Sensors and Actuators B 111–112 (2005) 45–51 Gas sensing properties of nanoparticle indium-doped WO 3 thick films V. Khatko a,∗ , E. Llobet a , X. Vilanova a , J. Brezmes a , J. Hubalek b , K. Malysz b , X. Correig a a Department d’ Enginyeria Electronica, Campus Sescelades, Universitat Rovira i Virgili, 43007 Tarragona, Spain b Department of Microelectronics, Technical University of Brno, 60200 Brno, Czech Republic Available online 11 August 2005 Abstract The gas sensing properties of pure and indium-doped nanoparticle WO 3 thick films were studied. Sensors were prepared using commercial WO 3 nanopowders and powder mixtures with different concentrations of In (1.5, 3.0 and 5.0wt.%). The gas sensing properties of the sensors to nitrogen dioxide, carbon monoxide, ammonia and ethanol were investigated. It was observed that the pure nanoparticle WO 3 sensing layers began to react with nitrogen oxide at room temperature. These sensors had maximum sensitivity to NO 2 at 100 ◦ C. The indium-doped WO 3 -based sensors were selective to NO 2 and CO at 200 and 300 ◦ C, respectively. A mechanism for such behaviour is discussed. © 2005 Elsevier B.V. All rights reserved. Keywords: Pure and indium-doped tungsten oxide thick film; WO 3 gas sensor; Gas sensing properties 1. Introduction Nowadays, WO 3 -based thick films are considered as one of themostinteresting materials for detectingnitrogenoxides and other species such as NH 3 ,CH 4 and CO [1–6]. Reduc- ing the grain size of active layers is one of the key factors to enhance the gas sensing properties of semiconductor metal oxide sensors [7,8]. Additionally, the inclusion of differ- ent doping metals in the sensing films has been shown to increase their sensitivity to specific gases. In very recent papers, the effects of doping either with In or indium oxide on the response of tin oxide to hydrogen [9,10], methanol and carbon monoxide [11] have been investigated. An important reduction in the operating temperature of the sensors for opti- mal sensitivity to these species has been reported. The aim of this work is to study the sensing properties of nanoparticle WO 3 gas sensors doped with In. A mechanism of response to NO 2 and CO will be presented and discussed. 2. Experimental Sensors were fabricated by screen-printing onto alumina substrates. A heating element and a temperature sensitive ∗ Corresponding author. Tel.: +34 977558653; fax: +34 977559605. E-mail address: vkhatko@etse.urv.es (V. Khatko). meander on the backside substrate and interdigited gold elec- trodes on the front side of substrate were prepared by using commercial platinum (Heraeus C3657) and conductive (ESL 8884) pastes, according to the sensor fabrication procedures reported in [12]. The commercial WO 3 nanopowder (Aldrich 55,008-6) with calculated spherical diameter up to 33.1 nm was mixed with InCl 3 using special technology to ensure: the breaking of In Cl bonds, the removal of Cl atoms and the uniform distribution of indium atoms in the tungsten oxide powder mixture. Three powder mixtures with an In/W atom ratio equal to 1.5, 3.0 and 5.0 wt.% were prepared. On the basis of the pure nanopowder and these powder mixtures, the gas sensing layers were deposited onto the electrodes using an organic binder. Glass frit (4.9 wt.%) was used for the preparation of the sensing layers based on pure WO 3 nanopowder, to ensure a good adhesion to the substrate. After being deposited, the active layers were dried at 125 ◦ C for 10 min and fired at 600 ◦ C for 20 min. The gas sensing properties of the sensors to nitrogen dioxide, carbon monoxide, ammonia and ethanol were inves- tigated. The sensors were kept in a temperature and moisture controlled test chamber (40 ±1 ◦ C and 41–43% R.H.). The sensors were operated at ambient temperature, 100, 150, 200, 250, 300 and 350 ◦ C to analyse the effect of the working tem- perature on their response. The resistance of the sensors in the presence of either pure air (R air ) or the differentpollutants 0925-4005/$ – see front matter © 2005 Elsevier B.V. All rights reserved. doi:10.1016/j.snb.2005.06.060 46 V. Khatko et al. / Sensors and Actuators B 111–112 (2005) 45–51 (R gas ) at different concentrations was monitored and stored in a PC. The morphology of the sensing layers was determined by JSM 6400 scanning electron microscope. In order to obtain high-resolution SEM pictures and chemical element distri- bution, the samples were coated with ultra thin gold and carbon layers, respectively. The phase composition of the sensing layers was determined by X-ray diffraction (XRD) measurements using a Siemens D5000 diffractometer oper- ated at 40 kV and 30mA with Cu K␣ radiation. 3. Results and discussion 3.1. Gas sensitivity studies For the first set of experiments, the sensing layers based on pure tungsten oxide nanopowders were used. The WO 3 sensors were operated in a working temperature range from room temperature to 350 ◦ C. The gas sensing properties of the sensors to nitrogen dioxide and carbon monoxide were investigated. WO 3 sensors did not change resistance signifi- cantly during their exposure to increasing CO concentrations up to 500 ppm, throughout the temperature range studied. The sensor response of these sensors to nitrogen dioxide had definite features. Fig. 1 shows the influence of the presence of glass frit on the response of un-doped tungsten oxide sen- sors to nitrogen dioxide. It can be seen that the sensors began to react with gas at room temperature (Fig. 1a). At 1ppm of NO 2 the responsiveness calculated using the expression S =(R gas − R air )/R air is shown in Table 1 as a function of the sensor working temperature. In the temperature range from room temperature to 150 ◦ C the sensors with glass frit (WO 2 3 ) show a higher response to nitrogen dioxide than the sensors without glass frit (WO 1 3 ) (see Fig. 1b and c). Furthermore, the response of the former is much faster than the response of the latter. At working temperatures higher than 150 ◦ C the sensor resistance increases monotonously (Fig. 1d) and the sensitivity to nitrogen dioxide decreases. In a second set of experiments, the level of In doping in the response of tungsten oxide based sensors to nitrogen dioxide and carbon monoxide was investigated. The sensors were operated in a temperature range from 150 to 350 ◦ C. Figs. 2 and 3 show the effects of indium concentration in the detection of nitrogen dioxide and carbon monoxide, respec- Table 1 Responsiveness of pure nanopowder WO 3 sensing layers to NO 2 (1 ppm) as a function of the working temperature and thick film composition Thick film composition Working temperature Room temperature 100 ( ◦ C) 150 ( ◦ C) WO 1 3 0.276 3.4 – WO 2 3 – 18.47 0.218 Super-indexes 1 and 2 are for tungsten oxide films without and with glass frit, respectively. Fig. 1. Responses to nitrogen dioxide of pure WO 3 sensors without (WO 1 3 ) and with (WO 2 3 ) glass frit in the paste, operated at room temperature (a), 100 ◦ C (b), 150 ◦ C (c) and 200 ◦ C (d). V. Khatko et al. / Sensors and Actuators B 111–112 (2005) 45–51 47 Fig. 2. Responses to nitrogen dioxide of indium-doped WO 3 sensors with indium concentrations of 1.5 wt.% (WIn 1 ), 3.0 wt.% (WIn 2 ) and 5.0 wt.% (WIn 3 ), operated at 150 ◦ C (a) and 200 ◦ C (b). tively. The In-doped WO 3 sensors were more sensitive to NO 2 when operated at 200 ◦ C and more sensitive to CO when operated at 300 ◦ C. The sensors showed the highest responsiveness to NO 2 when indium concentration was set at 3.0 wt.%. When operated at 200 ◦ C in the presence of 1ppm of NO 2 , the responsiveness of the In-doped tungsten oxide sensors was 0.144, 0.347 and 0.188 for indium concentra- tions of 1.5 wt.% (sensor labelled WIn 1 ), 3.0 wt.% (WIn 2 ) and 5.0wt.% (WIn 3 ), respectively. Fig. 3 shows that only the sensors (WIn 3 ), i.e., doped with In at a level of 5wt.% responded to CO. This responsiveness was up to 0.137. In a third set of experiments the response of the differ- ent sensors to ethanol and ammonia was investigated. The working temperature range varied from 100 to 300 ◦ C. The sensors showed response to ethanol at temperatures higher than 200 ◦ C. Fig. 4 shows the response sensor to ethanol as a function of the concentration of indium in the sensing layers, when operatedat 300 ◦ C. Itcan be seenthata saturation effect in sensor response takes place at 10 ppm of ethanol. Subse- quentinjectionsofethanolto increaseits concentrationto 100 Fig. 3. Responses to carbon monoxide of indium-doped WO 3 sensors with indium concentrations of 1.5 wt.% (WIn 1 ), 3.0 wt.% (WIn 2 ) and 5.0 wt.% (WIn 3 ), operated at 250 ◦ C (a) and 300 ◦ C (b). Fig. 4. Responses to ethanol of indium-doped WO 3 sensors with indium concentrations of 1.5 wt.% (WIn 1 ), 3.0 wt.% (WIn 2 ) and 5.0 wt.% (WIn 3 ), operated at 300 ◦ C. 48 V. Khatko et al. / Sensors and Actuators B 111–112 (2005) 45–51 Table 2 Responsiveness of In doped WO 3 sensing layers to ethanol (10 ppm) as a function of the working temperature and thick film composition Thick film composition Working temperature ( ◦ C) 200 250 300 WIn 1 0.677 0.8 0.723 WIn 2 0.477 0.898 0.845 WIn 3 0.761 0.901 0.874 WIn 1 ,WIn 2 and WIn 3 correspond to indium doping levels of 1.5, 3 and 5 wt.%, respectively. and 500 ppm did not essentially change the resistance of the sensing layers. The responsiveness of the differently doped sensors to ethanol as a function of their working temperature isshowninTable2.Thesensorswithanindiumconcentration of 5.0 wt.% showed the highest responsiveness when oper- ated at 250 ◦ C. The sensor response to ammonia follows an involved pattern (see Fig. 5). The resistance of the different sensing layers increased when 10 or 100 ppm of ammonia were injected into the test chamber, and decreased sharply when ammonia concentration was increased to 500ppm. 3.2. Structural characterisation SEM and XRD investigations were used to explain the experimental results obtained. Fig. 6 shows the surface (Fig. 6a) and the morphology of the pure WO 3 thick film (Fig. 6b) and In doped (5 wt.%) WO 3 thick film (Fig. 6c) sensing layers. It can be seen that the film surface (Fig. 6a) shows a large quantity of cracks. It is assumed that crack for- mation is related to the high (up to 80 ◦ C/min) temperature increase rate at the initial stage of firing. The average gran- ule size in the pure WO 3 sensing layers was up to 60 nm (Fig. 6b). The morphology of the In doped sensing layer did not depend on indium concentration. The tungsten oxide layers were nanoparticular with average granule size around Fig. 5. Responses to ammonia of indium-doped WO 3 sensors with indium concentrations of 1.5 wt.% (WIn 1 ), 3.0 wt.% (WIn 2 ) and 5.0 wt.% (WIn 3 ), operated at 300 ◦ C. Fig. 6. SEM images of a pure WO 1 3 thick film surface (a, b) and indium- doped WO 3 thick film with indium concentration of 3 wt.% 70 nm and had uniform granule distribution (Fig. 6c). It can be seen that the morphology of the pure and In doped WO 3 sensing layers is almost identical. There is just a small dif- ference in the average granule size. XRD data showed that two monoclinic phases (JCPDS cards no. 83-0950 and 87-2386) are present in the com- mercial WO 3 nanopowders. Two monoclinic phases are described in the P2 1 /n (JCPDS cards no. 83-0950) and Pc (JCPDS cards no. 87-2386) space with cell param- V. Khatko et al. / Sensors and Actuators B 111–112 (2005) 45–51 49 Fig. 7. XRD patterns fromWO 3 nanopowders,and pure (WO 1 3 ) and indium- doped WO 3 thick films (WIn 2 and WIn 3 ). eters a = 7.3008, b =7.5389, c = 7.6896, β = 90.892 ◦ and a =5.2771, b=5.1569, c= 7.666, β = 91.742 ◦ , respectively. Fig. 7 presents the XRD patterns from 2θ =22 ◦ to 25 ◦ of WO 3 nanopowder, both pure and In-doped WO 3 thick films. The XRD patterns contain (20 0), (020) and (0 02) reflec- tions of the monoclinic phase described in the P2 1 /n space and (1 1 0) reflection of another monoclinic phase. After the firing process, the sensing layers had mainly the first mon- oclinic phase described in the P2 1 /n space. The presence of metallic indium and indium oxide phase was not detected by the XRD method. On the basis of this result, we can suggest that In 3+ ions were able to diffuse into the tungsten oxide lattice at the firing temperature used. This fact is confirmed indirectly. The basic X-ray lines in the X-ray spectrum show a shiftfromthe standard position thatincreaseswhen the con- centration of indium is increased (see Fig. 7). The crystallite size in the WO 3 nanopowder, and in pure and In-doped WO 3 thick films was evaluated from the diffraction line of (00 2) Table 3 Chemical element distribution in the indium-doped WO 3 thick films Indium concentration in WO 3 thick films (wt.%) Chemical elements O In W In/W (%) 1.5 15.81 1.11 83.08 1.34 3.0 14.54 2.08 83.39 2.49 5.0 14.03 3.81 83.43 4.57 based on the Scherrer equation [13]. D hkl = 0.9λ β hkl cos(θ hkl ) (1) where λ is wavelength of the incident radiation, β hkl the full width at half-maximum(FWHM)of the peak in the radiation, and θ hkl the Bragg angle.Theaverage crystallitesizeofWO 3 nanopowder and pure WO 3 thick film is 30.4 and 45.5 nm, respectively. In In-doped WO 3 thick films this parameter is 49.0nm (1.5 wt.% In), 43.6nm (3 wt.% In) and 43.0 nm (5 wt.% In). An analysis of the chemical element distribution in the sensing layers obtained by energy-dispersive X-ray spec- troscopy (EDX) confirmed the absence of chlorine atoms into the sensing layers. Fig. 8 shows the chemical element distribution into the In-WO 3 sensors with an indium concen- tration up to 3wt.% obtained by EDX. It can be seen that tungsten, indium and oxygen atoms are the only constituents of the sensing layer. Estimation of the In/W ratio in the tung- sten oxide films doped with indium performed on the basis of EDX data were in good agreement with the designed indium concentrations of 1.5, 3 and 5wt.%. These results are sum- marised in Table 3. 3.3. Discussion The data obtained from the first set of experiments show that the high response of pure WO 3 sensing layers (even at Fig. 8. Chemical element distribution in the indium-doped WO 3 sensor with indium concentration of 3 wt.% 50 V. Khatko et al. / Sensors and Actuators B 111–112 (2005) 45–51 very low temperature) is most likely due to the small grain size and the high surface area of these nanopowder films. The surface layer of nanogranules has a non-stoichiometric structure, which contains oxygen vacancies that behave as traps for electrons. The sensing properties of pure WO 3 thick films are con- trolled by their surface defects and structure. A probable rea- son for the high responsiveness to nitrogen dioxide shown by pure tungsten oxide films at 100 ◦ C is the desorption of O 2 − [14]species.NO 2 replacesthedesorbed oxygenspeciesat the surface of the WO 3 thick films, which causes a sharp growth in their resistance. Increasing the working temperature of the sensorschangesthe equilibriumof the adsorption–desorption reaction with NO 2 . The decrease in the number of active adsorption sites when the temperature of the sensor is raised causes a reduction of the sensor response to NO 2 at work- ing temperatures higher than 100 ◦ C. The addition of glass frit increases sensor sensitivity because of the presence of different metal oxide additives. Thefiringprocess undergoneby pureor In-dopedtungsten oxide films at 600 ◦ C does not dramatically increases particle size nor promotes the growth of crystallites. Furthermore, particle size of pure or In-doped films is almost identical due to the fact that indium diffuses into the tungsten oxide lattice. The sensitivity of indium-doped sensors operated at 200 and 300 ◦ CtoNO 2 and CO is determined by the defects generated by the inclusion of indium impurities. During the preparation of powder mixtures and the firing process, In 3+ ions generated from the breaking of In Cl bonds can diffuse into the tungsten oxide lattice and form there an additional number of new defects. On the basis of XRD data it can be derived that these defects are substitutional defects, since the interplanar spacing of the WO 3 crystal lattice decreases when the concentration of indium impurities is increased. Correspondingly, new energetic levels related to the presence of indium atoms are generated in the band gap of the In- loaded WO 3 . These energetic levels are the source of added support of charge that changes the sensing properties of the WO 3 -based sensors. 4. Conclusions The gas sensing properties of pure and indium-doped nanoparticle WO 3 thick films were studied. Sensors were prepared using commercial WO 3 nanopowders and pow- der mixtures with different concentrations of In (1.5, 3.0 and 5.0wt.%). Their response to different concentrations of nitrogen dioxide, carbon monoxide, ammonia and ethanol were investigated. It was found that the pure WO 3 sensors responded to nitrogen dioxide even when operated at room temperature. These sensors showed a maximum sensitivity to NO 2 when working at 100 ◦ C. The fact that pure WO 3 sensing layers show response to NO 2 at low temperatures is due to the small grain size and high surface area of the WO 3 nanopowders. Indium-doped WO 3 sensors were selective to NO 2 and CO when operated at 200 and 300 ◦ C, respectively. In this case, the selectivity of the sensors is determined by the defects generated by indium impurities. Acknowledgement The authorsthank Dr. FrancescGuirado(URV,Tarragona) for performing the XRD measurements on the WO 3 thick films. References [1] P. Shaver, Activated tungsten oxide gas detectors, Appl. Phys. Lett. 11 (1967) 255–257. [2] D.G. Dwyer, Surface chemistry of gas sensors: H 2 SonWO 3 films, Sens. Actuators B 5 (1991) 155–159. [3] A.A. Tomchenko, V.V. Khatko, I.L. Emelianov, WO 3 thick films gas sensor, Sens. Actuators B 46 (1998) 8–14. [4] A.A. Tomchenko, I.L. Emelianov, V.V. 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Biographies Viacheslav Khatko graduated in nuclear physics from the Byelorussian State University (Minsk, Belarus) in 1971. He received his PhD in mate- rial science in 1985 and Dr.Sc. in electronic engineering in 2001. In 1975–2003 he worked at the Physical Technical Institute of National Academy of Sciences of Belarus, Minsk, as a researcher, head of the V. Khatko et al. / Sensors and Actuators B 111–112 (2005) 45–51 51 Laboratory of Electronic Engineering Materials, head of the Thin Film Materials Department and then as Principal Investigator of the insti- tute. He was Ford SABIT Intern and Ford Visiting Scientist in 1998 and 1999, respectively. From April 2003 he is Ram ´ on y Cajal profes- sor in the Electronic Engineering Department at the Universitat Rovira i Virgili (Tarragona, Spain). His current research interests include the development and application of semiconductor thin and thick film gas sensors. Eduard Llobet graduated in telecommunication engineering from the Universitat Polit ` ecnica de Catalunya (UPC), (Barcelona, Spain) in 1991, and received his PhD in 1997 from the same university. During 1998, he was a visiting fellow at the School of Engineering, University of Warwick (UK). He is currently an associate professor in the Electronic Engineering Department at the Universitat Rovira i Virgili (Tarragona, Spain). His main areas of interest are in the fabrication, and modelling, of semiconductor chemical sensors and in the application of intelligent systems to complex odour analysis. Dr. Llobet is a member of the Institute of Electrical and Electronic Engineers. Xavier Vilanova graduated in telecommunication engineering from the Universitat Polit ` ecnica de Catalunya (UPC), (Barcelona, Spain) in 1991, and received his PhD in 1998 from the same university. He is currently an associate professor in the Electronic Engineering Department at the Universitat Rovira i Virgili (Tarragona, Spain). His main areas of interest are in semiconductor chemical sensors modelling and simulation. Jes ´ us Brezmes graduated in telecommunication engineering from the Universitat Polit ` ecnica de Catalunya (UPC), (Barcelona, Spain) in 1993. Since 1993, he has been a Ph.D. student in the Signal Processing and Communications Department at the same university. He has been a lec- turer in the Electronic Engineering Department at the Universitat Rovira i Virgili (Tarragona, Spain) since 1994. His main area of interest is in the application of signal processing techniques such as neural networks to chemical sensor arrays for complex aroma analysis. Jaromir Hubalek graduated in electronic devices and systems from Brno University of Technology (Czech Republic) in 1996. Since 1996 he has been a PhD student at the Microelectronics Department at Brno University of Technology and received his PhD in 2003 from the same university. His work is focused on precise conductivity detector using planar comb electrodes. Since 2000 he has worked in thick-film sensors fabrication at the Electronic Engineering Department at the Universitat Rovira i Virgili (Tarragona, Spain). Karel Malysz graduated in Materials Engineering at University of Par- dubice, faculty of Chemistry and Chemical Technology in 2000. Since 2000 he has been a PhD student at the Department of Microelectronics, Brno University of Technology (Brno, Czech republic). His work focuses on the preparation of new types of semiconductor gas sensors and gas sensing materials. Xavier Correig graduated in telecommunication engineering from the Universitat Polit ` ecnica de Catalunya (UPC), (Barcelona, Spain) in 1984, and received his PhD in 1988 from the same university. He is a full professor of Electronic Technology in the Electronic Engineering Depart- ment at the Universitat Rovira i Virgili (Tarragona, Spain). His research interests include heterojunction semiconductor devices and solid-state gas sensors. Dr. Correig is a member of the Institute of Electrical and Elec- tronic Engineers. . source of added support of charge that changes the sensing properties of the WO 3 -based sensors. 4. Conclusions The gas sensing properties of pure and indium-doped nanoparticle. indium-doped tungsten oxide thick film; WO 3 gas sensor; Gas sensing properties 1. Introduction Nowadays, WO 3 -based thick films are considered as one of