comparative study of nanocrystalline sno2 materials for gas sensor application

We found that commercial SnO2nanopowder has lower thermal stability in comparison with synthesized one, resulting in higher crystallite growth rate and poly-dispersed particle size after

Contents lists available atScienceDirect Sensors and Actuators B: Chemical

j o u r n a l h o m e p a g e :w w w e l s e v i e r c o m / l o c a t e / s n b

Thermal stability and catalytic activity

R.G Pavelkoa,∗, A.A Vasilieva, E Llobeta, X Vilanovaa, N Barrabésb, F Medinab, V.G Sevastyanovc

aUniversity Rovira i Virgili, Department of Electronic, Electrical and Automatic Control Engineering (DEEEA), 43007 Tarragona, Spain

bUniversity Rovira i Virgili, Chemical Engineering Department (DEQ), Tarragona, Spain

cN.S Kurnakov Institute of General and Inorganic Chemistry RAS, Moscow, Russian Federation

a r t i c l e i n f o

Article history:

Received 3 October 2008

Received in revised form

26 November 2008

Accepted 10 December 2008

Available online 24 December 2008

Keywords:

Gas sensor

SnO 2

Long-term stability

Thermal stability

Impurity level

Crystallite growth

a b s t r a c t

In this paper we discuss thermal stability of tin dioxide nanoparticles and long-term stability of the SnO2-based gas sensors Relying on laser-spark element analysis and XRD analysis we compare crystallite growth kinetics of synthesized and commercial (Sigma–Aldrich) SnO2with different impurity level We found that commercial SnO2nanopowder has lower thermal stability in comparison with synthesized one, resulting in higher crystallite growth rate and poly-dispersed particle size after annealing A special attention is drawn to discussion of catalytic activity of the nanocrystalline materials Using IR spectroscopy

we studied chemical composition of the annealed materials, which allowed us to reveal in the synthesized SnO2intensive formation of Sn–OH bonding during annealing We performed temperature programmed reduction (TPR) analysis to compare the catalytic activity of the materials with and without deposited Pd

on SnO2 Long-term stability of the sensors made on the basis of synthesized and commercial SnO2was measured as a sensor signal deviation during 590 h of operation in 0.2, 0.6 and 1.0 vol % of propane in air (50% RH at 20◦C)

© 2008 Elsevier B.V All rights reserved

1 Introduction

During last decades, the development of thick film materials for

tin dioxide based gas sensors enabled the fabrication of sensitive

and relatively selective gas sensors However, long-term stability

of the sensors remains an important problem, which restricts the

application of such devices in industrial and residential gas and

fire alarm systems, electronic noses, etc [1,2] The attempts to

solve this problem by chemical modification of the sensing material

showed that this approach gives hard to predict gas-sensing

proper-ties, because each nanoparticle of SnO2contains only few atoms of

dopant As a result, the number of admixture atoms is random and

can be very far from the one calculated using average concentration

values

In this research, we apply a completely different approach

that consists of synthesizing a very pure tin dioxide material

with extremely low level of sodium, chlorine, and sulfur

contam-ination Using different techniques (laser-spark element analysis,

thermal X-ray diffraction, temperature programmed reduction and

IR spectroscopy) we study both home-made and commercial SnO2

nanopowders to estimate the influence of the impurities on

crys-∗ Corresponding author Tel.: +34 977 558764; fax: +34 977 559605.

E-mail address:rpavelko@yandex.ru (R.G Pavelko).

tallite growth rate during isothermal annealing at 700◦C, as well

as the catalytic activity and surface composition of SnO2materials These results are compared with the ones on long-term stability of the sensors fabricated using the same SnO2materials The role of the impurities in the long-term stability of SnO2-based sensors is discussed

2 Experimental

2.1 Synthesis and characterization of the nanomaterials

As a precursor for the synthesis of tin dioxide nanopowder, we used tin (IV) acetate (Sigma–Aldrich) solution in acetic acid Tin oxide was synthesized by the precipitation from this solution by drop-by-drop addition of an aqueous NH3solution After the precip-itation, the sample was centrifuged and washed several times with deionized water Then the powder was dried carefully at 150◦C and annealed at 300◦C for 12 h As a reference material SnO2 nanopow-der fabricated by Sigma–Aldrich (p/n 549657) was used

The impurity content in both materials was measured by laser-spark mass-spectrometry (EMAL-2) Transmission electron microscopy (TEM) was used to establish the morphology and to evaluate the particle size distributions (Jeol JEM 1011, operating at

100 kV) FTIR spectra were recorded using JASCO 680 Plus spec-trometer (absorption mode, scan times—32, resolution—2 cm−1) at 0925-4005/$ – see front matter © 2008 Elsevier B.V All rights reserved.

room temperature The samples were mixed with KBr powder and

pressed into self-supporting disks

The crystallite growth kinetics was studied by means of Siemens

D5000 diffractometer (Bragg-Brentano parafocusing geometry,

ver-tical −  goniometer, Ni-filtered CuK␣ radiation) equipped with

an Anton-Paar HTK10 heating platform (TXRD) The data were

recorded during isothermal annealing at 700◦C after 1, 6, 18 and

30 h Crystallite size was determined using the Fundamental

Param-eters Approach convolution algorithm implemented in the program

TOPAS 3.0[3] It was assumed for all samples that only crystallite

size affects the XRD peak broadening and no effects of microstrains

were observed in the XRD line width For the calculation of the

crys-tallite size, we used three diffraction peaks corresponding to 110,

101, 121 planes of SnO2cassiterite structure The calculations were

performed according to the Scherrer’s law from the net integral

width of the peaks

Temperature programmed reduction (TPR) study of synthesized

and commercial SnO2 was performed using a ThermoFinnigan

TPD/R/O 1100 instrument equipped with a thermal conductivity

detector (TCD) Before the TPR experiments, the samples (100 mg

of each material) were dried for 24 h in helium flow (20 ml/min) at

120◦C After that, the reduction process in the reducing gas

mix-ture flow (5% H2in argon, flow rate was equal to 20 ml/min) was

started at room temperature and finished at 800◦C at a heating rate

of 10◦C/min Hydrogen consumption was measured using thermal

conductivity detector The TPR study was carried out for pure oxides

and for the oxides with deposited catalyst (1 wt % of Pd)

N2physisorption adsorption–desorption isotherms at 77 K was

measured using Micromeritics ASAP 2010 surface analyzer Before

analysis, all the samples were degassed in vacuum at 393 K for 6 h

2.2 Sensor fabrication

Both synthesized and commercial SnO2materials were

impreg-nated with water solution of palladium complex Pd(NH3)4(NO3)2

Then, the powders were dried at 110◦C, calcined at 300◦C for 10 h

and annealed at 500◦C in order to achieve the Pd complex

decom-position The preset catalyst to carrier ratio was equivalent for all

sensing materials: wPd= 1 wt % Then the powders were mixed with

the solution of ethyl cellulose in terpineol to form printable ink The

ink was deposited on sensor microheater platform, dried for 15 min

at 150◦C and annealed at 700◦C for 15 min to reach the stabilization

of the material

The sensor platforms were made of screen-printed refractory

glass, platinum heaters and electrodes, assembled in TO-8 package

The details can be found elsewhere[4]

2.3 Sensor characterization

The sensor responses were measured in 0.2, 0.6 and 1.0 vol %

of propane in synthetic air at 50% RH The gas concentrations and

gas humidification were prepared with gas mixing system

Envi-ronics 4000 at 20◦C Before the measurements all sensors were

stabilized at operation temperature 450◦C during 100 h The first

measurements, taken for zero point, were carried out after the

sen-sor stabilization, then after 330, 460 and 590 h of operation The

sensors were exposed to the target gas during 10 min, which was

followed by 10 min exposition to pure carrier gas (synthetic air, 50%

RH) The sensor signal was defined as a ratio Rair/Rgas, where Rgas

is the sensing layer resistance in target gas atmosphere and Rair

is the resistance in pure carrier gas Long term stability was

esti-mated as a total deviation of sensor signal after certain periods

of time and was defined as((S n − S n−1)/S n−1)× 100%, where S n

is sensor signal after 330, 460 or 590 h and S n−1is the previous

sen-sor (e.g (S330− S0)/S0, where S0and S330are sensor signals after the

stabilization and 330 h of operation respectively)

Table 1

Concentration of main impurities in SnO 2 materials.

SnO 2 material Impurity content (wt %)

3 Results and discussion

3.1 Material properties

The impurity level of synthesized and commercial SnO2 was estimated by means of laser spark mass-spectrometry for more than 20 widespread elements It was found that commercial mate-rial is highly contaminated with Na and Cl ions (Table 1) High level

of contaminations is related, probably, with the use of tin chlo-ride and sodium compounds as precursor and precipitating reagent, respectively, in the preparation process of tin dioxide nanopowder used by Sigma–Aldrich The material did not become notably purer even after six-fold washing in hot deionized water Therefore, we can conclude that byproducts of the SnO2synthesis are partially incorporated in the crystalline lattice or tight pores of the material and could not be removed completely using conventional chemical methods

Synthesized and commercial SnO2 have BET surface area of

148 m2/g and 17 m2/g, respectively, which corresponds to parti-cle sizes of 3 nm for synthesized and 26 nm for commercial SnO2 (calculated assuming spherical particle shape)

TEM investigation of the oxides shows that synthesized SnO2 consists of uniform particles with mean diameter 3–5 nm (Fig 1) Particles of commercial SnO2are polydisperse: the least diameter

is∼10 nm, while the largest is ∼70 nm (Fig 2a) These results are in good agreement with BET area of the materials

Both materials have cassiterite type crystalline structure The mean crystallite size of SnO2nanopowders before heat treatment, calculated using TOPAS software, was equal to 1.3 and 30 nm for synthesized and commercial SnO2, respectively The temperature range for TXRD study of crystallite growth kinetics was chosen

by several reasons The usual process of formation of metal oxide sensing layers in semiconductor and thermocatalytic gas sensors requires annealing at 700–800◦C[5] This could be used not only

to remove carbon traces of organic vehicle, but for catalyst activa-tion and to stabilize phases as well The latter sometimes requires

Fig 1 TEM image of synthesized SnO (Jeol, JEM 1011).

Fig 2 TEM images of commercial SnO2 before (a) and after (b) annealing at 700◦C

for 1 h.

several hours of annealing In addition, the experimental error in

crystallite size calculation for commercial material was equal to

5.6% at 700◦C, which increases significantly at lower temperatures

due to fewer changes in crystallite size

Fig 3 shows the results of the simulation of the crystalline

growth during annealing at 700◦C The simulation was performed

using a commonly assumed parabolic law describing isothermal

crystallite growth:

where D0is the initial crystallite size, D the current crystallite size,

K the rate constant, N the grain growth exponent factor and t the

annealing time

The difference between both materials becomes more evident,

if we compare their integral crystallite growth rate The integral

rate, calculated asD/t (where D the change in crystallite size

for 30 h of annealing and t the annealing time in hours) was found

equal to 0.026 and 0.14 nm/h for synthesized and commercial SnO2,

respectively The main contribution to high integral growth rate of

commercial SnO2was made during the first 2 h of annealing when

the rate was by a factor of 7 higher than for the synthesized SnO2

Fig 3 Crystallite size of synthesized and commercial SnO2 as a function of annealing

◦

The difference in crystallite growth rates could be explained

by several factors First, the materials have different morphology, which complicates the comparison of the results According to [6] for example, porosity of nanomaterials plays significant role

in crystallite growth kinetics The nitrogen physisorption revealed that commercial SnO2has lower porosity in comparison with syn-thesized material by a factor of ∼2.5 (pore volume equals 0.16 and 0.06 cm3/g for synthesized and commercial SnO2respectively), which is believed should decrease thermal stability However, the most drastic difference between two materials is related to their chemical composition The Na+and Cl−content in commercial SnO2

is more than by 20 times higher in comparison with synthesized one And it is well known that admixtures (especially with high dif-fusion coefficient like Na+and Cl−) in a quantities as low as 10−6to

10−4at % could notably favor grain growth by increasing the defect density of the crystalline lattice[7]

After 30 h of isothermal annealing, TEM particle size for synthe-sized SnO2 equals∼7 nm and particles remain uniform in shape, while for commercial SnO2the particles are in the range 20–150 nm The change in the particle size affects the electrical properties of the material and this will have negative impact on long-term stability

of the sensor[8]

In addition, we found that after 1 h of isothermal annealing, a new phase appears on the surface of commercial SnO2 particles (Fig 2b) This new phase is a result of the thermal migration of impurities (Na and Cl ions), which presence on the surface can lead

to inhibition of catalytic processes[9] FTIR spectroscopy of nanomaterials can provide useful informa-tion about chemical modificainforma-tion of the solid The spectra were recorded on JASCO 680 Plus spectrometer at room temperature for SnO2samples, which undergone isothermal annealing at 700◦C during 1, 6, 18 and 30 h The spectra of commercial and synthesized powders are shown inFig 4

While the spectrum of commercial SnO2 is quite simple with only one intense band between 400 and 800 cm−1, the spectrum

of synthesized SnO2 shows several intense bands: a broad one between 400 and 850 cm−1, a peak around 1620 cm−1, and another broad band at 2000–3650 cm−1 The first band is assigned to dif-ferent stretching vibration of Sn–O bond and during isothermal annealing The maximum of the band shifts to the higher wave numbers that is from 590 to 630 cm−1after 30 h of annealing at

700◦C The right shoulder of the peak also becomes less intense The similar phenomenon is observed for commercial material A weak shoulder near 510 cm−1looses intensity with annealing time, while the peak at∼650 cm−1becomes more intense.

The shoulder in the region 520–560 cm−1corresponds to ter-minal vibration of Sn–O bond, whereas vibrations at higher wave numbers can be ascribed to bridged ones[10] Thus, a decrease

in adsorption band at around 500 cm−1 could be a result of ter-minal group lessening This allows us to conclude that either chemical modification of the surface or growth processes occur during isothermal annealing The following discussion will show that the chemical modification of the surface is more signifi-cant

The bands in the range of 2000–3650 cm−1 can be assigned

to hydroxyl stretching vibrations OH(Sn–OH) of both, terminal and bridged groups, and to stretching vibration in hydrogen bond

OH···O During the annealing, the band becomes more intense and several shoulders appear on the right and on the left side of the band maximum, located at 3416 cm−1 The latter, together with

a small left shoulder around 3230 cm−1, should be ascribed to stretching vibrations of bridged Sn–OH bond The right shoulder around 3545 cm−1is related, probably, to stretching vibrations of terminal Sn–OH group[10] The maximum of the band does not shift during annealing, which indicates that new types of hydroxyl bonding do not take place on the surface Commercial SnO has a

Fig 4 FTIR spectra in the range 400–4000 cm−1 of synthesized (a) and commercial

(b) SnO 2 after drying and after isothermal annealing at 700 ◦ C for 1, 6, 18 and 30 h.

peak in the same range 3250–3650 cm−1with much lower

inten-sity, which is an evidence of lower concentration of hydroxyl groups

on the surface The broad nature of the band indicates that OH

groups are bonded by several modes, including Sn–OH

(termi-nal groups), Sn–(OH)–Sn (bridged groups) and hydrogen bonding

Sn–O···HO–Sn

The band around 1620 cm−1corresponds to the bending mode

of ligand-bonded molecular water (Fig 5a) It is known that

monomeric, dimeric and polymeric water molecules have their

deformation modes at 1600, 1620 and 1633 cm−1, respectively[11]

The evolution of the peak shape with annealing time indicates that,

after approximately 6 h, there are mostly dimers and polymers of

water molecules on the SnO2surface (1616 and 1635 cm−1) The

same situation is observed with commercial material The weak

peak at 1620 cm−1 is a superposition of two peaks at 1616 and

1635 cm−1 However, the quantity of adsorbed water increases with

annealing time only in the case of synthesized SnO2, whereas

com-mercial material loses molecular water during annealing (decrease

in peak intensity)

In a range of 900–1250 cm−1, a broad intense band appears after

1 h of annealing (Fig 5b) According to numerous investigations, this

band corresponds to the deformation modeıOH(Sn–OH) of

termi-nal OH groups[10] It is remarkable that the spectrum of the SnO2

powder dried after wet synthesis does not have any corresponding

vibration mode The intensity of the band increases with annealing

time The band maximum at 1040–1045 cm−1does not shift during

heat treatment

Fig 5 FTIR spectra in the range 1300–1900 cm−1 (a) and 850–1300 cm −1 (b) of syn-thesized SnO 2 after drying and after isothermal annealing at 700 ◦ C for 1, 6, 18 and

30 h.

Summarising, the FTIR spectra manifest that surfaces of synthe-sized and commercial SnO2are very different from the chemical point of view The change in spectrum shape of synthesized SnO2is mostly due to the intensive formation of Sn–OH groups and accu-mulation of molecular water during annealing Taking into account that desorption of chemisorbed water in the range of 280–400◦C results in formation of catalytically active oxygen species (e.g O2−,

O−and O2−) the synthesized SnO2probably will demonstrate in the same temperature range high catalytic activity in oxidation reaction and as a result higher sensitivity to reducing gases[12]

To investigate the oxidation activity of synthesized and com-mercial materials, we performed TPR study of SnO2 with and without Pd (Fig 6) TPR profile of the synthesized SnO2 displays one broad intense peak at 360◦C, followed by the onset of bulk reduction (that is the reduction of SnO2particle bulk) starting from

550◦C Commercial SnO2shows a different profile with small peak around 200◦C and bulk reduction starting from 450◦C The low temperature reduction peak can be attributed to the reduction of surface and subsurface of SnO2, while the bulk reduction of SnO2

is observed at higher temperature (>500◦C) From the results one can easily see that synthesized SnO2demonstrates a higher surface reduction compared with the commercial one This indicates the presence of high amount of active oxidation species, which prob-ably form due to thermal desorption of chemisorbed water The presence of the latter in the synthesized SnO2was proved by FTIR studies

Fig 6 TPR profiles of pure (dash line) and with deposited Pd catalyst SnO2 (bold

line).

Whereas the deposition of 1% of Pd does not affect significantly

the reduction profile of the commercial SnO2(a slight increase in

the reduction of surface species is observed), the profile of

syn-thesized Pd-SnO2solid shows a clear shift to lower temperatures

This reduction peak is shifted from 360◦C to 200◦C However,

the reduction peak for bulk SnO2species remained constant The

H2 oxidation already starts at 100◦C and goes on up to 400◦C,

demonstrating significant decrease in activation energy of

oxi-dation processes This fact is only observed for the synthesized

samples

Thus, the TPR study has proved our assumption about high

cat-alytic activity of synthesized SnO2 and it becomes apparent that

high content of chemisorbed water could be an evidence for high

oxidation ability of material at elevated temperatures

3.2 Sensor characterization

Long-term stability measurements were performed for 590 h

All sensors underwent phase stabilization at operating

tempera-ture 450◦C during 100 h Then sensors were exposed to different

propane concentrations: 0.2, 0.6 and 1.0 vol % in humid air (50%

RH at RT) The first measurement was carried out just after

stabi-lization, which is considered as zero point for long-term stability

experiment, then after 330, 460 and 590 h We used sensing

mate-rials on the basis of synthesized and commercial SnO2with 1 wt %

of Pd

As it can be seen fromFig 7, the responses of the sensors differ

greatly with sensing materials Sensors on the basis of synthesized

SnO2have the highest resistance in humid air, which suggests lower

concentration of free charge carries in the bulk material The

lat-ter could be a result of high surface population with the electron

acceptors like oxygen species: O2 − and O− which is a result of

chemisorbed water desorption On the other hand, the resistance

under target gas is of the same order of magnitude as the resistance

of the sensors on the basis of commercial SnO2

The use of synthesized SnO2 results in the highest signals

(defined as Rair/Rgas) to all propane concentrations For example,

the signal to 0.4% of propane in synthetic air at 50% RH after sensor

stabilization is equal to 42 for synthesized SnO2and 4.5 for

com-mercial SnO2 The drastic difference between both materials can be

explained by higher catalytic activity and high specific surface of

the synthesized material

A distinctive feature of commercial SnO2is that the signals to all

propane concentrations increase with operation time The

crystal-Fig 7 Sensor layer resistance of synthesized (a) and commercial (b) SnO2 with 1 wt.

% of Pd to 0.4% of propane in synthetic air at 50% RH.

lite growth cannot lead to this phenomenon We explain this relying

on TEM results, which demonstrated the formation of a new phase

on the SnO2surface (Fig 2b) After 100 h of phase stabilization at

450◦C, chlorine impurities, known as catalyst inhibitor, cover the surface causing poor sensitivity to target gas[9] This inhibitor, in its turn, takes part in the oxidation processes and vacates the sur-face with oxidation byproducts The elimination of the inhibitor (Cl) from the surface leads to the signal increment

Unlike the previous, the sensing material on the basis of synthe-sized SnO2 demonstrates a slight decrease in signal value during the operation We suppose that signal decrease is a result of crys-tallite thermal growth and surface diminution, which takes place, without any doubts, in both sensing materials The difference is that impurities, apart from causing higher crystallite growth rate, lead

to the ambiguity in the surface chemistry by interacting with target gas and its oxidation products

Fig 8shows results of long-term stability measurements The plot reflects total signal drift defined as(S n − S n−1/S n−1)× 100%

(where S n−1 is previous and S n is current signal after a cer-tain operation time) against operating time for different propane concentrations The highest signal drift is obtained for sensing materials on the basis of commercial SnO2 The highest contribu-tion to the signal deviacontribu-tion for both types of sensors was observed after 330 h of sensor operation The total signal drift after 590 h varies (depending on the target gas concentration) from 0.7% to 1.4% for synthesized SnO and from 16% to 25% for commercial

Fig 8 Total signal drift depending on propane concentration against operation time

of the sensors.

SnO2 in the concentration range under investigation The high

stability of the synthesized material can be explained only by

ther-mal stability of nanoparticles which is a result of low impurity

content

4 Conclusion

XRD crystallite size and TEM particle size analysis indicate the

remarkable thermal stability of synthesized SnO2with low

impu-rity level On the other hand commercial SnO2 with Na and Cl

impurities has poor thermal stability resulting in higher crystallite

growth rate and poly-dispersed particle size after annealing It was

shown that during isothermal annealing, impurities tend to form

individual phase on the particle surface of commercial SnO2

FTIR results manifest significant difference in chemical

compo-sition of the synthesized and commercial materials which mostly

due to the intensive formation of Sn–OH groups and accumulation

of molecular water after annealing This fact can be explained by

high density of surface defect due to low particle size of synthesized

SnO2

TPR experiments manifest that the synthesized material has

high catalytic activity even without deposited catalyst This

indi-cates that desorption of chemisorbed water in the range of

280–400◦C results in formation of numerous oxygen species (e.g

O2 −, O−and O2−), which are known as catalytically active ones in

oxidation processes

As a result of high oxidation activity and high specific surface

area sensors made on the basis of synthesized SnO2have the highest

signals to different propane concentrations The low impurity level

of the synthesized materials results in the lowest signal drift

We found that crystallite growth causes signal decrease by 1%

during 590 h of operation for this material On the other hand,

high impurity concentration in commercial material leads to signal

increase by 25% after 590 h This indicates that, apart from

crys-tallite growth (resulting in signal decrease), impurities take part

in surface oxidation processes causing inhibition of the propane

oxidation and remarkable signal drift

Acknowledgments

This work has been funded in part by CICyT under Grant

no TEC2006-03671 R Pavelko gratefully acknowledges a Ph.D

scholarship from URV Also authors would like to thank Dr F Gispert—Guirado from the Laboratory of X-Ray Diffraction (URV, Spain) for his contribution to XRD experiments and spectra processing

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Biographies

Roman G Pavelko graduated from People’s Friendship University of Russia

(Moscow) in 2003, obtained his PhD in Chemistry in 2007 at the Institute of General and Inorganic Chemistry, (Russian Academy of Science, Moscow) At present he is PhD student in University Rovira i Virgili (Tarragona, Spain) in the Electronic Engi-neering Department His research interests concern synthesis of dispersed materials, material science, experimental and theoretical study of surface processes related to metal oxide gas sensors.

Alexey A Vasiliev graduated from Moscow Institute of Physics and Technology in

1980, obtained his PhD in 1986 for the “Study of the kinetics of low-temperature reactions of atomic fluorine by ESR method” Gained his Dr of Science degree (habil-itation) in solid state microelectronics in 2004 for the investigation of “Physical and chemical principles of design of gas sensors based on metal oxide semiconductors and MIS structures with solid electrolyte layer” Recently he is working in Sensor group of the University Rovira i Virgili (Tarragona, Spain) and at Russian research center Kurchatov Institute (visiting position) Research interests are related with the study of the kinetics and mechanisms of heterogeneous processes related with chemical sensing, kinetics and mechanisms of electrochemical processes in liquid and solid electrolytes.

Eduard Llobet graduated in telecommunication engineering from the Universitat

Politècnica de Catalunya (UPC), (Barcelona, Spain) in 1991, and received his PhD in

1997 from the same university He is currently an associate professor in the Elec-tronic Engineering Department at the Universitat Rovira i Virgili (Tarragona, Spain) His main areas of interest are in the design of semiconductor and carbon nanotube based gas sensors and in the application of intelligent systems to complex odor analysis.

Xavier Vilanova graduated in telecommunication engineering from the

Universi-tat Politècnica de Catalunya (UPC), (Barcelona, Spain) in 1991, received his PhD in

1998 from the same university He is currently an associate professor in the Elec-tronic Engineering Department at the Universitat Rovira i Virgili (Tarragona, Spain) His research activities are related to semiconductor gas sensors development and characterization, as well as, gas sensors systems design.

Noelia Barrabés received MS from Chemical Engineering Department in Rovira i

Virgili University in 2006 She is currently finishing the PhD degree in chemical

Francesc Medina is a professor in the Department of Chemical Engineering at the

University Rovira I Virgili of Tarragona His research interest is in the areas of

mate-rials science, catalysis, reactor design and chemical engineering.

Vladimir G Sevastyanov is graduated from Mendeleyev University of

Chemi-cal Technology of Russia in 1964 He is a professor, head of the Department of

Physical Chemistry of Sensor Materials in the N.S Kurnakov Institute of Gen-eral and Inorganic Chemistry (Moscow, Russia) His research activity is related to synthesis and investigation of volatile coordination compounds of wide range of ele-ments (including actinides), ultra pure chemical compounds, dispersed oxides and carbides.