zno nanofiber
TRANSCRIPT
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Synthesis and characterization of ZnO
nanorods
By
Akshay Gupta B.tech E.P. 3
rd
yr DTUAnurag Chopra B.tech E.P. 3
rdyr DTU
SYNTHESIS
INTRODUCTION (aguilarc86210.pdf)
The synthesis of one-dimensional nanostructures such as carbon nanotubes, semiconductor
nanowires, metal-oxide and metallic nanowires have attracted wide attention since their
inception. The high surface area architectures and potential quantum confinement effects have
found use in a myriad of applications beyond piezoelectrics such as novel electronic devices,
quantum computing, chemical and biological sensing, solar cells, thermoelectrics, nanolasers,
photonics, and optoelectronics.
There are a variety of synthetic strategies that have been exploited to achieve 1D growth and
the most popular technique to produce nanostructures with controlled size, crystallinity and
chemical composition are
1. Chemical Vapor Deposition (CVD) (VLS approach)2. Hydrothermal Synthesis
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Chemical vapor deposition (CVD)-
Vapor species are first produced by evaporation, chemical reduction, and gaseous reaction.
After that, the species are transferred and condensed onto the surface of a solid substrate.
Generally, the vapor phase synthesis process is carried out at higher temperatures from 500 C
to 1500C and produces high-quality nanowires. Of the various approaches that utilize CVD, the
vapor-liquid-solid (VLS) approach has been the most successful. Therefore, our focus in this
report was the VLS method.
Vapor-Liquid-Solid Synthesis
VLS requires the diffusion of a gaseous reactant intonanometer-sized liquid droplets of a catalyst metal,
immediately followed by the nucleation and growth
of single-crystalline 1-D nanostructures (Figure 1).
Various inorganic materials such as carbon
nanotubes, classical semiconductors of silicon (Si)
and germanium (Ge), III-V semiconductors of
gallium arsenide (GaAs), gallium nitride (GaN),indium phosphide (InP), II-VI semiconductors of zinc
selenide (ZnSe), cadmium telluride (CdTe), and
metal-oxides of zinc oxide (ZnO),tin dioxide (SnO2),
have been produced with the VLS method.
Compared to other vapor phase techniques, VLS
method is a simpler and cheaper process, and is
advantageous for growing ZnO on large wafers.
The VLS process has been widely used for thegrowth of 1D nanowires and nanorods. A typical
VLS process is used with nanosized liquid metal
droplets as catalysts. The gaseous reactants
interact with the nanosized liquid facilitating
nucleation and growth of single crystalline rods and
Figure 1. Schematic representation of Zn
nanowire growth mechanism (056.pdf)
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wires under the metal catalyst. Typical metal catalysts in the VLS process are Au, Cu, Ni, Sn, and
so forth. ZnO nanowires have been successfully grown on sapphire, GaN ,AlGaN ,and ALN
substrates through the VLS process. The quality and growth behavior of the ZnO nanowires are
strongly affected by the chamber pressure, oxygen partial pressure, and thickness of the
catalyst layer.
Single crystalline zinc oxide (ZnO) nanowires have been grown on Si (100) substrates by a vapor-
liquid-solid (VLS) process at temperatures in the range 850-950 C in an inert atmosphere.
Figure 2 shows proposed mechanism of the VLS growth of the ZnO nanowires.
The Au thin film on Si substrate annealed at 500 C for 30 min was expected to form nanosized
Au-Si alloy droplets as the eutectic point of Au-Si binary system is about 363 C on the basis of
their phase diagram. An AFM image of the annealed Au/Si substrate indicates that the
annealing process leads to the formation of the Au-Si alloy nanoparticles having a mean
diameter of 25 nm (Figure 2). The ZnO nano-wires might be nucleated on the Au/Si alloy
nanoparticles. As the temperature increased to ~900 C, the ZnO was reduced by graphite and
CO(g). The corresponding chemical reaction can be expressed as:
ZnO(s) + C(s) Zn(g) + CO(g) (1)
CO(g) + ZnO(s) CO2(g) + Zn(g) (2)
Zn(g) + CO(g) ZnO(s) + C(s) (3)
C(s) + CO2(g) 2CO(g) (4)
The gaseous products produced by reactions (1) and (2) would adsorb and condense on the
alloy droplets. Subsequently, the following reaction (3) is catalyzed by the Au-Si alloy at solid-liquid interface. As the substrate temperature decreases, the alloy droplets form the spherical
caps on the ZnO nanowires. The substrate surface indicated a light or dark gray color after
reaction.
Figure 2. Schematic illustration of vapor-liquid-s
nanowire growth mechanism (a) Au film deposit
(b) alloy nanoparticles formation; (c) absorption
nucleation; (d) epitaxy growth
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ADD IMAGES FROM 628.pdf figures 1 to 7
all with description
Analysis of Zno nanorods
synthesized by VLS
ZnO nanowires were synthesized on the Si
(100) substrate by VLS growth process
using Au as catalyst. The process leads to
the formation of oblique ZnO nanowires
on the Si substrate without buffer layer.
The SEM and TEM analyses of ZnO
nanowires indicate that the ZnO
nanowires grow epitaxially as hexagonal
poles along [0001] direction. The ZnO
nanowires have diameters ranged from 60
to 100 nm and lengths 1-3 m.
The XRD, XPS and EDX analyses provide the evidence for the presence of small amounts of
silicon in the nanowires. The ZnO nanowires are stoichiometric and are found to emit UV light
at
room
temp
erature.
Figure 3. AFM image of Au-Si alloy nanoparticles with
mean diameter of 25 nm
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Figure 4. XRD pattern of ZnO nanowires grown on a
silicon (100) substrate
Figure 5 (a) The top view of SEM ima
of ZnO nanowires; (b) the 45tilted v
of SEM images of ZnO nanowires;
cross section SEM images of
nanowires
Figure 6. (a) TEM image of ZnO nanowire with a
Au-Si alloy tip; (b) High-resolution TEM image of a
single crystalline ZnO nanowires and thecorresponding electron diffraction pattern as
shown in inset
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Figure 7. EDS spectra on (a) tips of the ZnO
nanowires (b) ZnO nanowires pattern as shown in
inset
Figure 8. XPS spectra of the synthesized ZnO nanowires, (a) f
range surveyed spectra; (b) zinc 2P 3spectra; (c) oxygen 1s spect
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Gas-phase approaches are favored for their simplicity and high-quality products, but these
generally require economically prohibitive temperatures of 800900 C. Despite recent MOCVD
(metal organic chemical vapor deposition) schemes that reduced the deposition temperature to
450 C by using organo-metallic zinc precursors, the commercial potential of gas-phase-grown
ZnO nanowires remains constrained by the expensive and/or insulating (for example, Al2O3)
substrates required for oriented growth, as well as the size and cost of the vapor depositionsystems.
Thus, high temperatures, expensive substrates and small growth chambers ultimately limit the
VLS method from adoption into higher-production facilities. A low-temperature, large-scale,
and versatile synthetic process is needed.
and
Solution Phase Synthesis
Solution phase synthesis has many advantages when compared to vapor phase synthesis, such
as
inexpensive substrates,
low growth temperature,
Figure 8. Photoluminescence spectra of ZnO
nanowires at room temperature
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less hazardous,
use of simple equipment,
good potential for scale-up,
no need for use of metal catalysts, and
ease of handling.
Thus, solution synthesis methods allow for a greater choice of substrates including inorganic
and organic substrates. Due to the many advantages, solution phase synthesis methods have
attracted increasing interest. In solution phase synthesis, the growth process could be carried
out in either an aqueous or organic solution or a mixture of the two.
The ZnO nanowires are grown using a two-step wet strategy, whereby each step is
systematically optimized. In the first step, substrate surfaces are prepared with ZnO
nanocrystals of various shapes and sizes. In the second step, oriented nanowire growth from
the catalyst seeds is accomplished in a diluted aqueous solution at low temperature. By
separating the nanoparticle film nucleation and oriented growth into two separate steps, the
architecture of the nanowire array can be controlled.
ZnO is a nontoxic n-type semiconductor that can be
grown as crystalline nanowire arrays in a variety of
facile conditions. The developed approaches for
growing oriented nanostructures of ZnO in solution
are all based on a controlled nucleation and growthprocess. According to the fundamental theory of
nucleation and growth, the free energy of forming
stable nuclei on a substrate can be roughly controlled
by four factors according to the equation:
G = -RT*ln S + p-l+ (p-ss-l) * Ap-s
where S is the degree of supersaturation, p-l is the interfacial energy between the particle(p) and the liquid (l), p-s is the interfacial energy between the particle and the substrate (s),
s-l is the interfacial energy between the substrate and the liquid s-l, and Ap-s is the surface
area of the particle. If the number of nuclei (N) is plotted as a function of the degree of
supersaturation, a window where nucleation is favoured for oriented nanostructures can be
seen from figure 9.
Figure 9. Diagram of Nucleation and
Growth
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Usually, oriented nanostructures are difficult to grow in solution because most syntheses are
conducted at high precursor concentrations where massive precipitation dominates the
reaction. Using the thermodynamic equation and figure 9, a comprehensive synthetic method
was designed and relied on the following factors:
1. The narrow window of the diagram dictates that the precursor concentration must be
sufficiently high to ensure nucleation and growth can occur but low enough to limit the
degree of precipitation. In order to restrain the degree of supersaturation, the precursor
concentration was kept low and the reaction temperature was reduced as much as
possible.
2. In order to ensure nucleation is favoured on the substrate rather than in solution, the
surface was functionalized. Surface functionalization has been a widely adopted method
to decrease the interfacial energy between the substrate and the particle and readily
presents an efficient technique to aid in oriented growth. The functionalization also
enabled a degree of latitude to separately form stable nuclei and deposit them on the
substrate. Accordingly, various nuclei were produced in separate reactions and
deposited onto a substrate to gauge which produced the best nanowire array.
3. The orientation of nanostructures grown on substrates in solution can be achieved
through several techniques. First, the crystal structure of the as-grown nanowire must
permit anisotropic growth. For ZnO, the thermodynamically stable crystal structure is
hexagonal wurtzite (6mm), which can be viewed as hexagonal close packing of oxygen
and zinc atoms in space group P63mc with the zinc atoms in tetrahedral sites (point
group 3m). The occupancy of four of the eight tetrahedral sites of the hexagonal lattice
controls the structure, with a hexagonal wurtzite ZnO crystal exhibiting a basal polar
oxygen plane (000), a top tetrahedron corner-exposed polar zinc face (0001)and six low
index nonpolar faces {100} parallel to the c -axis (Figure 10). Since the polar faces are
metastable and the nonpolar faces are very stable, an inherent asymmetry exists along
the c-axis, which allows for anisotropic growth of the crystal along the [0001] direction.
4. Next, the kinetic growth of the nanostructures must be augmented so oriented
structures grow rather than non-oriented structures. Oriented growth can be achieved
through the addition of organic growth factors that regulate the growth and orientation
of specific crystalline planes. Growth factors that selectively bind to the nonpolar {100}
crystal faces and inhibit radial growth permit an effective medium to tweak the aspectratio of the nanostructure as well as shape its orientation. An additional technique to
encourage orientation is through competitive growth, whereby neighbouring growing
crystals impede unaligned growth and only allow oriented nanowires to grow. The
orientation of the growing nanostructures can also be influenced by the manner in
which the catalyst seed lays on the substrate. A combination of these techniques was
employed, textured nuclei were first formed in situ on a substrate to promote growth
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along the c-axis and an amine-rich polymer (low molecular-weight polyethylenimine)
was introduced to the solution to impede radial growth of the nanowires.
Utilizing the guidelines above, a synthetic strategy for growing piezoelectric nanowires of ZnO
with high orientation on plastic substrates was developed. The synthetic platform is able to
produce dense, (>1010per cm2) ordered arrays of highly crystalline nanowires directly on a
variety of flexible organic substrates.
Hydrothermal synthesisGenerally, solution phase synthesis is carried out in an aqueous solution, and the process is
then referred to as the hydrothermal growth method. Hydrothermal methods have received a
lot of attention and have been widely used for synthesis of 1D nanomaterials. In addition,
hydrothermally grown ZnO nanowires have more crystalline defects than others primarily due
to oxygen vacancies. Nanowires with inherent defects are capable of exhibiting visible light
photocatalysis even without doping with transition metals. The general process for vertically
aligned ZnO nanowires grown on a substrate by the hydrothermal method is the following.
a) A thin layer of ZnO nanoparticles is seeded on a certain substrate. The seeding layerpromotes nucleation for the growth of nanowires due to the lowering of the
thermodynamic barrier.
b) An alkaline reagent (such as NaOH or hexamethylenetetramine) and Zn2+salt
(Zn(NO3)2,ZnCl2,etc.) mixture aqueous solution is used as a precursor(or growth
solution).
Figure 10. Structural model of ZnO. a) Schematic of ZnO crystal
structure along polar axis. b) Schematic of crystal faces of wurtzite
ZnO.
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c) The ZnO seeded substrate is kept in the growth solution at a certain temperature and a
certain period of time.
d) The resultant substrate and growth layer is washed and dried.
When hexamethylenetetramine [(CH2)6N4,or HTMA] and Zn(NO3)2 are chosen as precursor, the
chemical reactions can be summarized in the following equations
Decomposition reaction:
(CH2)6N4 + 6H2O 6HCHO + 4NH3
Hydroxyl supply reaction:
NH3 + H2O NH4++ OH
Supersaturation reaction:
2OH+ Zn
2+ Zn(OH)2
ZnO nanowire growth reaction:
Zn(OH)2 ZnO + H2O
One of the key parameters for the growth of ZnO nanowires is controlling the supersaturation
of the reactants. It is believed that high supersaturation levels favor nucleation and low
supersaturation levels favor crystal growth. If a lot of OHis produced in a short period, the Zn2+
ions in the solution will precipitate out quickly due to the high pH environment, and, therefore,
Zn2+ would contribute little to the ZnO nanowire growth and eventually result in the fast
consumption of the nutrient and prohibit further growth of the ZnO nanowires. Thus, the
concentration of OH should be controlled in the solution to maintain low super-saturation
levels during the whole nanowire growth process.
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Now we analyse the effects of different parameters during the synthesis process.
Effect of the ZnO Seeding Layer:
Typical pre-seeding methods include thermal decomposition of zinc acetate, spin coating of
ZnO nanoparticles, sputter deposition, and physical vapor deposition. In order to seed ZnO
particles on the substrate, ZnO seeds must be annealed at certain temperature to improve ZnO
particle adhesion to the substrate and nanowire vertical growth alignment. The minimum
temperature required to form textured seeds from zinc acetate on a silicon substrate from 100
to 350C. The results suggest that temperatures between 150 and 200C are needed for seed
alignment, whereas higher temperatures promote seed crystallinity and growth.
A very uniform thin layer of ZnO nanoparticles can be observed when ZnO seeds are annealed
at a temperature of 350C. However, when the annealing temperature was further increased to
450C,ZnO crystallized into nanoparticles as well as nanorod-like structures. ZnO seeds
annealing at a temperature of about 350C can give the best results for the ZnO nanowire
growth.
The texture, thickness, and crystal size of ZnO seed layers also affect the quality of ZnO
nanowire growth. The results show that as the diameter increases, the density decreases , and
the length of the nanorods slightly decreases when the thickness of the seed layer increases
(see Table).
The SEM images show that the density of nanowires decreased from 35 to 12 m2 when the
thickness increased from 106 to 191 nm and the diameter of the nanowires was found toincrease with the seed layer (002) grain size. It has been found that the average diameter of
nanowires is increased from 50 to 130 nm and the density is decreased from 110 to 60 m2
when the seed layer thickness is changed from 20 to 1000 nm.
It has been reported that the nanorods grown on seeds crystallized from a zinc acetate solution
have a higher aspect ratio (of the order of 3) than those grown using nanoparticle-seeded
substrates.
Without a ZnO seeding layer, ZnO nanowires could be grown on an Au/substrate by introducing
a suitable content of ammonium hydroxide into the precursor solution. Au is used as anintermediate layer to assist the growth of ZnO nanowires.
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Table: The diameter, density, and length of ZnO nanorods corresponding to the thickness of the
seed layer.
Effect of an Alkaline Reagent:
There are some alkaline reagents that have been used to supply OH
during the reaction
process such as NaOH, hexamethylenetetramine (HMTA), Na2CO3, ammonia, and
ethylenediamine. When NaOH, KOH, or Na2CO3 is chosen, the synthesis process usually is
carried out at elevated temperatures ( >100C) and pressures in a Teflon-sealed stainless
autoclave.
When HMTA, ammonia, or ethylenediamine is chosen, the synthesis process can be carried out
at lower temperatures (
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The nanowire density with varying the precursor concentration with equal molar
concentrations of the zinc salt and HMTA have been studied. The experimental results showed
that the density of the nanowires is closely related with the precursor concentration. From 0.1
to 5 mM, the ZnO nanowire density was increased from 55/100 m2 to 108/100 m2. When the
precursor concentration is further increased, the density of ZnO nanowires remainsapproximately steady with a slight decreasing tendency. The zinc chemical potential inside the
body of the solution increases with zinc concentration. To balance the increased zinc chemical
potential in the solution, more nucleation sites on the substrate surface will be generated, and,
therefore, the density of the ZnO nanowires will increase. However, a continuous increase in
the solution concentration may not increase the density of the nanowires when its density is
larger than the saturation density.
It has been reported that the density and diameter of ZnO nanorods are especially sensitive to
the concentration of the reactants. Furthermore, the structural transition is shown by
increasing the concentration. At the lowest concentration of Zn2+, theZnO nanorods grow as
single crystals with a low density and variable orientations. On the other hand, at the highest
concentration, the nanorods grow as polycrystals due to the supersaturated Zn2+ source.
Effect of Growth Duration Time:
ZnO nanowires were synthesized by using equimolar (50 mM) zinc nitrate and HMTA at 93 C.
The average diameter of ZnO nanowires is increased with growth duration time when the
growth time is less than 2.5 h (See Table). However, the average diameter is almost unchanged
after that. It means that the growth rate is slowed down after this period due to depletion ofthe precursor. ZnO nanowire experiments on zinc-acetate-seeded substrates for different
growth durations from 5 to 15 h were carried out. The SEM images showed that both length
and diameter of the nanowires were increased with increasing growth duration time but the
aspect ratio was reduced. Although nanowire growth slowed down after a certain period, the
precursor supply for the ZnO nanowire growth can be replenished by repeatedly introducing
fresh solution into the baths to keep up the growth rate. However, the diameter of the
nanowires will also continue to increase and eventually connect together to form a ZnO film.
Effect of Initial Solution pH:
ZnO nanorods were grown on preseeded glass substrates using the same concentration of zinc
nitrate and HTMA as the precursors. The pH of the reaction bath was found to change gradually
from 6.4 to 7.3 in 5 h during the growth process.
When the growth process was initiated in basic condition (pH 812), flower petal like ZnO
nanostructures were obtained. The effect of pH change from 7.5 to 11.44 on the growth of
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ZnOnanorods by using zinc nitrate and NaOH as precursors was studied. The diameters of the
nanowires are increased with increased pH until they formed a ZnO film when the pH reached a
value of 11.44. For a precursor pH value of 11.33, fast growth of ZnO nanorods was observed
on the seed layer. The fast growth of ZnO nanorods resulted in a reduction of the optical band
gap energy due to the creation of greater number of defects in the nanorods during this fastgrowth.
Effect of Growth Substrate:
One major advantage of the hydrothermal synthesis method is that almost any substrate can
be used for the growth of vertical ZnO nanowires by using ZnO seeding layer. In this way, ZnO
nanowires can grow on flat surface regardless of the substrate (polymer, glass, semiconductor,
metal, and more) by only control-ling the growth conditions. ZnO nanowires can also be grown
on organic substrates.
ZnO nanowires have been successfully grown on polydimethylsiloxane (PDMS), polystyrene
(PS), polyethylene terephthalate (PET), polyethylene fibers, microfibers, polyurethane,
polyimide, paper, and other organic substrates like lotus leaf.
Effect of Growth Temperature:
Growth of ZnO nanowires at different temperatures by using equimolar zinc nitrate and HMTA
from 60 to 95C was carried out. Hydrothermal growth carried out with 1 mM solution of the
precursors at 95C produced similar nanowire lengths as those grown at 65C in the same
growth period. Thus, there is no significant difference in the nanowire growth process for
different chemical bath temperatures.
Effect of Additives:
The aspect ratio of ZnO nanowires could be affected by the addition of additives. The effect of
the addition of polyethyleneimine (PEI) on ZnO nanorods was studied and showed that the
average diameter of the nanorods was reduced drastically from 300 nm to 40 nm as the PEI
amount increased from 0 to 12% (v/v) in solution. The PEI molecules were adsorbed on the
lateral facets of the ZnO nanorods due to the electrostatic affinity. Thus, the lateral growth of
the nanorods could be largely limited.
The influence of PEI and NH3 on the growth of ZnO nanowires was accounted. The SEM image
showed that the diameter and length of ZnO nanowires decreased with the addition of PEI.
With the addition of NH3, the diameter of the ZnO nanowires was reduced even further.
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Other Factors:
Other factors affecting ZnO growth include the heating source, the Zn2+ source, the external
electric field, and mechanical stirring.
The use of microwave heating instead of conventional heating has recently received great
interest. The hydrolyzed method creates defective crystallites under microwave irradiation and
leads to a faster growth process as compared to the conventional process.
Zinc salts include acetates, nitrates, perchlorates, and chlorides. The counter ion of zinc often
affects the crystallite morphology by acting as promoter or inhibitor in the nucleation and
growth processes.
An external electric field could also affect the growth rate and depends on the electric field
direction and the applied voltage.
Mechanical stirring could increase the growth rate.
Other Solution Phase Synthesis Methods:
Other solution phase synthesis methods include the microemulsion and ethanol base methods.
microemulsion synthesis- The surfactant, such as ethyl benzene acid sodium salt (EBS), dodecyl
benzene sulfonic acid sodium salt (DBS), and zinc acetate dispersed in xylene by stirring until a
homogenous mixture, was obtained. Then the hydrazine and ethanol mixture solution was
added drop by drop to the well-stirred mixture at room temperature. The resulting precursor-
containing mixture was subsequently heated to 140C and refluxed for 5 h. The resultant ZnO
nanorods had an average diameter of 80 nm.In the microemulsion synthesis, the process is
referred to as hydrothermal when it is carried out in an aqueous solution.
Ethanol base synthesis- ZnO nanorods are synthesized by using a solvothermal base in an
ethanol solution. The synthesis process consisted of a NaOH ethanol solution added drop by
drop in a Zn(NO3)2 ethanol solution and the mixture transferred into a Teflon-lined stainless
autoclave and heated at 160 C for 12 h.
Doping of ZnO Nanowires
Doping is the primary method of controlling semiconductor properties such as the band gap,
electrical conductivity, and ferromagnetism. Many metals and nonmetals have been
successfully used to dope ZnO nanowires by various synthesis methods. ZnO nanowire metal
doping includes Ni, Co,Ga, Eu, Al, and Cu, and nonmetal doping includes C, N, P, and Cl.
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Two different element co-doped nanowires such as Mn + Co, Mn + Li, and Li + N, have also been
studied.
Doping of ZnO nanowires with Mn, Cr, and Co by a hydrothermal method from aqueous
solutions of zinc nitrate hydrate, TM (TM = Mn, Cr, Co) nitrate hydrate, and HTMA. The
experiments were carried out in vials and heated in an oven at 90C for 3 h.
Studies on nitrogen-doped ZnO nanowires by using the MOCVD method. The precursors
chosen were dimethylzinc-triethylamine (DMZn-TEN) for zinc, nitrous oxide (N2O) for oxygen,
and diallylamine for the nitrogen source. The MOCVD reactor operated at atmospheric pressure
and 850 C.
Li and N co-doped ZnO nanowires were synthesized on a Si substrate by using the hydrothermal
method. The process was carried out in three steps: First, a thin ZnO seed layer (10 nm) was
predeposited on Si by a sputtering technique. Second, Li-doped nanowires were synthesized by
using Zn(NO3)2, HTMA, and LiCl for precursor growth at 80 C for 8 h in an oven. Finally, the
nanowires were treated by rapid thermal annealing at 500 C in NH3 environment for 30 min.
It has been reported that Indium doping of ZnO nanowires cannot be carried out by
hydrothermal synthesis due to formation of the In(OH)3phase. Nevertheless, it could be realized
bya postdeposition thermal annealing in an inert atmosphere or by a vapor phase transport
process.
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Characterization/Properties of ZnO nanowires synthesized by
Hydrothermal method
Under general conditions, ZnO is single crystalline and exhibits a hexagonal wurtzite structure.
A dominant diffraction peak for (002) indicates a high degree of orientation with the c-axis
vertical to the substrate surface.
Figure 11: XRD of ZnO nanowires on a silicon substrate
growth by the hydrothermal synthesis method.
Figure 12: SEM image of the ZnO nanorods array on
glass substrate.
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ZnO nanowires have a homogeneous diameter size that does not vary significantly along the
wire length. The measured plane spacing is characteristic of the (002) planes, showing the ZnO
nanowire with a perfect lattice structure and verifying that the nanowires grow along the c-axis
direction.
Figure 13: (a) TEM of ZnO nanowires on an ITO substrate showing a general view. (b)
HRTEM image showing individual nanowires with [0 0 2] growth direction. Inset shows
selected electron diffraction (SAED) patterns.
Figure 14: Raman spectra of the ZnO
structures obtained by the hydrothermal
method at 130C for (a) 30min, (b)
60min, (c) 120min, and (d) 180min.
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ZnO nanowires showed a larger enhancement absorption in the visible range as compared to
ZnO nanoparticles. The ZnO/Fe nanowires exhibit even stronger absorption than the ZnO
nanowires and nanoparticles in both the UV and the visible range implying that ZnO/Fe
nanowires could more fully utilize most of the UV and visible light than the other two.
Figure 15: UV-Visible absorption spectra of ZnO
nanoparticle, ZnO and ZnO/Fe nanowires.
Figure 16: FTIR spectrum of ZnO nanorods prepared
at 200 C for 20 h using NaOH.
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When the UV light is switched on, electron-hole pairs are generated and produce a
photocurrent. The UV irradiation changes the current abruptly with some variation, and the
photo-potential is sharply reduced when the light is switched off.
Figure 17: Zn(2p) XPS spectrum of synthesized ZnO
nanorods on a ZnO thin film.
Figure 18: Photocurrent response to UV light at
different DC biases
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In addition to the above characterizations, ZnO nanowires also exhibit many other unique
chemical and physical properties for many applications such as large surface areas,
piezoelectric, piezotronic, and optical.
We have analyzed two different methods of synthesis of ZnO nanowires. By knowing the
synthesis process in detail, nanowires with precise orientation and characteristics can be grown
which will be best suited for the need at hand.
From this knowledge we progress to the ultimate aim of our report: the applications of the ZnO
nanowires.
APPLICATIONS
ZnO nanowires can be used for a number of applications in different fields due to the unique
electrical, optical, and mechanical properties.
1.Sensora) Gas Sensor: ZnO is one of the earliest discovered and most widely used oxide gas
sensing materials. ZnO functions as a gas sensitive material due to its electrical
conductivity that can be dramatically affected by the adsorption or desorption of gas
molecules on its surface. 1D nanostructured devices such as nanowires are more
sensitive and selective due to their high aspect ratio giving rise to large surface area.
There are many gases that can be detected by ZnO nanowires, such as NO, NO2 ,CO,
NH3, H2, O2, and ethanol. A resistor type NO 2 gas sensor based on the ZnO nanorod was
reported using a sonochemical route. The vertically aligned ZnO nanorods were grown
on a Pt-electrode patterned alumina substrate under ambient conditions. The ZnO
nanorod gas sensor was highly sensitive to the NO2 gas with a very low detection limit of
10 ppb at 250C and short response and recovery time (Figure 19).There has been a
room temperature NH3 gas sensor based on a ZnO nanorod array produced by
hydrothermal decomposition on an Au electrode. Recently, CO sensors based on aligned
ZnO nanorods on a substrate exhibited high sensitivity to CO gas with the low detection
limit of 1 ppm at 350C.
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b) Biosensor: Recently, ZnO nanostructures have attracted interest in biosensor
applications due to many advantages, including non-toxicity, biosafety, bio-
compatibility, high electron-transfer rates, and combination with immobilized enzymes.
The high isoelectric point (IEP) of ZnO (IEP 9.5) makes it a good matrix for immobilizing
low IEP acidic proteins or DNA by electrostatic interactions with high binding stability. In
addition, ZnO has high ionic bonding (60%), and it dissolves very slowly at normal
biological pH environments. An ampere-metric glucose biosensor based on aligned ZnO
nanorod films formed directly on the surface of ITO glass has been constructed. Thebiosensor exhibited a linear response to glucose from 5 M to 300M and a limit of
detection of 3 M (Figure 20(a)). The biosensor also showed good selectivity for glucose.
In an air-saturated and stirred 0.01 M PBS containing 5 M glucose, there was no
significant change of the ampere-metric response by the injection of 10 M UA and AA,
respectively (Figure 20(b)). Fabrication of a ZnO-nanorod-based biosensor with good
reproducibility and selectivity for the quick monitoring of penicillin with the
immobilization of the penicillinase enzyme by the simple physical adsorption method
has been done. The authors showed that the potentiometric response of the sensor
configuration revealed good linearity over a large concentration range from 100 M to
100 mM. A ZnOnanowire field-effect-transistor (FET) based biosensor can detect low
level biomolecular interactions. The ZnO nanowire biosensor could detect as low as 2.5
nM of the streptavidin with a current increase of 7.5 nA.
Figure 19: Response curve of a ZnO gas sensor
exposed to 10 ppb NO2
gas at 250
C
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2.UV DetectorUV detection is another promising optical application of ZnO nanowires. The UV
detector utilizes the electric potential of the ZnO nanowires changed under UV
irradiation. A UV photodetector by contacting a circular spiral structure ZnO nanowire
with 30 nm IrO2 electrodes has been constructed. The I-V measurement showed that the
Figure 20: (a) Typical steady-state response of the biosensor by the successive addition of specific
concentrations of glucose to air-saturated and stirred 0.01 M pH 7.4 PBS solution at 100mV. (b) Effect
of interfering species on the biosensor response.
Figure 21: I-V characteristics of a ZnO
photodetector in the dark and under Xe illumination
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curve corresponded to the Schottky metal-semiconductor contacts with the photo-
generated current reaching 5.11107 A, under a bias voltage of 5 V, and the
photocurrent being 2 orders of magnitude larger than the dark current (Figure 21).
For fabricating a ZnO bridging nanowire structure exhibiting nanowatt UV detection,
electrodes are formed by the thick ZnO layers covering the Au-catalyst-patterned areason the substrate, and the sensing elements consists of the ultralong ZnO nanowires
bridging the electrodes. The device exhibited drastic changes (10105 times) in current
under a wide range of UV irradiance (108
102 Wcm
2 ). Moreover, the detector
showed fast response (rise and decay times of the order of 1 s) to UV illumination in air.
A simple self-assembled lateral growth ZnO nanowire photodetector with the
photocurrent of the ZnO nanowires under UV illumination being twice as large as the
dark current with a bias voltage of 5V. Loading of Ag particles in ZnO nanowires
produces an enhanced photoresponse. The ZnO nanorods were combined with
graphene enabling the UV sensor to reach 22.7 A/W.
3.UV LaserRoom temperature of ZnO-nanowire-based UV lasing has been recently demonstrated.
Figure 22 shows a typical room temperature photoluminescence (PL) spectrum of ZnO
nanorods with an excitation wavelength of 325 nm at room temperature. The spectrum
exhibits two bands including a strong ultraviolet emission at 378 nm (or 3.28 eV) and a
weak spectral band in the visible region. The UV emission was contributed to the near
band edge emission of the wide band gap of ZnO. Visible emission is due to the
presence of various point defects such as oxygen vacancies. The hydrothermal methodgives rise to Oxygen vacancies.
Figure 22: Room temperature PL spectra
of ZnO nanorods (exc =325 nm)
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4.Light-Emitting DiodeThe output power of GaN LEDs with ZnO nanotip arrays can be enhanced by up to 50%.
A heterojunction LED could be fabricated by the growth of vertically aligned ZnO
nanowires on a p-GaN substrate and employed indium tin oxide (ITO)/glass to combine
and package. Figure 23 shows the electroluminescence (EL). A UV-blueelectroluminescence (EL) emission was observed from the nanowire-film heterojunction
diodes. Most of the currently developed ZnO LEDs are based on heterojunctions.
However, a ZnO rod p-n homojunction LED with an ion-implanted P-doped p-type ZnO
could also be fabricated.
5.Dye-Sensitized Solar Cells.Dye-sensitized solar cells (DSSCs), which are based on oxide semiconductors and
organic dyes or metal organic complex dyes, are one of the most promising candidate
systems to achieve efficient solar-energy because they are flexible, inexpensive, and
easier to manufacture than silicon solar cells. ZnO-based DSSC technology alternative to
TiO2 is considered as one of the most promising materials for solar cells due to a faster
Figure 23: EL spectra of ZnO nanowires/p-GaN/ZnO nanowires
heterostructure at a DC current of 20mA. The inset is a photograph
of the emission of blue light by the heterojunction LED under DC
bias
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electron transport with reduced recombination loss and its ease of crystallization and
anisotropic growth.
On comparing different fabricated ZnO nanowire DSSCs that included lengthwise growth
(LG) and branched growth (BG) showed that the overall light-conversion efficiency of
the branched ZnO nanowire DSSCs was much higher than the upstanding ZnO nanowires(Figure 24 and Table below).
The reason for the improvement is the enhanced surface area for higher dye loading
and light harvesting and the reduction of charge recombination by providing direct
conduction pathways along the crystalline ZnO nanotree multigeneration branches.
Well-aligned arrays of vertically oriented ZnO nanowires electrodeposited on ITO-coated
glass for dye-sensitized solar cells show maximum overall photovoltaic conversion
efficiency was 0.66% at 100 mW/cm2.
Fabricated branched ZnO nanowires on conductive glass substrates via a solvothermal
method for dye-sensitized solar cells have the short-circuit current density and the
energy conversion efficiency of 4.27 mA/cm2 and 1.51%, which are higher than those of
the bare ZnO nanowire.
Jacks-like ZnO nanorod architecture as a photoanode in dye-sensitized solar cells
exhibited a higher conversion efficiency of = 1.82% (Voc = 0.59 V, Jsc = 5.52 mA cm2)
than that of the branch-free ZnO nanorods electrodes ( = 1.08%, Voc = 0.49 V, Jsc = 4.02
mA cm2).
Figure 24: (a) Schematic structure of a solar cell and (b)J-V curve of dye-sensitized solar
cells with different fabricated ZnO nanowires.
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6.Smart Woven Fabrics in Renewable Energy GenerationFabric has been a part of human life for protection from natures elements and hazards.
However, with a growing population and ever improving advanced technologies, todays
fabrics are mostly used for fashion and performance thus enhancing the standard of
peoples everyday life and enjoyment. It is now possible to produce smart woven fabrics
by combining the oldest fabric making method with smart fiber material technologies.
A smart material is one that shows extraordinary response when subjected to a
stimulus. Piezoelectric materials are considered as smart materials because of their
ability to generate electricity against the stimulus which is mechanical strain or
vibration.
Each fabric making method has its own special attributes which help us to find most
applicable fabric structure and method for a specific application. By weaving polymer
based
piezoelectric fibres into woven fabrics, smart piezoelectric fabrics can be produced and
used
for many responsive applications.
Weaving is one of the best fabric making techniques that can be used for smart fabric
production. Warp threads can be located at the heddles with different orders and wefts
are
travelled through warps by shuttle(s). The position of heddles designates where wefts
will
be going over or under the warps.
Table: Characteristics and parameters of the Nanoforest DSSC Solar Cells shown in Figure 24.
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While a fabric is being designed, expectations from the final fabric are taken into
consideration. For smart piezoelectric fabrics, depending on expected energy generation
from the final product, weaving designs can bevariable. In this case, intersection of
piezoelectric (the charge generator) and conductive (the charge carrier) fibres is crucial.
Onepiezoelectric fibre can interlace more than one conductive fibre. One conductive fibre
can
also interlace more than one piezoelectric fibre. However, one conductive fibre can only
interlace the same pole of the each piezoelectric fibre.
A number of weaving designs are studied below for smart woven fabrics. Conductive
fibres
and conventional (non-conductive) fibres are needed alongside piezoelectric fibres.
Because
piezoelectric fibres carry negative charges on one side along its length and positive
charge
on the other side, a conductive material isneeded to carry the charge produced by
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Smart Woven Fabrics in Renewable Energy Generation 31
movements of the piezoelectric fibres. Conductive wires would add extra rigidity to the
fabric which is an undesirable outcome for most textile structures.
The best alternative to undesirable wires may be conductive fibres are produced and
patented (Perera & Mauretti, 2009). It is claimed (Mauretti & Perera, 2010) that
conductive
filaments are flexible, non-toxic and conformable for wearable applications. Electrical
conductivity of metallised synthetic (acrylic) conductive textile yarns is widely studied
(Vassiliadis et al., 2004, 2009, 2010). Mechanicaland electrical properties of metallised
conductive yarn are controlled by blending conventional and conductive fibres in the
yarn
and changing the ratio of fibres in the blend. The way piezoelectric, conductive and
conventional fibres are integrated into fabricstructure by weaving technique, gives a
good
indication of the performance of resultant fabric. When more piezoelectric fibres are
used in
the fabric, this results in higher energy generation by movement and mechanical strain.
However, to be able to carry as much charge as it is possible, the right number of
conductive
fibres need to interlace with piezoelectric fibres.
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The possible woven fabric designs for energy generation for wearable textiles are shown
in
this chapter. Blue lines represent piezoelectric fibres while red lines represent
conductive
and grey lines show non-conductive conventional fibres. This is the simplest weavingpattern produced by plain weaving technique. However, by integrating piezoelectric and
conductive fibres into this basic structure, the resultant woven fabric becomes a smart
fabric
which can harvest energy from the natural sources.
Polymer based piezoelectric fibres can be used as either weft or warp into the woven
structure and conductive fibres can be used as negative and positive electrodes for
charge
transfer so that the resultant fabric can produce energy for micro powered electronics.
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Advances in Modern Woven Fabrics Technology 32
The main advantage of the use of polymer based piezoelectric material in this
application is
its flexibility and the fact that it can easily be incorporated in the woven structures
without
causing any problem. It is impossible to integrate existing ceramic based piezoelectric
fibres
into similar structures because these fibresare rigid and brittle thus can cause major
problems in the weaving process. For the first design shown in Figure 6(a), 2 heddles are
needed to locate conductive and non-conductive fibres/yarns and 2 shuttles, the one
with
piezoelectric fibres/yarn and the other with non-conductive conventional fibres/yarn. In
the
warp direction, 2 conventional fibres are located between conductive fibres. Conductive
fibres
act as negative and positive electrodes.
If a number is given to each warp from left to right, odd numbered warps are located on
the
first heddle and even numbered warps are located on the second heddle. During the
shuttles travel along the looms width, according to design, while the first conductive
fibre
only interlaces with negative pole of piezoelectric wefts, second conductive warp
interlaces
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only positive pole of the piezoelectric filling fibres/yarns. Thus, any short circuit is
avoided.
Figure 6(b) shows interlace of warp and weft threads and possible appearance on face
of the
fabric. If the used fibres counts are the sameand the warps and wefts are located withan
exact sequence, the resultant fabric will contain 24% piezoelectric, 16% conductive and
60%
non-conductive conventional fibres/yarns.
The design shown in Figure 7(a) needs 2 heddles to locate conductive and non-
conductive
fibres/yarns and 2 shuttles, the one with piezoelectric fibres/yarn and the other with
non-conductive conventional fibres/yarn. If a number is givento each warp from left to
right,
odd numbered warps are located on the first heddle and even numbered warps are
located
on the second heddle.
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Smart Woven Fabrics in Renewable Energy Generation 33
During the shuttles travel along the looms width according to the design, the first
heddle is
kept in place, second heddle is uplifted so that warps are kept apart and shuttle travels
through easily. Shuttle carrying piezoelectric fibre travels twice and then the other
shuttle
which carries non-conductive conventional fibres/yarn travels once. The whole process
is
repeated until the desired fabric structure is created. Thus, the first conductive warp
only
interlaces with negative charged sides of piezoelectric wefts, second conductive warp
interlaces only with the positive charged sides of the piezoelectric filling fibres/yarns.
Figure 7(b) shows interlace of warp and weft threads and possible appearance on face
of the
fabric. If the used fibres counts are the sameand the warps and wefts are located with
an
exact sequence, the resulted fabric will contain 34% piezoelectric, 18% conductive and
48%
non-conductive conventional fibres/yarns.
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The design shown in figure 8(a) needs 2 heddles to locate conductive and non-
conductive
fibres/yarns and 2 shuttles, the one with piezoelectric fibres/yarn and the other with
non-conductive conventional fibres/yarn. If we give a number to each warp from left to
right, 1st
,
2
nd
, 7
th
, 8
th
, 13
th
, 14
th
, 19
th
, 20
th
and 25
th
warps are located on the first heddle and other warps
are located on the second heddle.
According to design in figure 8(a), while first heddle is kept in place, second heddle is
uplifted so that warps can be kept apart fromthe first heddles warps and shuttl e, which
carries piezoelectric fibres/yarn, can easilytravel through. The shuttle which carries
piezoelectric fibre travels twice and then the first heddle is uplifted while the second
heddle
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Advances in Modern Woven Fabrics Technology 34
is lowered so that the other shuttle which carries non-conductive conventional
fibres/yarn
travels once through the warps. The same movements are carried out with the same
order
again and again until a fabric structure is created. Thus, all the conductive warps on the
first
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heddle only interlace with negative pole of piezoelectric wefts and all the conductive
warps
on the second heddle interlace only with positive pole of the piezoelectric wefts.
Figure 8(b) shows interlace of warp and weft threads and possible appearance on face
of thefabric. If the used fibres counts are the sameand the warps and wefts are located with
an
exact sequence, the resultant fabric will contain 34% piezoelectric, 34% conductive and
32%
non-conductive conventional fibres/yarns.
The design shown in Figure 9(a) needs 2 heddles to locate conductive and non-
conductive
fibres/yarns and 2 shuttles, the one with piezoelectric fibres/yarn and the other with
non-conductive conventional fibres/yarn. If we give a number toeach warp, 1
st
, 2
nd
, 5
th
, 6
th
, 9
th
,
10
th
, 13
th
, 14
th
, 17
th
, 18
th
, 21
st
, 22
nd
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and 25
th
warps are located on the first heddle and others
are located on the second heddle.
During the first shuttles travel along the loom width, the first heddle is kept in placeand
the second heddle is uplifted so that warps can be kept apart from the first heddles
warps
and shuttle which carries piezoelectric fibres/yarn can easily travel through. The shuttle
carrying piezoelectric fibre travels twice and then the first heddle is uplifted while the
second heddle is lowered so that the other shuttle which carries non-conductive
conventional fibres/yarn travels twice through the warps. The same movements are
carried
out in the same order again and again until a fabric structure is created. Thus, all the
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Smart Woven Fabrics in Renewable Energy Generation 35
conductive warps on the first heddle only interlace with negative pole of piezoelectric
wefts
and all the conductive warps on the second heddle interlace only with positive pole of
the
piezoelectric wefts.
Figure 9(b) shows interlace of warp and weft threads and possible appearance on face
of the
fabric. If the used fibres counts are the sameand the warps and wefts are located with
an
exact sequence, the resultant fabric will contain 26% piezoelectric, 18% conductive and
56%
non-conductive conventional fibres/yarns.