Introduction

Due to their size dependant properties the synthesis of nanostructures (nanowires (NWs), nanorods (NRs), nanotubes (NTs) and nanobelts (NBs)) has become one of the most active research areas within the nanoscience community. Nanostructured materials, in particular semiconducting metal oxides (SMOx), have demonstrated exceptional optical and electrical properties due to electron and phonon confinement, with higher surface-to-volume ratios, modified surface work function, higher surface reaction activity, better catalytic efficiency and stronger adsorption ability compared to their bulk counterparts1.

Tin oxide (SnO2) is an intrinsic n-type wide-bandgap SMOx with applications in transparent conducting electrodes, solar cells and gas sensors2,3,4. In particular SnO2 is used in most current commercial resistive gas sensors and is the most studied material in the gas sensing literature, with demonstrated sensitivity to carbon monoxide, hydrogen, ethanol, and nitrogen dioxide, amongst others3,4,5,6.

Nanostructures of SnO2 have been synthetized using various methods, including chemical vapour deposition (CVD)7,8,9,10,11,12,13,14,15, thermal evaporation16,17,18,19, laser ablation20, template (AAO – anodic alumina oxide) assisted electrodepositon21,22, and liquid-phase methods23,24. Among these, vapour-phase synthesis (e.g. CVD) offers potential advantages, including the ability to operate in continuous mode and greater material purity. However CVD routes to nanostructured SnO2 typically require significant amounts of energy to reach the high temperatures required to break strong chemical bonds during the precursor-to-material conversion, which can lead to incompatibilities when integrating this process with microsystems and/or temperature sensitive substrates. To avoid these stringent conditions and allow nanostructure growth at temperatures as low as 650–800 °C15 or 550–750 °C8, catalyst seeds on the substrate are used to promote a vapour-liquid-solid (VLS) growth mechanism. However, the need for extra surface pre-treatment processing steps adds potential technological limitations in device fabrication. The formation of nanostructures via a vapour-solid (VS) mechanism, in contrast, avoids the use of catalyst seeds and facilitates device fabrication, but the synthesis of tin oxide nanostructures via a VS mechanism has so far required the use of very high temperatures in the range of 850 °C and 1150 °C10,11,13,14,25, or the use of plasma systems to reduce the deposition temperature, both of which can damage fragile substrates26. Recently, however, we have recognised that aerosol assisted (AA)CVD (a variant of traditional CVD which uses aerosol droplets to transport the precursor solution to the heated reaction zone) can lead to the formation of tungsten oxide nanostructures via a VS mechanism at relatively low onset temperatures, attributed to formation of reactive intermediates during deposition27. This method, which works at atmospheric pressure and relies on a solution-based delivery approach, is advantageous over traditional CVD as it allows for a wider range of precursors to be utilised28. It also allows for the functionalization of SMOx nanostructures with metal nanoparticles (NPs) in a single processing step via co-deposition, which we have demonstrated previously for incorporation of gold29, platinum30 or other SMOx (e.g. Cu2O31 and Fe2O332) nanoparticles segregated at the surface of tungsten oxide nanostructures.

There are very few reports on synthesis of tin oxide or tin oxide composites via AACVD, with most referring to the formation of thin films33,34,35,36,37,38,39,40 rather than nanostructures. The precursors used for the AACVD of tin oxide include common precursors used in traditional CVD41, such as monobutyltin trichloride (C4H9SnCl3)38,40, and tin(II) chloride dihydrate (SnCl2·2H2O)33,42, tin complexes [Sn(18-Cr-6)Cl4]34 and [Sn(H2O)2Cl4](18-Cr-6)34, or for the deposition of composite films bimetallic complexes such as C29H40FeO2Sn37, C35H28FeO2Sn37, or [ZnSn(dmae)(dmaeH)2(NO3)Cl4]·2H2O39.

Here we demonstrate the AACVD of SnO2 nanostructures, in the form of NRs, from a simple commercial tin precursor (SnCl4·5H2O) at atmospheric pressure and exceptionally reduced process temperatures compared to existing VS-based CVD methods. In addition, to enhance the functionality of tin oxide we use the co-deposition opportunities afforded by AACVD to incorporate, in the same single-step, Au NPs at the surface of tin oxide NRs. These non-functionalised (SnO2) and functionalised (Au@SnO2) nanostructures are directly integrated into silicon micromachined platforms (fabricated using Micro-Electro-Mechanical-System (MEMS) technology) and validated for gas sensing, with sensors based on Au-functionalised SnO2 NRs demonstrating enhanced properties.

Results

AACVD of SnO2

AACVD of SnCl4·5H2O dissolved in acetone or methanol at temperatures between 300 and 675 °C resulted in the formation of adherent uniform greyish films on silicon wafers. XRD analysis confirmed the presence of tetragonal SnO2 (P42/mnm, a = 4.7380 Å, c = 3.1870 Å, literature P42/mnm space group, a = 4.7382 Å, c = 3.1871 Å; ICCD card no. 41-1445) for all the films (Fig. 1), except for those deposited from a methanol-based solution at temperatures exceeding 500 °C (Fig. S1), which showed extra diffraction peaks corresponding to metallic tin (I41/amd, a = 5.8310 Å, c = 3.1820 Å, ICCD card no. 4-673).

Figure 1: Typical XRD pattern of the SnO2 NRs deposited at temperatures between 300 and 620 °C from a solution of SnCl4·5H2O dissolved in acetone.
figure 1

The diffraction peaks in the data can be indexed to a tetragonal phase (P42/mnm, ICCD card no. 041-1445) of tin oxide.

The morphology of the films was strongly dependent on the deposition temperature, solution concentration and solvent. For instance (Fig. 2), the films deposited from acetone-based solution (12.5 mM) displayed uneven morphology at 500 °C and porous structures with twinned crystallites at 600 °C, whereas the films deposited from lower solution concentration (8.5 mM) showed the formation of porous films with defined crystallites at 500 °C, a high density of leaf-like structures at 550 °C, and the formation of a high density of NRs at 600 °C. An increase in temperature from 600 °C to 620 °C improved the definition of the NRs, and above this temperature (up to 675 °C) the structures suffered deformations with less material deposited on the substrate, most likely due to homogeneous gas-phase reaction resulting in the formation of powder and the action of thermophoretic forces. A further decrease of solution concentration to 4.3 mM ended-up without visible film deposition. Similar test were carried out for methanol-based solutions, which produced porous films for solution concentrations of 12.5 and 8.5 mM in the temperature range of 300 °C and 675 °C (Fig. S2), and no visible deposition when the concentration was decreased to 4.3 mM.

Figure 2
figure 2

Film morphology observed by SEM images at different solution concentrations and various deposition temperatures.

Estimation of the energy activation for the perpendicular growth () of the films43 via the Arrhenius equation indicated lower for films grown from acetone-based solutions (16.2 kJ/mol) compared to films grown from the methanol-based solutions (27.4 kJ/mol), the latter being in agreement with the value reported in the literature (24.12 kJ/mol)44 for the CVD of planar SnO2 films from SnCl4·5H2O.

SnO2 NRs

Detailed examination of the NRs formed at 620 °C via AACVD suggest that the structures have a prism-like morphology terminated in a pyramidal cap (Fig. 3a), with a total length of ~700 nm and apparently wider sides at the highest part of the prism (~100 nm) in contrast to the base (Fig. 3b), corresponding to an aspect ratio of approximately 7. TEM imaging of the NRs end-cap indicates a similar morphology to that observed by SEM with an apex and lateral angle of 133.8° and 113.3°, respectively (Fig. 3c). These geometrical features are consistent with the models reported previously on the study of octahedral SnO2 structures synthesized from SnCl4·5H2O via a hydrothermal process45, and suggest that the pyramidal caps and the prism-like base might be enclosed by the {111} and {110} facets, respectively.

Figure 3
figure 3

Cross-section SEM (a,b) and TEM (c) images of SnO2 NRs grown at 620 °C from SnCl4·5H2O dissolved in acetone (8.5 mM). The insets show the NR view models (not to scale).

The Sn 3d region of the XPS spectra for the SnO2 NRs (Fig. 4a) exhibited Sn 3d5/2 and Sn 3d3/2 doublets for binding energies of ~486.3 and ~494.7 eV, respectively, confirming the presence of the Sn4+ oxidation state46,47. In addition, the good symmetry of the peaks, showing no sub-components, suggests the absence of Sn2+. The O 1s core level (Fig. 4b), in contrast, indicates the presence of two components, with the main peak at ~531 eV, assigned to the lattice oxygen, and a shoulder at ~532.5 eV, which is assigned to contamination (organic fragments) on the samples in light of the lack of additional structures on the Sn 3d core level46. Both WDX and XPS analysis showed no evidence of chlorine contamination and similar tin contents (anal. calcd. for SnO2: Sn 33.27 and O 66.53 at.%, found WDX: Sn 30.18 at.%, found XPS: Sn 30.30 at.% with a O/Sn ratio of 1.9 taking into account only the component assigned to lattice oxygen). The formation of SnO2 at this temperature is consistent with the TGA of SnCl4·5H2O, which has been shown to produce nearly stoichiometric tin oxide from 450 °C to 700 °C41,48.

Figure 4
figure 4

XPS spectrum of the SnO2 NRs grown at 620 °C from SnCl4·5H2O dissolved in acetone (8.5 mM).

Au@SnO2 NRs

The films synthesised at 620 °C by co-deposition via AACVD of tin and gold precursors dissolved in acetone resulted in the formation of adherent uniform greyish films on silicon substrates, with similar appearance to those deposited from only the tin precursor. SEM imaging of the Au@SnO2 films revealed a high density of NRs (Fig. 5a) with similar features to those observed for intrinsic SnO2 films deposited at 620 °C (Fig. 2), though with apparently small particles dispersed at the surface. Similarly, TEM imaging of the functionalised NRs displayed NPs along the NR surface (Fig. 5b c), which indicate the incorporation of Au NPs as noticed previously when co-depositing gold with tungsten oxide nanoneedles29. The NPs showed spherical morphologies and sizes up to 35 nm; an analysis of the size distribution of these particles via TEM was complex due to NRs tending to agglomerate on the TEM grids and the relatively high thickness of NRs.

Figure 5
figure 5

SEM (a) and TEM images at low (b) and high (c) magnification for the Au@SnO2 NRs.

XRD of the Au@SnO2 NRs (Fig. 6a) revealed similar pattern than that observed for intrinsic SnO2 NRs (Fig. 1) showing a tetragonal phase (P42mnm space group, a = 4.7382 Å, c = 3.1871 Å; ICCD card no. 411-1445), with an extra weak diffraction at 44.3 degrees corresponding to the (200) reflections of gold face centred cubic phase (Fm3m space group, a = 4.07860 Å; ICCD card no. 04-0784). XPS of the films indicated a (0.9 at.%) 3.7 wt.% Au in the films with the characteristics of Au 4f core level spectra being in agreement with that reported for gold metal29, which suggests the gold NPs incorporated at the surface of the tin oxide NRs are in the metallic state. The Au:Sn ratio determined by XPS (found: Au:Sn 3.22 at.% (5.23 wt.%)) and compared to the initial ratio present in the precursor solution used for AACVD (anal. calcd for Au:Sn 23.2 wt.%) showed the incorporation of gold NPs is about 23% efficient, which is higher compared to the efficiency (5%) obtained previously for the co-deposition of tungsten oxide and gold30, likely due to the higher temperature of deposition.

Figure 6
figure 6

Typical XRD pattern of the Au@SnO2 NRs (a) indexed to a tetragonal phase (P42/mnm, ICCD card no. 041-1445) of tin oxide and to the gold face centred cubic phase (Fm3m, ICCD card no. 04-0784). Au 4f core-level spectrum recorded on Au-functionalised tin oxide NRs (b).

SnO2 and Au@SnO2 NRs integrated into micromachined platforms

The SnO2 and Au@SnO2 films grown directly into the micromachined platforms (Fig. 7a) via AACVD at 620 °C, showed similar diffraction patterns (Fig. 7b) with NR-like morphology (Fig. 7c d) compared to that observed for the same deposition conditions on silicon wafers (section SnO2 NRs and Au@SnO2 NRs). Measurements of the electrical resistance of the films using the microelectrodes confirmed a good electrical contact, with the resistance at different sensor operating temperatures showing a direct dependency of the conductivity to the temperature, as expected for an n-type semiconductor. The apparent energy activation for electrical conduction () estimated for temperatures between 250 °C and 350 °C yielded a value of 0.35 eV for the SnO2 NRs, which is consistent with the for porous SnO2 (between 0.28 eV and 1.1 eV) reported previously49. The estimated for the Au@SnO2 NRs, in contrast, yielded a much lower value (0.11 eV), approximately 69% less than the obtained with the SnO2 NRs. This change is much higher compared to that recorded previously for the co-deposited Au-functionalised tungsten oxide (Au@WO3) structures, which showed only 9% lower compared to the non-functionalised tungsten oxide structures30. These numbers show a close relation with the theoretical differences in the work functions (WF) of these materials, as the WF of Au (4.8 eV)50 is 16% and 2% lower than that of SnO2 (5.7 eV)2 and WO3 (4.9 eV)51, respectively, and the relative value of these differences (i.e. 8) is similar to that found for the of Au@SnO2 and Au@WO3 (i.e. 7.7).

Figure 7
figure 7

Photograph of the 4-microsensor array mounted on a standard TO-8 package (a), XRD of a single microsensor based on SnO2 nanorods (platinum and boron nitride diffractions come from the microsensor platform) (b) and SEM images at low (c) and high (d) magnification of the SnO2 material grown onto the microplatform (EG represents the electrode gap).

Gas sensing characterization

Gas sensing tests were carried out to H2 and CO at various operating temperatures between 250 and 390 °C using dc resistance measurements. The temperature dependency of the sensor response for each analyte and concentration is displayed in Fig. 8a and S3a. Results for H2 suggest a similar trend for sensors composed of SnO2 and Au@SnO2 NRs, with slight changes of the response by increasing the operating temperature, whereas results for CO display a tendency to increase the sensor response by increasing the operating temperature, particularly for sensors comprised of Au@SnO2 NRs. Figure 8a and S3a also reveal greater sensor responses for the Au-functionalised NRs compared to the intrinsic NRs, with higher increments (12-fold) for H2 than for CO (2-fold), which reduces the cross-response of these analytes and in turn improves the selectivity of the device. The typical change of resistance recorded for each type of sensor is shown in Fig. 8b and S3b. Overall, the sensor responses displayed an n-type behaviour, i.e. decreasing electrical resistance when exposed to H2 or CO. During the testing period (i.e. 100 h) the sensor response showed good reproducibility with standard errors below ±1.5%, and little variation of the baseline resistance at each operating temperature (below ±6%), with the SnO2 NRs showing lower baseline resistances compared to the Au@SnO2 NRs (e.g. 4.5 kΩ for SnO2 and 50 kΩ for Au/SnO2 at 290 °C). With the injection of humidity (90% RH) in the system, at operating temperature of 290 °C, the baseline resistance of the sensors increased up to 5.5 kΩ for sensors based on SnO2 NRs and 120 kΩ for those based on Au@SnO2 NRs. Under these conditions the electrical resistance changes to H2 remained stable and reproducible, but the sensor response was higher compared to the response obtained in dry air (Fig. 8), showing an increase of the sensor response to H2 up to 18% for the SnO2 NRs and 140% for the Au@SnO2 NRs, indicating decreased humidity tolerance of the SnO2 NRs after decoration with gold NPs.

Figure 8
figure 8

Sensor responses to 250 and 500 ppm of H2 as a function of the operating temperature (a) and film-resistance changes towards 500 ppm of H2 at 290 °C (b). The response to 500 ppm of H2 in humidity (90% RH) is displayed in both plots.

A detailed view of the normalised response to H2 at 290 °C for the sensors based on SnO2 and Au@SnO2 NRs show the characteristics of the response (tR) and recovery (trec) time, and the time needed to reach stationary state when exposed to H2 (Fig. S4). The overall view of the response and recovery times as function of the temperature for each type of sensor towards H2 (Fig. 9) suggests a decrease in the response and recovery time of the sensor as the operating temperature increases. Results in Fig. 9 also show faster response times for the Au@SnO2 NRs compared to intrinsic NRs, and an inverse relationship of the recovery time with respect to the response time, i.e. longer recovery times for Au@SnO2 as opposed to SnO2. Similar comparison between the non-functionalised and Au-functionalised tungsten oxide structures studied previously showed a similar tendency of the response/recovery time30.

Figure 9
figure 9

Response (a) and recovery (b) time for each type of sensor towards 500 ppm of H2. The response and recovery times at 290 °C in humidity are also shown in the plot and represented by a star.

After 100 h of testing the sensor alternately to H2 and CO in dry and humid environment and at different operating temperatures, the gas sensitive nanostructures where examined again using SEM and XRD. In comparison to the initial samples the morphology of the SnO2 and Au@SnO2 NRs was unchanged and the diffraction patterns were identical, indicating a good stability of the devices.

Discussion

The AACVD of SnCl4·5H2O allowed for the synthesis of nanostructured SnO2 films by adjusting the deposition temperature, the precursor concentration and solvent used to produce the aerosol. The ideal conditions for growing SnO2 NRs were found using a solution 8.5 mM of SnCl4·5H2O dissolved in acetone at 620 °C (Fig. 2), a much lower temperature compared to other CVD methods based on VS mechanism which require temperatures exceeding 850 °C10,11,13,14,25. The AACVD of SnO2 NRs via VS mechanism at this relatively low temperature can be connected to two factors: a drop of the energy activation for the perpendicular growth of the film registered when using acetone (16.2 kJ/mol) instead of methanol as carrier solvent, and a decrease of the number of precursor molecules per volume induced by reducing the initial solution concentration about 30%. This is consistent with previous analysis of the growth mechanism of tungsten oxide nanorods via AACVD, which indicated that the transition from planar to nanorod films (characterised by the Frank-van der Merwe and Volmer-Weber growth mode, respectively) at a fixed temperature requires the attenuation of these factors (i.e. and density of precursor molecules)43. As the same deposition temperatures and AACVD parameters (e.g. flow, gas carrier, solution concentration) for the different systems were kept constant with the exception of the ‘carrier’ solvent, it is therefore reasonable to suggest that the use of solvents such as acetone and methanol, which can decompose via radical mechanism at these temperatures52,53,54, might also add active reactive products to the reaction in AACVD. This has a direct influence on the decomposition profile of the tin precursor and in turn modifies the energy activation for the perpendicular growth rate of the film promoting formation of nanostructured growth. The presence of metallic tin at 600 °C when using a methanol solution (Fig. S1) corroborates this hypothesis, as this suggests a different chemical species, with a different decomposition profile to the initial precursor, is involved in the AACVD process when this solvent was used. Acetone may also play a similar role in the decomposition mechanism of the tin precursor but results suggest it is less reactive than methanol. The change in reactive chemical species is likely to affect the reaction time and hence the ratio between this and the reactor residence time, parameters which have previously been shown to be involved in the transition from planar to columnar-like structures55.

The incorporation of a second precursor (HAuCl4·3H2O) during the AACVD of SnO2 NRs allowed for the co-deposition of Au@SnO2 NRs, similar to our previous results for the co-deposition of gold NPs with tungsten oxide nanostructures29,30, although requiring use of a different carrier solvent and higher deposition temperatures (acetone at 620 °C instead of methanol at 400 °C for tungsten oxide). Overall, the analysis of these structures showed that the gold NPs incorporated at the tin oxide NRs are in metallic state (Fig. 6b) with no evidence of modification of either the morphology (Fig. 5) or the crystalline structure (Fig. 6a) of the NRs. However, the lower energy activation of conduction () estimated for the Au@SnO2 samples (0.11 eV) compared to that of the intrinsic SnO2 (0.35 eV) may suggest the presence of Au-O bonds at the surface of the NPs, as inferred earlier for the co-deposited gold NPs on tungsten oxide30.

The direct integration of these structures (SnO2 and Au@SnO2) with micromachined platforms was achieved, demonstrating this process and the associated temperature are compatible with the complementary electronics on these devices. The capability to integrate nanostructured materials with microsystems, such as those used in this work (i.e. fabricated by MEMS technology), represents a technological advantage for gas sensing, as MEMS sensor platforms provide low power consumption features and are suitable for integrating monolithic sensor arrays. Sensor testing showed an optimum operating temperature for SnO2 of 300 °C, a temperature frequently reported for SnO2 when sensing H2 and CO, Table 1. At this temperature (i.e. 300 °C) the micromachined sensors registered 16-times less power consumption (32 mW) than the traditional planar ceramic sensors (525 mW) used in our previous works for tungsten oxide29.

Table 1 Summary of the gas sensing properties of non-functionalised tin oxide reported in the literature for H2 and CO.

Overall, validation of these devices towards the detection of H2 and CO showed good performance with stable signal, very low drift of electrical resistance over the testing period and relatively fast response. These characteristics are highly enhanced compared to our previous sensors based on SnO2 NPs synthesised via AACVD of tin complexes34; which showed a very slow and low resistance change to NO2 and non-sensitivity towards H2 or CO. A direct comparison of our results and those of the literature is relatively complex, as the performance of the sensor is not only linked to the material properties, but also in part to the characteristics of the transducers and test conditions (e.g., operating temperatures, flows, and gas concentrations). Despite this we believe that Table 1 can still be useful to evaluate the tendency of SnO2 towards the analytes tested in this work. Consequently, this comparative table suggests that the SnO2 NRs synthesised via AACVD provide higher sensitivity (S) to H2 compared to that recorded in other works for this analyte. In contrast, the sensitivity obtained for CO reveals a much lower value with respect to that observed for hydrothermal synthesised grains, although marginally higher than that reported for electrospun tin oxide fibres. These differences could be linked to some technological characteristics of each sensor, for instance the use of platinum top electrodes in the sensor architecture of the electrospun films, or the use of transfer steps and most likely the introduction of impurities when integrating the tin oxide films synthesized via hydrothermal or thermal evaporation method into the sensor platforms. In fact, impurities such as chlorine (typically introduced from the precursors), or potassium and calcium (often introduced by the use of transfer steps) have been demonstrated to play a relevant role in the surface activity and sensing properties of tin oxide56; most of the tin oxide films in Table 1 were synthesised from chlorine containing precursors (i.e. SnCl4 and SnCl2) or integrated using transfer steps. The analysis of our SnO2 NRs integrated directly on the micromachined platform though showed no evidence of chlorine, likely due to easy elimination via HCl from the SnCl4·5H2O precursor.

The shape and geometry of the AACVD NRs showed similar characteristics to those reported previously in prism-like rods45, suggesting a surface likely dominated by the SnO2 {110} facets. The presence of these facets, which have shown to be less favourable for CO adsorption due to the need of a particular adsorption geometry with the C-end orientated to the surface2, may be responsible for the attenuation of the response to CO compared to H2. No equivalent studies were found for H2, however as the adsorption of H2 includes the formation of intermediate molecules as water, and these have shown more favourable adsorption on SnO2{110} surfaces2, the higher responses registered for H2 in dry and humid air seem consistent.

The functionalization of the SnO2 NRs with Au NPs showed enhanced sensing characteristics, compared to the intrinsic SnO2 NRs, which include higher sensor response, (almost 12- and 2-times more for H2 and CO respectively) and a reduction of the response time of about 6 times. However, the functionalization also showed a tendency to reduce the sensor tolerance to humidity, inducing a larger change of the response to hydrogen in humid ambient compared to the non-functionalised SnO2 NRs. This characteristic is undesirable in gas sensing and seems to be related to both the propensity of SnO2 to adsorb hydroxyl groups on the surface at the temperature used for this test57, and the amplification of the response by analogous mechanisms than those involved in the enhancement of H2 and CO sensing. The mechanisms that lead the metal NPs functionalised SMOx to an enhanced gas sensing performance has been discussed in the literature previously, and generally involve surface dependent effects (i.e. chemical sensitization, which may include mechanisms such as spill-over and complementary decomposition) and/or interface dependent effects (electronic sensitization, which may include the modulation of potential barrier heights, carrier injection and conduction channel modulation)58,59,60. The faster response in the Au@SnO2 compared to the SnO2 NRs gives evidence of a chemical sensitization, with the Au NPs most likely accelerating the dissociation of hydrogen molecules into H atoms and simultaneously inducing a faster saturation of the active sites on the NR surface via spill-over. This saturation (also observed in the response (Fig. S4) of the sensors based on Au@SnO2 NRs as opposed to those based on SnO2 NRs) is responsible for the larger desorption time required to recover the baseline resistance at each temperature (Fig. 9). In contrast, the lower obtained for the Au@SnO2 NRs compared to the SnO2 NRs indicates an electronic sensitization, with the Au NPs facilitating the carrier injection and thus modulating the conduction channel along the nanostructure.

The ratio of the response to H2 and CO for each microsensor (ΔR = 2.5 for SnO2 and ΔR = 20 for Au/SnO2) indicates relatively higher cross-sensitivities for the microsensors comprised of intrinsic SnO2 NRs, as opposed to those comprised of Au@SnO2 NRs, which potentially improves selectivity to H2. A comparison of these ratios with those recorded for similar systems synthesised via sol-gel in the literature61 revealed similar values for the SnO2 NRs and nearly 7 times higher values for the Au@SnO2 NRs, suggesting the functionalisation of SnO2 with Au NPs via AACVD is effective for improving the selectivity of tin oxide towards H2 and CO.

In summary, these results demonstrate the AACVD of SnO2 NRs via VS mechanism at exceptionally reduced process temperature compared to existing CVD methods with no need for substrate pre-treatment. This allowed for the direct integration of these nanostructures into micromachined platforms and their use for sensing H2 and CO. The incorporation of Au NPs at the surface of the SnO2 NRs via co-deposition improved the functionality of SnO2, particularly to H2, reducing the cross-sensitivity of this analyte to CO.

Conclusions

SnO2 NRs with an aspect ratio of approximately 7 were synthesized without catalyst seeds via AACVD of SnCl4·5H2O at 620 °C, a much lower onset temperature compared to other CVD methods based on a VS mechanism, which typically requires temperatures exceeding 850 °C. The evolution of nanorod SnO2 is linked to an increase in energy activation of the perpendicular growth of about 40% respect to that observed for non-nanostructured SnO2 films, and is attributed to the use of acetone as solvent carrier, and a reduction of precursor concentration. Co-deposition of Au NPs (<35 nm) and SnO2 NRs via AACVD was also achieved at 620 °C. The gas microsensors based on the intrinsic SnO2 and Au@SnO2 NRs were validated towards H2 and CO and show sensing properties that are in agreement with the literature, with notable enhancement of sensing properties for Au@SnO2 NRs which showed 12-fold higher response with 6-fold faster response and improved selectivity to H2 compared to the gas sensors based on intrinsic SnO2 NRs.

Experimental Section

SnO2 synthesis

SnO2 nanostructures were deposited at temperatures between 300 and 675 °C via aerosol assisted (AA) CVD of tin (IV) chloride pentahydrate (SnCl4·5H2O, Sigma-Aldrich, ≥98%) dissolved in 15 ml of acetone. In order to vary the concentration of the solution, three different weights (45, 30 and 15 mg) of SnCl4·5H2O were used for the deposition. A piezoelectric ultrasonic atomiser (Liquifog, Johnson Matthey) operating at 1.6 MHz was used to generate an aerosol of the solution. The aerosol droplets were transported to the heated substrate by a nitrogen (BOC, oxygen free) gas flow (200 cm3·min−1), and the time taken to transport the entire volume of solution was typically 15 minutes.

Au@SnO2 synthesis

Nanocomposites composed of gold NPs and tin oxide NRs were synthesised at 620 °C by co-deposition, via AACVD, of tin (IV) chloride pentahydrate (30 mg, SnCl4.5H2O, Sigma-Aldrich, ≥98%) and tetrachloroauric acid trihydrate (4.2 mg, HAuCl4·3H2O, Sigma-Aldrich, 99.9%) dissolved in acetone (15 ml, Sigma-Aldrich, ≥99.6%) using the same system described above and following the method reported in literature29.

Substrate and micromachined platforms

Silicon wafers (10 mm × 10 mm × 0.37 mm) and KBr disks were used as substrates for film analysis, whereas micromachined platforms consisting of an array of four SiO2/Si3N4/SiO2 membrane, each of them with isolated polysilicon heaters and platinum electrodes (gap: 50 μm, thick: 0.2 μm), were used for gas sensor fabrication. After deposition of the sensing active film the platforms were mounted on a TO8 package. The sensor technology was described in detail previously62.

Film analysis

The morphology of the samples was examined using Scanning Electron Microscopy (SEM — Jeol 6301F, 5 keV). The structure using X-Ray Diffraction (either XRD — Bruker, AXD D8- Discover for the films grown on silicon wafers or Rigaku Smartlab 9 kW for the films grown on micromachined platfoms) and the chemical composition using Wavelength Dispersive X-Ray (WDX — Philips, XL30ESEM) and X-ray Photoelectron spectroscopy (XPS) (Thermo Scientific K-Alpha, using Al Ka radiation operated at 0.6 eV with electron gun operating at 1 eV and argon-ion gun operated at 10 eV; the binding energies were calibrated to the C 1s peak at 284.5 eV). TEM (JEOL JEM-100CX II, 100 kV) images were carried out on samples prepared by deposition on KBr substrates followed by dissolution of the substrate in distilled water and suspended on Cu grids.

Gas sensing tests

Gas sensors were tested in a continuous flow (200 sccm) test chamber (280 cm3) as previously described62. The sensors were exposed to 250 and 500 ppm of hydrogen and carbon monoxide for 10 min and subsequently the chamber purged with air until initial baseline resistance was recovered. The whole testing period comprised of 100 h during which sensors were tested to different hydrogen and carbon monoxide concentrations at operating temperatures between 250 and 390 °C in dry and humid ambient, performing 5 replicates for each condition. To obtain the desired analyte concentration calibrated cylinders of either hydrogen (Praxair, 1000 ppm) or carbon monoxide (Praxair, 1000 ppm) were mixed with pure synthetic air (Carburos Metálicos, 99.99%) by means of a mass flow system (Bronkhorst hi-tech 7.03.241). The sensor response was defined as R = Ra/Rg, where Ra is the sensor resistance in air at stationary state and Rg represents the sensor resistance after 10 min of the analyte exposure. The response time was defined as the time required for the sensor to reach 90% of the sensor response, and the recovery time as the time required to reach 10% of the initial baseline resistance after the analyte was purged.

Additional Information

How to cite this article: Vallejos, S. et al. Aerosol assisted chemical vapour deposition of gas sensitive SnO2 and Au-functionalised SnO2 nanorods via a non-catalysed vapour solid (VS) mechanism. Sci. Rep. 6, 28464; doi: 10.1038/srep28464 (2016).