of the solid? . The total current I as a function of the macroscopic 
electric field can be derived out as  
                                       
3
22
2
( / )exp( / )I EBE? ?????                                             (2.24) 
The relationship above is called the Fowler-Nordheim equation. When ln(I/E
2
) is plotted 
versus 1/E (Fowler-Nordheim plot), a straight line with a slope s that depends on ?  and ? 
is obtained  as 
                                          
3
2
/sB??=?                                                                        (2.25) 
Therefore, the field enhancement factor ? can be calculated from the slope if the work 
function of the tip is known.  
 69
 70
2.5.2 Field emission from semiconductor surface 
 
    An internal electrical field complicates the problem of electron field emission of 
semiconductors. This can be explained by the penetration of an external electrical field into 
the semiconductor surface, by surface state, and by the field emission current through the 
emitter. Electric field penetrates into a semiconductor results in the indeterminacy of forces 
acting on an electron at the surface of the body, and downward bending of the energy bands 
at the surface of the body. The downward bending is prescribed by the particular polarity of 
the emission field (Figure 2.19a).  
The existence of surface states in a semiconductor is usually accompanied by an internal 
retarding field, by an additional potential barrier at its surface (Figure 2.19 b). An internal 
barrier reduces the field emission because it decreases the concentration of electrons on the 
surface layer. In contract with metal where electrons from conduction band are emitted, 
field emission of semiconductor is further complicated by the fact that electrons may be 
emitted from both the conduction and valence band. 
At present, there is no complete theory of semiconductor field emission. Experimentally 
in most case, only log I vs. 1/V (I is the emitted current from the total emitting area, V is the 
voltage applied between the emitter and the anode) which is called Fowler-Nordheim plot, 
was usually plotted. Experimentally, Ge crystal with different doping concentration 
suggested that the emission from all n-type crystals leads to a linear slope in all cases of the 
plot of log I vs. 1/V [149].  The internal retarding field drop is relatively small compared to 
the anode voltage. However, above some particular field, which depends on temperature 
and illumination, the current becomes almost independent of the applied electric field. 
 
Figure 2.19: (a) Schematic diagram of the band bending neat the semiconductor surface 
by strong electric field (b) An internal barrier generated by an internal retarding field. [142] 
 
 71
 72
Electron field emission for display applications has better advantages over conventional 
thermionic electron emission. First, the field emitters that provide electron sources do not 
need to be heated. Therefore, it can eliminate the need for a heating source and circuitry. 
Second, the energy spreading of the electrons emitted from a field emitter is much smaller 
than that from a thermionic emitter. Finally, the emission currents form the field emitters 
can be precisely controlled with controlling the applied voltage.  
 
2.5.3 Field emission from carbon nanotube  
 
    Carbon nanotubes have high conductivity and sharp tip with long and narrow shape 
which are useful for field emission. Recently, there have been growing interests on the 
development of field-emitting cathodes by carbon based material, for a versatility of 
potential microelectronic and display applications. Table 2.9 shows a summary of typical 
values of threshold electric field encountered in flat panel display application for several 
different materials [141]. The definition of threshold electric field, in the case of flat panel 
display application, is the electrical field needed to originate a current of 10mA/cm
2
.   
So far, carbon nanotubes are reported to exhibit excellent behavior for electron field 
emission. . The field emission behavior of CNTs is observed at fields lower than 1 V/?m. 
They have the turn-on electric field at 5 V/?m, typically, and high current densities of over 
1A/cm
2
. The emission current was also reported to be relatively stable, without any 
obvious degradation after a few hundred hours of aging in vacuum.  Dean et al. reported a 
significant phenomenon that in most case, the electron emission was the resonant tunneling 
of electrons from the carbon nanotube through a molecule adsorbed on the tip [131]. The 
adsorbate gives a lower on-set electric field, which indicates that carbon nanotube starts to 
emit electron more easily with the presence of adsorbate. However, adsorbate on 
nanotubes causes early emission current density saturation because of transmission 
through the adsorbate.   
Single tube emission current is constrained due to its ultra small dimensions, but this 
problem can be surmounted by using a large area array of vertically aligned nanotubes or 
nanotube film. However, a high density of nanotubes at the substrate surface does not 
provide high emission site density during field emission. This can be realized in terms of 
the screening out of the electric field by too many nanotubes. Neighboring nanotubes 
screen the electric field of each other; therefore, the enhancement factor is reduced.    The 
aspect ratio and tip sharpness are not the only factors that determine whether a carbon 
nanotube film will exhibit good emission characteristics. An important factor affecting the 
field emission properties is field screening.  
 
Table 2.9: Emission threshold electric fields for various emitter materials [141]. 
 73
 74
Carbon nanotubes which are perpendicular to the substrate surface are considered to be 
the most optimum emitting sources. However, even in this configuration, the density of 
emitting tips (~10
5
cm
-2
) is only a small fraction of the nanotube density (10
8
cm
-2
) [132]. 
Only the tubes that are perpendicular to the substrate with sharp tips or those tubes protrude 
out of the surface emit efficiently. The emission of randomly oriented carbon nanotubes 
under low electric field is dominated by a certain amount of nanotubes that have 
perpendicular orientation to the surface of the film [133]. At high electric field, loops of 
nanotubes might also contribute to field emission. The emission site density increases with 
increasing electric field that applied due to the nanotubes with loose end intend to align 
each other by the outer strong electric field. Those tubes which are bent by the strong 
electric field will emit electrons from the loose end of the nanotubes, which are stick out of 
the surface. The typical field enhancement factor for SWCNT and MWCNT have been 
carried out by F-N slope experimentally. Base on the assumption that the work function is 
5eV, for a single MWCNT the field enhancement factor is ranged form 30000 to 50000 and 
1000 to 3000 for MWCNT film. The turn-on and threshold electric field are 2.6 V/?m and 
4.6 V/?m, respectively, for a typical MWCNT film. For SWCNT film, it exhibits to have 
the field enhancement factor of 2500 to 10000, and the turn-on and threshold electric field 
are 1.5-4.5 V/?m and 3.9-7.8 V/?m, respectively [134, 135].  The field enhancement factor 
for SWCNT is significantly higher than MWCNT which is probably due to the smaller tip 
radius and the smaller curvature radius of SWCNTs.  
Current stability and degradation are also very important factors for display applications. 
For nanotubes, regardless of SWCNTs or MWCNTs, a gradual degradation with time 
under high vacuum of the emission performance has been observed. The degradation is 
 75
probably caused by the ion bombardment of gas phase electron ionization or by ion 
desorption from the anode, both are induced by the emitted electrons. Generally, SWCNTs 
show faster degradation rate than MWCNTs [136]. The pressure during the emission test 
shows great effect on current stability and degradation due to the excess residual gas 
molecules in the chamber. The tips of nanotubes will be destroyed by the gas molecules 
that ionized during aging process. Therefore, emission is more stable under high vacuum.   
Carbon nanotubes for electron field emission applications have also been reported 
recently. Carbon nanotubes for flat penal display were proposed in 1995 to be the most 
promising field emission display [132], and the group in Samsung produced a fully sealed 
4.5 inch three color field emission display in 1999 [137]. Other application, such as using 
carbon nanotubes for lighting elements [138], microwave tubes [139], and X-ray tubes 
[137, 140] have already been demonstrated.  
 
2.5.4 I-V instabilities and arcing protection 
 
Field emission cold cathodes in low power applications are hurdle of obtaining stable 
and reproducible emission characteristics. The problems that cause the degradation and 
premature failure of field emission cold cathodes are ion bombardment due to the residual 
gas molecules ionization of poor vacuum, arcing, resistive heating of emission site, and 
surface migration. Arcing failure, which is the major obstruction for field emission to 
utilize in high current applications, has been recognized to be originated by ionization of 
gas molecules and/or desorbed contaminants. 
 76
Some efforts have been carried out to stabilize the I-V characterization of field emission 
such as passive resistor stabilization, active transistor cathode current limiting, and closed 
loop stabilization. Long life time of current stability has been greatly resolved for 
applications such as flat panel display by using integrated passive resistors that provide 
current limiting.    
 
 
 
 
CHAPTER 3 
SPECIMEN PREPARATION AND CHARACTERIZATION 
 
3.1 Growth process 
 
3.1.1 ZnO nanostructures growth 
 
       ZnO nanoneedles were synthesized by catalyst-assisted thermal evaporation method. 
Figure 3.1 shows the schematic diagram for the thermal CVD reactor used for synthesis 
ZnO nanoneedles. A resistive heater is used to heat the outer and inner quartz tubes and 
the substrate inside the inner quartz tube. A thermocouple is located closed to the inner 
quartz tube in order to precisely measure the reaction temperature. The pressure in the 
quartz can be controlled by a manually throttle valve or a exhaust valve controller, which 
is connected to a mechanical pump, and a manometer pressure gauge. Ar (carrier gas) and 
O
2
 (reactant gas) are introduced into the tube precisely by using mass flow controllers to 
control the amount of flow rate.  
    Different kinds of ZnO nanostructures were obtained by adjusting the thermal CVD 
conditions, such as gas pressure, furnace temperature, gas flow rate, reaction period, 
wafer (local) pressure etc.   
A n-type <100> silicon (Si) wafer was cleaned by the RCA wafer cleaning process, 
dipped in deionized water (DI) for 15 min, and then dried by flowing nitrogen.  After the 
 77
cleaning procedures, a few drops of liquid catalyst solution would be placed on the 
surface of the Si wafer.  The wafer was left in air ambient to dry.  The liquid catalyst 
solution consisted of nickel chloride hexahydrate (99.9999%, NiCl
2
?6H
2
O) diluted in 
ethanol with a weight ratio of 1:100. An alumina boat, 10?1.5?1 cm
3
 in size, was used to 
load the Si wafer.   A small amount of Zinc (Zn) powder (99.998%) was put underneath 
the Si wafer with a 0.5cm gap distance between the Zinc powder and the silicon wafer at 
the bottom of the alumina boat. The alumina boat was then loaded into the center of a 
quartz tube furnace.  The Si sample was heated up to 550?C with a constant flow of 500 
sccm argon.  The reaction time was 30 min at 1 atmosphere gas pressure. After the 
deposition completed and the furnace was cooled down, the sample was unloaded from 
the quartz tube with a white wax-like material deposited on it.  
 
 
 
 
 
 
 
 
 
 
 
 
 78
 
 
 
 
 
 
 
 
 
Transparent 
window 
O2 
Ar 
Stainless steel U shape tube for spacer Sample 
Thermocouple 
Quartz
Exhaust Line 
Quartz tube 
 
   Figure 3.1: Schematic diagram for thermal CVD ZnO nanostructures growth.  
 
 
 
 
 79
3.1.2 Carbon nanotubes growth 
 
    Vertically aligned MWCNTs were synthesized by means of thermal chemical vapor 
deposition.  The Si substrate was cleaned by the same procedures described above. The Si 
substrate was sputter deposited with titanium (Ti), Si, and iron (Fe) sequentially using 
electron beam evaporation or DC sputtering [143]. The Ti layer provides good adhesion 
of the metal coating on the substrate.  A few nanometers thick of silicon layer was 
deposited on top of the titanium before an iron thin coating was deposited on top of 
titanium.  The substrate was loaded into the furnace, heated to 700?C and stay there for 
10min with the feed gas mixture of acetylene (C
2
H
2
) and argon (Ar) at a constant gas 
pressure of 75 Torr inside the quartz tube (Figure 3.2). 
    Vertically aligned SWCNTs were grown by the same method as MWCNTs but with 
different catalyst layer preparation processes. The catalyst layers for SWCNTs [144] 
were composed of Al (aluminum)/Fe/Al.  The first layer of 5nm thick Al was deposited 
by electron beam evaporation.  The first layer Al was oxidized for 12 hrs at 75?C on a hot 
plate in air in order to generate uniform and dense nucleation sites. The oxidation process 
was to allow the aluminum to form aluminum oxide as a support for the subsequently 
deposited iron catalyst thin coating.  A Fe layer was sputter deposited by a DC-
magnetron sputtering gun at a low power level of about 20W~40W to obtain an ultra thin 
layer of Fe (approximately 0.5nm) to be used as the catalyst for SWCNTs growth. The 
third layer of Al was also deposited using a DC-magnetron sputtering gun to obtain an 
ultra-thin layer for catalyst support. The growth process and parameters for SWCNTs are 
the same as that for growing MWCNTs.  
 80
 
 
 
 
 
 
 
Figure 3.2: Schematic diagram for thermal CVD carbon nanotubes growth [143]. 
 
 
 
 
 
 
 
 81
3.2 Electron field emission measurement and setup 
    The samples are loaded into a high vacuum chamber in which the electron field 
emission characterizations of the samples are measured. The chamber is first pumped by 
rotary mechanical pump to the pressure of several mTorr, the turbomolecular pump is 
turn on after the pressure reach mTorr range. The field emissions perform when the 
chamber pressure was lower than 1?10
-6
 Torr. Alumina oxide disks of 60 ?m thick 
served as spacers between the anode and the cathode.  The gap spacing used for ZnO 
nanoneedle measurements was 120?m (two alumina oxide disks) and that for CNT 
measurement was 60?m, respectfully.   
    The anode used for collecting electron field emission current was inserted inside an 
electrically insulating machinable ceramic block with the surface of the anode aligned 
with the surface of the ceramic block. The area of the anode is 1cm in diameter. A 
tungsten rod with hemispherical is attach on the top surface of the anode block in order to 
more precisely align and fix the anode. Spacers are placed between the cathode and the 
electrically insulating ceramic block so that in case the side walls of the spacers are 
coated with conducting materials, there will not be leakage current between the anode 
and the cathode through the conductive side walls of the spacers.  
    Initial FE measurements were done with a background pressure of ~1x10
-6 
Torr at 
room temperature.  Ambient air was leaked intentionally and under control into the 
chamber up to a  pressure of 60 mTorr by means of a needle-valve and an air leak valve.  
The air was leaked into the chamber step by step from low pressure (<2e-6 Torr) to allow 
FE measurement at different air pressures.   After all the measurements were done with 
 82
leaked air, the test chamber was evacuated to the initial vacuum level to examine whether 
the FE properties could recovery to the original level measured in good vacuum. 
    A digital dc power supply (Stanford Research Systems PS235) is used to apply a 
voltage between the anode and cathode. A Keithley 485 picoammeter is used to measure 
the emission current. By using a GPIB card, the power supply and the ammeter can be 
controlled by a desktop computer, by which voltage and current is recorded for further 
evaluations (Figure 3.3).  
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 83
 
 
 
 
 
 
 
                                                                                 
 
Ceramic 
A
Sample 
Spacer 
Power supply 
Anode 
Tungsten rod with  
     hemispherical 
Air leak valve 
Needle-valve 
IEEE 488 IEEE 488 
Linear feed-through 
 
Figure 3.3: Schematic diagram for the field emission measurement setup. 
 
 
 
 
 
 
 
 
 
 
                             
 84
 
 
 
CHAPER 4  
 
RESULTS AND DISCUSSION 
 
 
    Vertically aligned single-walled and multi-walled carbon nanotubes were successfully 
deposited on silicon substrate by thermal CVD. Several ZnO nanostructures were also 
prepared by tuning the processing parameters during thermal evaporation. The field 
emission characterizations of carbon nanotubes and ZnO nanoneedles samples were 
performed and analyzed.  
    Effects of gas pressure on the electron field emission (FE) properties of ZnO 
nanoneedles and carbon nanotubes were investigated. Reversibility and sensitivity of the 
FE of ZnO and CNTs to air pressures were studied for potential applications such as field 
emission display (FED) and vacuum microelectronic devices. The pressure-dependant, 
time-dependant, and pressure-time-dependant field emission behaviors of ZnO 
nanoneedles and CNTs will be compared and discussed. 
 
4.1 Growth of carbon nanotube and its field emission 
 
4.1.1 Growth and field emission property of multi-walled carbon nanotubes 
 
Since the surface of polysilicon (~400?m thick) is too rough that is relatively difficult 
to synthesize high-density or well-aligned carbon nanotubes on top of it. Hence, 
 85
transition metal catalyst thin film is deposited directly onto the polysilicon surface to 
solve the surface roughness and lattice mismatch problems. Moreover, the adhesion of 
nanotubes to polysilicon is poor. On the other hand, with the improvement of Ti adhesion 
promotion layer and the silicon buffer layer, high density carbon nanotubes can be easily 
grown on the polysilicon surface. Figure 4.1 is the SEM picture of vertically aligned high 
density multi-walled carbon nanotubes [143]. 
 
 
                              
        Figure 4.1 SEM image crosssectional view of the side wall of multi-walled carbon 
nanotubes [143]. 
     
 
 86
The length of MWCNTs was approximately 60?m. The sample was densely covered 
with MWCNTs.  Figure 4.2 is the transmission electron microscopy (TEM) image for 
this MWCNTs sample.  The TEM image shows that a few nanotubes attach to the same 
large particle with a diameter of ~80 nm, which is believed to be a piece of titanium layer 
that pealed off from the substrate. This indicated that the roots of carbon nanotubes bond 
strongly with the Ti layer underneath them. 
 
              
    Figure 4.2 TEM photograph of multi-walled carbon nanotubes on silicon with e-
beam evaporation of Ti/Fe/Si metal catalysts. The magnification is 100k [143]. 
 
Field emission measurement of multi-walled carbon nanotubes was first performed at 
2?10
-6
 Torr with the gap spacing of 60?m. Figure 4.3 shows the typical field emission of 
multi-walled carbon nanotubes under high vacuum with the voltage scanned from 0 to 
600V. The electron started to emit at the electric field about 1.2 V /?m. The turn-on 
 87
voltage is determined at the current reaches 10
-7 
A, which indicated the turn-on voltage of 
multi-walled carbon nanotubes is about 2 V/?m. Therefore, these nanotubes are very 
efficient for cold cathode electron emission. 
 
    
       Figure 4.3:  Field emission measurement of multi-walled carbon nanotubes. 
 
4.1.2 Growth and field emission property of single-walled carbon nanotubes 
 
The catalyst layer for SWCNTs is a sandwich structure, Al/Fe/Al. Since Al was first 
deposited on the silicon substrate with further oxidation in air, which allows the Al thin 
film (~5nm) to separate into small pieces of islands, is the adhesion and support layer for 
Fe catalyst to be deposit on top of it. An ultra-thin layer of Fe (~5?) was deposited on top 
of the Al oxide layer, which is anticipated that SWCNTs or SWCNTs bundles would be 
 88
grew due to the ultra small size of catalyst. After depositing the Fe layer, an ultra-thin 
layer of Al (?5?) was deposited on top of the Fe layer in order to confine the Fe 
nanoparticles and also confine the growth direction. Figure 4.4 (a) shows the cross-
sectional image of SWCNTs taken by scanning electron microscopy (SEM).  A silicon 
substrate was densely and uniformly covered by vertically aligned SWCNTs of lengths 
approximately equal to 40?m. The very high density of SWCNTs affected the electron 
field emission current density because of the field screening effect. Raman spectra (not 
shown) indicated that the sample contained single-wall carbon nanotubes with diameters 
about 1.2nm based on the radial breathing mode signal at 190 cm
-1
, the D-band at 1360 
cm
-1
, and the G-band at 1585 cm
-1
. Figure 4.4 (b) is the top view of the SWCNTs sample 
that shows the high density of the CNTs covered the Si substrate with several SWCNTs 
bundles.  
 
 
5 ?m
1 ?m
 
 
 
 
 
  
 
Figure 4.4: (a) Cross section SEM image of SWCNT bundles (b) Top view of SWCNT  
 
    
 
 89
Field emission measurement of single-walled carbon nanotubes was first performed at 
2?10
-6
 Torr with the gap spacing of 60?m. Figure 4.5 shows the typical field emission of 
single-walled carbon nanotubes under high vacuum with the voltage scanned from 0 to 
600V. The electron started to emit at the electric field lower than 1V/?m, and the turn-on 
of the SWCNT is approximately 1.5 V /?m, which indicates that single-walled carbon 
nanotubes are more denser and more easily to emit electron than multi-walled carbon 
nanotubes. 
              
 
    Figure 4.5: Field emission measurement of single-walled carbon nanotubes. 
 
 
 
 90
4.2 Growth of ZnO and its field emission 
 
ZnO nanostructures growth is more complicate than CNTs growth and the growth 
mechanisms are not clear now. Several processing parameters need to concern such as 
growth temperature, substrate, lattice mismatch, catalyst, growth time, gas flow rate, 
kinetic energy, environment pressure and wafer (local) pressure. Figure 4.6 (a) and (b) 
show two SEM images of ZnO nanoneedles which were grown on Si (100) with Au 
liquid catalyst deposit on it.  ZnO were grown at 550?C for 60 min with constant Ar flow 
rate. There does not have additional oxygen feed into the tube since the quartz tube is not 
perfectly leak tight, which provides enough oxygen for ZnO growth.   As the SEM 
images show that ZnO nanoneedles spread out in a cactus-like morphology with many 
sharp tips (~100nm) at their ends, which are relatively easy to generate high local electric 
field between the emitters and the anode. Even though this kind of experiment setup can 
produce ZnO nanostructres but the reproducibility is poor and the structure size is larger 
than we expect, which indicates there are still many processing parameters need to be 
more precisely controlled.  
                           
    Figure 4.6: (a) higher resolution of SEM image for ZnO nanoneedles. Image size: 6?6 
?m (b) lower resolution of SEM image for ZnO nanoneedles. Image size: 20?20 ?m  
 
 91
In order to more precisely control the growth condition, the quartz tube was change to 
a both ends O-ring sealed leak tight quartz tube. The tube is first pumped down to 60 
mTorr, which can guarantee how much reactive oxygen is fed in the tube during growth. 
Argon gas was fed as the furnace was turned on, but oxygen gas was only fed when the 
desire temperature was reached. If oxygen is fed at the same time as argon gas was fed, 
the Zn powder would be oxidized during elevating the quartz tube temperature instead of 
sublimating to vapor.  
ZnO nanostructures dramatically change as we change the Si (100) wafer to Si (111).  
Si (111) does not need any catalyst solution deposit on it, which can greatly improve the 
catalyst contamination problem of Si (100).  Figure 4.7 shows the SEM images of ZnO 
grow on Si (111) under 500 sccm of Ar and 15 sccm of O
2
 at 650?C for 30 min. As the 
SEM images show, there have lots of ZnO nanoneedles (nanotips) spreading out form a 
small ZnO single crystal. The average size of the nanoneedles was smaller than 30nm, 
which is much smaller than the one show in Figure 4.6. Figure 4.7 (c) is the image taken 
at the corner of the sample which exhibits the corner also have the same structure as the 
center of the sample. Therefore, the ZnO was deposit very uniformly onto the Si wafer. 
Moreover, at figure (c) also shows some spring-like structure with lots of ZnO nanotips 
stand on top of it. 
Figure 4.8 shows the ZnO grew on Si (100) with Au liquid solution coated on top it. 
Both samples that show in Figure 4.7 and 4.8 were grew on the same time and the growth 
conditions. As we can see that the structures of these two samples are dramatically 
different, the one synthesis on Si (100) shows lots of individual nanoneedles interacts 
with each other and the growth direction was much more regular than the one grew on Si 
 92
(111), but the size of the tip is approximately 2 times larger then the one grew on Si (111). 
However, the one grew on Si (111) shows smaller tip size and all the tips are grown on 
top of a small ZnO single crystal instead of growing individually. This indicates that even 
the same kind of material is used as the substrate, but different lattice conformations 
cause significant change of the ZnO nanostructures. 
          
 
 
               
(a) (b) 
                                     
(c)
Figure 4.7 SEM images of ZnO nanostructure grow on Si (111) wafer, (a) is the 
magnification of 10K (image size 5?5 ?m), (b) is the magnification of 20K (image size 
2.5?2.5 ?m) and (c) is the edge view of the sample with the magnification of 10K (image 
size 6?6 ?m). 
 
 
 
 93
 
 
   
   Figure 4.8 SEM images of ZnO nanostructure grow on Si (100) wafer, (a) is the 
m
s mentioned in chapter 2 that ZnO has a strong UV peak at 380nm and a broad green 
band emission around 510nm, Figure 4.9 shows the photoluminescence (PL) spectra for 
both Si (100) (Figure 4.8) and Si (111) (Figure 4.7) samples.  PL spectra of the as-grown 
samples were measured at room temperature. As shown in Figure 4.9, both samples show 
a strong and sharp UV emission at 380 nm (3.26eV), which is attributed to the near band 
edge emission of the wide band gap ZnO. The difference is that Si (111) sample shows 
no green emission at 510nm (2.34 eV) while Si (100) sample shows a relatively strong 
green emission at 510nm. The reason for the vanished green emission of Si (111) is still 
unknown, but it is a great improvement that the non-green emission ZnO with relatively 
small structure can be synthesized in a certain given growth condition.   
 
(a) 
(b
 
agnification of 10K (image size 5?5 ?m) and (b) is the magnification of 5K (image size 
10?10 ?m)   
 
A
 94
 
Figure 4.9 PL spectrum measured at room temperature, (a) is the PL spectrum of Si 
(111) sample, which shows no green emission and (b) is the PL spectrum of Si (100) 
sample, which shows strong green emission at 510nm.  
 
 
 
   Field emission measurement of ZnO nanoneedles (sample of Figure 4.6) was first 
performed at 2?10
-6
 Torr with the gap spacing of 120?m. Figure 4.10 shows the typical 
field emission of ZnO nanoneedles with the voltage scanned from 0 to 600V. The voltage 
step is 5V for this scan. Figure 4.10 shows that the electron started to emit at the electric 
field much lower than 1V/?m, and the turn-on of the ZnO nanoneedles is approximately 
2.5 V /?m, which indicates that ZnO also possesses good electron emitter  properties that 
can comparable of carbon nanotubes. The current density for this ZnO sample is lower 
than that of SWCNTs and MWCNTs, which can be explained by the field emission sites 
of the ZnO.  As the SEM images shows above that there are less ZnO nanoneedles at a 
certain area compare to the highly dense carbon nanotubes samples, which results in a 
smaller current density.  Figure 4.11 is the Fowler-Nordheim plot of figure 4.10, the work 
function for ZnO is 5.3 eV; therefore, the field enhancement factor ? can be calculated 
out as 1050. 
 
 95
      
                  Figure 4.10: Field emission measurement of ZnO nanoneedles. 
 
                            Figure 4.11: Fowler-Nordheim plot of ZnO. 
 96
4.3 Field emission measurements under diverse pressures 
 
   A variety of nanostructured materials have been considered for use as an efficient field 
emitter for field emission displays (FEDs) and related vacuum microelectronics 
applications. Carbon nanotubes are considered to be the most promising candidate for 
field emission display (FED) applications because they are small in diameters and large 
in length leading to a very large field enhancement at the tips of the nanotubes.  The field 
enhancement allows high electron field emission current density at low electrical fields. 
A relatively simple fabrication process using screen printing of CNTs paste or chemical 
vapor deposition of CNTs on glass substrates have been reported to have superior 
properties as compared to molybdenum (Mo) micro-tip arrays [145,146]. However, field 
emission for single-wall carbon nanotubes (SWCNTs) and multi-wall carbon nanotubes 
exhibit a permanent decrease in FE current density and an increase in the turn-on 
electrical field in oxygen environments [147].This degradation phenomenon greatly 
impacts CNTs application in FED under poor vacuum or low-pressure gas filled 
environments. Besides the geometric factor (aspect ratio), thermal stability, and ambient 
insensitivity are also important factors for choosing a material for applications as cold 
cathode electron field emitters 
    An FED is assembled using hundreds of micrometre spacers as supports between the 
anode and cathode plate and must be sealed using fritted glass under vacuum. The 
vacuum level normally deteriorates from an initial evacuated pressure of?10
?7
 Torr to 
10
?6
?10
?5
 Torr due to outgassing from device components and the phosphor during the 
vacuum-sealing process. The residual gas or gas liberated by electron bombardment of 
 97
FED components interacts with field emitters and has a negative effect on device 
properties during display operation, showing a decrease in emission current and an 
increase in turn-on field, resulting in a decay of luminance of the FED. Environmental 
stability is one of the main requirements for field emitters in FED applications. 
    Field emission measurements of ZnO nanoneedles have already been reported to be a 
valuable candidate for field emission application in high vacuum [148]. Therefore, ZnO 
were executed in this research due to the degradation phenomenon of CNTs under poor 
vacuum. Moreover, ZnO has a relatively high melting point (1975?C) and is believed to 
have a more stable phase under oxygen ambient as compared to carbon nanotubes. The 
electron field emission current density depends on the nanostructures of ZnO.  The 
shapes especially affect the aspect ratios and in turn the field enhancement at the electron 
emission sites. ZnO electron field emission properties have been measured in a fairly 
large gas pressures range and its electron field emission properties are characterized and 
compared with both MWCNTs and SWCNTs in the same experimental conditions. 
 
4.3.1 ZnO nanoneedles field emission measurement under diverse pressures 
     
    FE measurement of ZnO nanoneedles was initially performed at 1x10
-6
 Torr with 
applied voltage being scanned from 0 to 800V.  The gap spacing between the anode and 
the cathode was 120?m.  The electron field emission current shown in Figure 4.8 curve (a) 
was 5.8x10
-7
A that is much smaller than that for both MWCNTs and SWCNTs at the 
same applied electric field of 4V/?m as shown in Figure 4.9 and 4.10. ZnO nanoneedles 
and MWCNTs have approximately the same turn on voltage but the current was higher 
 98
for MWCNTs since MWCNTs has the higher aspect ratio and much more electron field 
emission sites than the ZnO sample as shown in the SEM figures given above.  Shown in 
Figure 4.12 were data taken when the chamber pressure was adjusted from 1x10
-6
Torr 
(curve (a)) to 0.5mTorr (curve (b)), 3.5mTorr (curve (c)), 30mTorr (curve (d)), and then 
60 mTorr sequentially. After measuring the FE with intentional air leaks, the chamber 
was pumped to 1x10
-6
 Torr again to study the pressure effects on the recovery of the FE 
properties. 
The FE test results shown in Figure 4.8 for ZnO nanoneedles under different gas 
pressures, show that the electron emission currents decreased with the increasing turn-on 
voltage when the air leak increased. At a fixed applied electric field of 4V/?m (see Figure 
4.12) the emission current for curve (b) (0.5mTorr) is smaller than curve (a) by more than 
60% and that the emission current shown  by curve (d) (30mTorr) is about 10 times 
smaller than that shown by curve (a).  This indicates that the electron field emission 
current was approximately 10 times smaller for the air pressure of 30mTorr compared to 
that measured at a low pressure of 1x10
-6
 Torr.  The curve (e) shown in Figure 4.12 
represent data measured at 60mTorr with applied voltage being scanned from 0V to 380V. 
Gas breakdown of the gas occurred when the applied voltage was greater than 400V.  The 
larger gap spacing used for ZnO due to its long needles and surface morphology also 
contributed to the premature breakdown at a lower voltage, too, because the probability 
for emitted electrons to cause impact ionization of air molecules was higher with a larger 
gap spacing.   
 99
 
Figure 4.12 I-E curves of field emission of ZnO nanoneedles measurement at varied air 
pressures: (a) 1x10
-6 
Torr, with the cross marks (b) 0.5mTorr, with the asterisk marks (c) 
3.5 mtorr, with the plus marks, (d) 30mTorr, with the diamond marks (e) 60mTorr, which 
is the curve that overlapped with curve (d) up to 3V/?m  
 
 
4.3.2 SWCNT & MWCNTs field emission measurement under diverse pressures 
 
Figure 4.13 and 4.14 are the FE measurements at different gas pressures for MWCNTs 
and SWCNTs.  The experimental procedure followed that used for ZnO nanoneedles. 
Figure 4.13 shows that when gas pressure increased from 1x10
-6
Torr to 60mTorr, the 
turn-on voltage of MWCNTs increased from 2V/?m to 5V/?m with greatly decreased 
electron field emission current.  Electron field emission current measured in vacuum at 
1x10
-6
 Torr was 3 orders of magnitude higher than that measured at 60mTorr under the 
 100
same applied electric field of 3V/?m, which indicated that MWCNTs were damaged 
during measuring under air leakage.  Figure 4.14 shows a more apparent result of the 
SWCNTs emission current that decreased as the gas pressure increased while the turn-on 
voltage increased greatly due to the increasing of air leakage.  For example, as shown in 
Figure 4.14, the turn-on voltage was 0.8V and emission current was 1x10
-5
A (at 
E=3V/?m) when measurement was done in vacuum at 1x10
-6 
Torr.  The turn-on voltage 
increased to greater than 6 V/?m for measurements done at 60mTorr.  It also indicates 
that there was practically no emission current (<1x10
-12 
A) at the applied electric field of 
3V/?m. The faster increase in the turn-on voltage for SWCNTs than MWCNTs when the 
measurements were done under increasing air leakage and therefore increasing air 
pressure suggested that FE measurements at high pressures caused the ionized gas 
molecules to accelerate and collide more frequently with carbon nanotubes resulting to 
more damages to the tips of carbon nanotubes. 
 
 
 
 101
                     
Figure 4.13 I-E curves of field emission of MWCNTs measurements at varied pressures 
(a) 1x10
-6
 Torr, with the cross marks (b) 0.5mTorr, with the asterisk marks (c) 3.5 mtorr, 
with the plus marks, (d) 30mTorr, with the diamond marks (e) 60mTorr, with the dark 
circles. 
 
                     
Figure 4.14 I-E curves of electron field emission of  SWCNTs measured at varied 
pressures  (a) 1x10
-6
 Torr, with the cross marks (b) 0.5mTorr, with the asterisk marks (c) 
3.5 mtorr, with the plus marks, (d) 30mTorr, with the diamond marks (e) 60mTorr, with 
the dark circles. 
 
 102
4.3.3 Field emission pressure effect of ZnO nanoneedles and CNTs 
 
     In order to prove this assumption that CNTs were damage athigh pressure, the 
chamber was evacuated down to 1x10
-6
Torr again for testing the FE after the FE 
measurements were performed at high pressures.    Figure 4.15 shows the low pressure 
FE measurement for ZnO nanoneedles before and after testing at high pressures, showing 
that the FE of ZnO nanoneedles was nearly the same  even after the FE tests were 
performed at high pressure. This demonstrates that ZnO nanoneedles were not as easy to 
be damaged as carbon nanotubes by subjecting to FE measurements with air leakage.  
Considering that the series of measurements done for varied gas pressures as shown in 
Figures 4.12 and 4.15 were carried out for the same sample, the ZnO nanoneedles proved 
to be a more robust and inert electron field emitter than carbon nanotubes under poor 
vacuum environments.  
Shown in Figure 4.16 and 4.17 are data obtained from FE measurement carried out in 
vacuum without air leakage for MWCNTs and SWCNTs.  It shows that after being 
subjected to high pressure measurement, the electron field emission current decreased 
with increasing turn-on voltage even after the chamber was pumped down to high 
vacuum.  As shown in Figure 4.17, the FE measurements for SWCNTs manifested that 
SWCNTs suffered severe structural damages during FE measurements at high pressures.  
The undesirable effect of absorbed O
2
 on the tips of CNTs was believed to also result in 
reactive etching/oxidation of CNTs [42, 43].  
 103
          
Figure 4.15: I-E curves of field emission measurements for ZnO nanoneedles at low 
pressure before (a) and after (b) measurements carried out at higher pressures. 
          
Figure 4.16: I-E curves of field emission measurements for MWCNTs at low pressure 
before (a) and after (b) measurements carried out at higher pressures. 
 
 104
               
Figure 4.17: I-E curves for Field emission measurements for SWCNTs at low pressure 
before (a) and after (b) measurements carried out at high pressures. 
 
 
4.4.4 Low and high pressure current stability of ZnO and CNTs 
 
Shown in Figure 4.18 are data obtained from FE stability tests for both ZnO and 
MWCNTs in vacuum at 1x10
-6
Torr and at 0.5mTorr with a constant applied electric field 
of 4V/?m. Curve (a) and (b) in Figure 4.18 are for MWCNTs FE stability tests at low 
pressure and high pressure, respectively. Curve (a) shows that the emission current for 
MWCNTs at low pressure was still high even the emission current became about 1/3 
smaller than the initial emission current after a 5 hours stability measurement.  On the 
other hand, the FE stability tests for MWCNTS at high pressures showed rapidly 
decreasing electron emission current from the initial emission current of ~1x10
-5
A to less 
than 1x10
-9
A after a 5 hours testing.   Comparing to curve (d) for ZnO nanoneedles, the  
 105
FE stability test shows that even at the high end of the pressure range being examined, 
the electron emission current decreased only by half  from the initial electron field 
emission current.  This indicates that the ZnO nanoneedles emitters are still stable even 
after being subjected to FE measurements at high pressure for a long period of time. 
Curve (c) in Figure 4.18 shows the FE stability test of ZnO nanoneedles in vacuum.  A 
much more stable electron field emission current was recorded.   
The more stable electric field emission current in high pressure was suspected that in 
high pressure there are more ionized gas molecules, which bombard the ZnO nanoneedles 
surface, cause the spiking tips to be damage. Therefore, it would generate more uniform 
local electric field between the ZnO nanoneedles and the anode. The one directly 
measured in low pressure have more spiking tips that cause a gradient of local electric 
field, and result in a more fluctuated emission current. This phenomenon can also be 
found in figure 4.15 that curve (a) is more unstable that curve (b) that underwent a high 
pressure field emission measured process.  
FE tests for ZnO nanoneedles under air leakage and FE stability measurements 
demonstrated that ZnO is a better electron field emitter material than carbon nanotubes 
for electron field emission operation in poor vacuum or with air leakage.  It also 
demonstrated good long-term stability even when the air pressure was at 0.5mTorr.  ZnO 
can be a very useful cold cathode material for vacuum microelectronics and field 
emission displays.                                                                                                            
In summary, both CNTs and ZnO nanoneedles serve as excellent electron field 
emission cold cathode with low turn-on electric fields in high vacuum. However, ZnO 
nanoneedles can recover their FE properties even after being subjected to FE 
 106
measurements at high pressures up to 60mTorr by introducing air into the test chamber.   
ZnO nanoneedles is more favorable than CNTs as cold cathode for applications in poor 
vacuum and in low pressure environments filled with oxidizing gases. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 107
 
 
 
 
 
Figure 4.18 Stability measurements for both MWCNTs and ZnO nanoneedles in vacuum 
at 1x10
-6
 Torr and a higher pressure at 0.5mTorr at a constant applied electric field of 
4V/?m: 
(a) MWCNTs stability test in vacuum (b) MWCNTs stability test at 0.5 mTorr (c) ZnO 
nanoneedles stability test in vacuum (d) ZnO nanoneedles stability test at 0.5 mTorr. 
 
 
 108
 109
 
 
 
 
CHAPTER 5 
 
SUMMARY AND FUTURE DIRECTIONS 
 
 
Phenomenal progress has been made in the science of carbon nanotubes since the 
publication of Iijima?s paper in 1991. Synthesis of vertically well-aligned MWCNTs and 
SWCNTs is under a mature stage which can be manufactured in small quantity and be 
purified. However, how to synthesis carbon nanotubes at desired direction, which means 
how to control its chirality is still blurry, and need to have future investigations. 
Theoreticians have predicted predominant electronic and mechanical properties, and 
many of these predictions have been confirmed experimentally. Carbon nanotubes is a 
extraordinary material for nanoelectronics application such as: nano-sized tweezer, 
interconnection for VLSI, single electron devices, sensor, field emission display, 
hydrogen storage, etc. However, how to integrate nanotubes into efficient device is still a 
challenge in fabrication and large scale production.   
Even though ZnO thin film has been investigated in 1960 and related devices have 
been mass produced, ZnO nanostructured materials are only under incubating stage since 
the passed twenty first century. Due to the small in size ZnO nanostructured materials 
show greatly different in electrical, optical, and chemical behaviors. The growth 
mechanisms of ZnO nanostructured material are still under study. How to synthesis 
 110
vertical array ZnO nanowires is the further step for utilizing ZnO nanowires for electrical 
and optical applications.  P-type doped ZnO is an important stage for diode applications.  
Field emission electron source is one of the most advanced and broadly studied 
applications of CNTs and ZnO.  In spite of the high work function (~5eV), CNTs emit 
electron very easily, compared to other carbon based materials. This is due to their 1D 
structure with a high aspect ratio, and high electrical conductivity.  However, the field 
emission degradation behavior under high pressure is an important concern of carbon 
nanotubes for FED applications, and needs future improvement. The establishments of 
inexpensive synthetic routes and preparation methods of aligned CNT films, as well as a 
clarification of the mechanism are strongly desired for future development.    
ZnO nanoneedles is a powerful material for low and high pressure field emitters due to 
its inert field emission behavior under diverse pressure effects. However, synthesis high 
density ZnO nanoneedles array is a challenge for improving its field emission current 
density. ZnO can be a very potential material if we can overcome the problems such as:  
(1) controllable structural growth (2) large scale production (3) growth mechanism (4) p-
type doping, etc. Since ZnO nanostructure surface is very sensitive, and changes with 
different environment; therefore, how to find a method to efficiently control its surface 
properties, such as surface resistance, chemical reactions, optical properties, will greatly 
improve its versatile applications.  
In these work, MWCNTs and SWCNTs have been successfully deposited on different 
kinds of catalyst layers by using thermal CVD. The catalyst size and nucleation site are 
the critical parameters for synthsis SWCNTs, since the size of the catalyst is the base for 
nanotubes growth, which directly affects the circumference of the nanotubes. Another 
 111
important role is played by the growth time. Field emission results from coated carbon 
nanotube show clearly Fowler-Nordheim behavior. Carbon nanotube films with turn-on 
electric fields as low as 1.5 volt per micrometer and field enhancement factor as high as 
2000 have been achieved.  
Several ZnO nanostructures have been fabricated by tuning the processing parameter 
such as, gas flow rate, growth temperature, local (wafer) pressure, environment pressure, 
etc. ZnO nanoneedles have been synthesized by thermal evaporation with a certain kind 
of growth parameters. Field emission from coated ZnO nanoneedles showed trun-on 
voltage as low as 1 volt per micrometer, but with lower current density, which maybe 
result form spare ZnO nanoneedle sites.  
Many obstacles still remain. From field electron emission application?s point of view, 
several problems should be solved in order to obtain a better field emission performance. 
The alignment, length, growth direction uniformity of carbon nanotubes and ZnO need to 
be well controlled. The density of carbon nanotubes and ZnO should be optimized to 
eliminate the field screening effect.  The growth and field emission mechanisms with 
pressure effect for carbon nanotubes and ZnO need to be deeply investigated. 
                                                    
 
 
 
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