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Nanoscale Res Lett. 2009; 4(12): 1434–1438.
Published online Aug 25, 2009. doi:  10.1007/s11671-009-9416-5
PMCID: PMC2893704

SnO2Nanowire Arrays and Electrical Properties Synthesized by Fast Heating a Mixture of SnO2and CNTs Waste Soot

Abstract

SnO2nanowire arrays were synthesized by fast heating a mixture of SnO2and the carbon nanotubes waste soot by high-frequency induction heating. The resultant SnO2nanowires possess diameters from 50 to 100 nm and lengths up to tens of mircrometers. The field-effect transistors based on single SnO2nanowire exhibit that as-synthesized nanowires have better transistor performance in terms of transconductance and on/off ratio. This work demonstrates a simple technique to the growth of nanomaterials for application in future nanoelectronic devices.

Keywords: SnO2nanowires, Semiconducting, Field-effect transistor

Introduction

One-dimensional semiconductor nanowires and nanotubes have stimulated increasing attention in the last few years and are expected to lead to novel device application due to their intriguing properties and potential applications in constructing nanoscaled electronic and optoelectronic devices [1-12]. Among semiconducting oxide nanostructure, SnO2 nanowires, nanobelts, and nanowires are very important n-type semiconductors for applications as transparent conducting electrodes [12], gas sensors [13], and lithium-ion batteries [14], which utilize the unique characteristics of SnO2 nanostructures including a wide band gap (Eg = 3.6 eV at 300 K) and large surface-to-volume ratios. A precondition for SnO2 nanostructures based on the applications is an easy and lager-scale synthesis of SnO2 nanostructures. Several methods have been reported for the synthesis of SnO2 nanowires/nanobelts, including thermal decomposition [15], electrospinning [16,17], solution-based crystal growth [18,19], laser ablation, and template-based approaches [20]. However, those methods always required long time for heating and cooling, which hinder the mass production of SnO2 nanostructures. Due to its versatility and simplicity, the synthesis method of SnO2 nanowires is still investigated [21].

The electrical properties of SnO2 nanowires and nanobelts are also reported [22,23]. Field-effect transistors (FETs) based on single carbon nanotube, Si nanowire, ZnO nanowire and others are with excellent properties superior to their bulk counterparts [24,25]. SnO2 nanowires are one of the potential semiconducting materials for nanoelectronic devices due to their excellent electronic properties. In the present study, we report a novel method to synthesize aligned SnO2 nanowires by using high-frequency inductive heating furnace. A mixture of SnO2 and the carbon nanotubes (CNTs) waste soot which was a main by-product in the production of CNTs by arc-discharge. The electrical properties including application in FETs of SnO2 nanowires were also studied.

Experimental

The fabrication of nanowires was carried out in a high-frequency introduction furnace. The schematic diagram of the apparatus is shown in Fig. Fig.1.1. The SnO2nanowires were synthesized on a silicon substrate by heating pure SnO2powders (50 wt.%) and CNTs waste soot (50 wt.%) which was a main by-product in the production of CNTs at 1,027 k in the quartz tube. An appropriate amount of source powders (about 1 g) and the silicon substrate separated by 10 cm were put in the center of the quartz tube. The silicon (100) substrate patterned with Au using conventional photolithographic method was located downstream of the source powders. The precursor was loaded in a graphite boat and located in a high-purity graphite tube. As a heating crucible, the graphite tube was placed in a horizontal quartz tube and heated in a high-frequency induction furnace. The quartz tube was first evacuated at 10−2Torr by a vacuum pump. After heated up to the desired temperature (1,027 K), an Ar gas flow at a rate of 20 SCCM was introduced, and the growth was initiated and maintained for less than 3 min. When the system was cooled to room temperature, many white products were formed on the surface of the substrate.

Figure 1
Schematic diagram of the apparatus for synthesis of SnO2nanowires

The as-grown SnO2nanowires were characterized by scanning electron microscopy (SEM, FEI SIRION 200) equipped with energy-dispersive X-ray spectroscopy (EDX, INCA OXFORD) and transmission electron microscopy (TEM, JEM-2010). The electronic measurements were made using an Agilent 4156C semiconductor characterization system under an ambient condition at room temperature.

Results and Discussions

Figure Figure2is2is the morphology of as-synthesized nanowires. Figure Figure2a2a and b show two typical SEM images of the as-grown SnO2ordered nanowire arrays deposited on the silicon substrate. It can be observed that large quantities of nanowires were grown vertically on the silicon substrate and formed the SnO2nanowire arrays with the length of tens of mircrometers, and the surfaces of the nanowires are uniform and smooth. Structural properties of the nanowires were further studied with TEM. Figure Figure2c2c shows a low-magnification TEM image of single SnO2nanowire with diameters ranging from ~20 nm. It can be seen that the SnO2nanowire is very smooth, straight, and uniform, and the geometrical shape is structurally perfect. The crystallography of the nanowires was investigated by select area electron diffraction (SAED) pattern. High-resolution TEM (HRTEM) (Fig. (Fig.2d)2d) shows that the as-synthesized SnO2nanowire is single crystalline. The interplanar spacing is about 0.334 nm, which is corresponding to the (110) plane of rutile crystalline SnO2.

Figure 2
a,bThe typical SEM images of as-synthesized aligned SnO2nanowires,clow-magnification TEM, anddHRTEM image of single SnO2nanowire

Figure Figure33 shows X-ray diffraction (XRD) patterns of SnO2 nanowires. All the diffraction peaks can be indexed to the tetragonal rutile structure of SnO2. The SnO2 lattice constants obtained by refinement of XRD data are a = 4.737 Å, c = 3.185 Å, which are consistent with bulk rutile SnO2 tetragonal structure [26]. It indicates that SnO2 nanowires are in excellent accordance with a rutile structure. To study the composition of single as-prepared nanowire, EDS measurements (Fig. (Fig.4)4) have been performed on individual nanowire. All the resultant nanowires are mainly composed of Sn, O, and C (come from CNTs).

Figure 3
X-ray diffraction patterns of as-synthesized SnO2nanowires
Figure 4
EDS patterns of as-synthesized SnO2nanowires

Figure Figure55 shows the FT-IR spectrum in the range of 1,000–4,000 cm−1 of as-synthesized SnO2 nanowires. It shows dominant peaks at 1,635, 2,377, 2,925, 3,467, and 3,865 cm−1 which corresponds to Si–O, Sn–O, C–O, CNT, H–O–H, and C–Hx, respectively [27,28]. The peak near 1,635 cm−1 can be assigned to the vibration of O–Sn–O that corresponds to the A2u mode [29]. The peaks near 2,370 cm−1 agreed with stretching vibrations of Sn–O bonds [30].

Figure 5
FT-IR spectrum of as-synthesized SnO2nanowires

These peaks confirm that SnO2nanowires possess the crystalline structure of the tetragonal rutile structure, which is corresponding to the results of XRD.

The growth mechanism of these aligned SnO2 nanowires follows the conventional vapor–liquid–solid during the experiment. In terms of this mechanism [31], there exist three processes. First, SnO2 powders react with CNTs waste soot powder, which results in the formation of SnO gas under high temperature. Subsequently, SnO gas will decompose to Sn and O2 at a temperature higher than 1,027 K. Some Sn droplets reacted with the Au particles and formed Au–Sn alloyed droplets. These alloyed droplets can provide the energetically favored sites for formation of SnO2 nanowires. Finally, aligned SnO2 nanowires were produced by the reaction with Sn and O2 during the process of transporting the Sn to the substrate by carrier gas. Moreover, the temperature is reached in several short seconds during high-frequency induction heating process, which results in eliminating the dimensional growth of the Au species present on the surface, so it gives rise to the formation of SnO2 nanowires, while other nanostructure products can not be formed. The following chemical reaction equations are proposed to explain the growth mechanism:

equation image
(1)
equation image
(2)
equation image
(3)

After growth, the SnO2nanowires were transferred from silicon substrates, and a number of FETs device structures were fabricated. Devices were fabricated by thermally growing SiO2film with 500 nm thickness on the top of n-type Si wafers, followed by deposition of an Au layer with sputtering and standard photolithography. Parallel Au electrode pairs, with ~1 μm in length and 80 nm in thickness, were patterned. The parallel Au electrodes will be used as source and drain electrodes. An n-type silicon layer serves as the back gate. The as-prepared SnO2nanowires were sonicated into a suspension in ethanol, followed by solution casting the slightly dispersed SnO2nanowires between the drain and the source of Au electrodes to form a single SnO2nanowire FET (SnO2-FET). The SnO2-FET samples were quickly transferred to a stove to anneal in Ar at 973 K for 5 min in order to improve the quality of Au–SnO2contacts. The inset in Fig. Fig.3is3is the SEM image of the as-fabricated single SnO2nanowire with a channel width of ~200 nm.

The current–voltage of drain and source (IdsVds) data of the device are shown in Fig. Fig.6.6. The gate voltages were applied from 0 to 9 V and the drain voltages were from −1.0 to 1.0 V for room temperature samples. It is very clearly shown that we have demonstrated that the conductance increased with the increase of the back gate voltage, which indicates an n-type property for the SnO2 nanowire. The possible reason is due to oxygen vacancies and extra gallium interstitial atoms in the lattice during the synthesis process [32]. An on/off current ratio (Ion/Ioff) of more than 105 has been achieved at Vgs from −1 to 1 V with Vds of 0.2 V. The FETs based on single SnO2 nanowire exhibited better electrical properties, which affected both on/off current ratio and threshold voltage of the devices. Figure Figure6.6. shows a typical IDSVDS characteristic of single SnO2 nanowire FETs. The mobility can be calculated from the following formula [33-35]

equation image
(4)
equation image
(5)
equation image
(6)
Figure 6
Transistor characteristic of back-gated single SnO2nanowire FET devices on silicon substrates:IdsVdscurves for gate voltages withVgs = 9 V to 0 in −3 V steps fromtoptobottom. Theinsetis the SEM image of the as-fabricated single SnO2nanowire ...

where gm is the transconductance, C is the capacitance and L is the channel length, ε, h, and r are the dielectric constant, the thickness, and the radius of silicon dioxide, respectively. Using ε = 3.9, h = 500 nm, L = 1.5 μm, and r = 15 nm, it can be calculated μe = 169 cm/V s at VDS = 0.3 V.

This value is consistent with those obtained in planar single-crystalline SnO2nanowire and other metal oxide nanowires. The performance of SnO2-FET devices depends to a large extent on the source and drain contacts. In our cases, we find that it is effective to improve the quality of Au–SnO2contacts by annealing the SnO2-FET devices in Ar at 973 K for 5 min. Therefore, the value of effective mobility, transconductance, and on/off ratio has also been significantly improved.

Conclusions

We present a simple, fast, and a low-cost method to synthesize SnO2nanowire arrays by using fast heating furnace. A ball-milled mixture of SnO2and CNTs waste soot was used as source materials. SEM and TEM images show nanowire diameters of 50–100 nm and lengths up to tens of mircrometers. The electrical properties of the as-synthesized single SnO2nanowire in FETs devices show that the n-type SnO2nanowires have larger on/off ratio (>105) and higher carrier mobility at room temperature. This method provides a promising candidate for large-scale preparation of SnO2nanostructures.

Acknowledgments

We acknowledge that this work is supported by National Natural Science Foundation of China (No. 50730008), Shanghai Science and Technology Grant (No. 0752nm015), and National Basic Research Program of China (No. 2006CB300406).

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