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Journal of Sol-Gel Science and Technology

Erschienen in:

06.08.2020 | Original Paper: Nano- and macroporous materials (aerogels, xerogels, cryogels, etc.)

Cu/SnO₂ xerogels: a novel epoxide derived nanomaterial as formaldehyde gas sensor

verfasst von: Nagesh L. Myadam, Digambar Y. Nadargi, Jyoti D. Nadargi, Manohar G. Chaskar

Erschienen in: Journal of Sol-Gel Science and Technology | Ausgabe 1/2020

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Abstract

Traditionally, sol–gel processing of metal oxides using organometallic precursors is expensive, nonaqueous, and complicated when it comes to two-or-more dissimilar metal oxides. Herein, we report a versatile epoxide-assisted non-organometallic, aqueous, and inexpensive synthesis route of developing Cu/SnO₂ xerogels and their use as efficient formaldehyde (FA) gas sensors. The route utilizes easy to handle salts as precursors (tin and copper chlorides, in the present case) and organic epoxide (propylene oxide) as a gelation agent, which led to highly porous web matrix of Cu/SnO₂. The obtained Cu/SnO₂ xerogels, with 0–2 mol% Cu doping, were analyzed using XRD, Fourier transform infrared, UV–Vis, FE-SEM, TEM/HRTEM, and EDAX. As-developed xerogels showed their versatility in physico-chemical as well as FA gas sensing properties. By proper Cu-doping level in SnO₂ matrix, the reduction in sensor operating temperature (325–275 °C) and enhancement in the gas response (S = 50–96%) are chronicled. The effects of gas sensing are represented by an epoxy-assisted Cu/SnO₂ sol–gel process and the subsequent morphological and structural properties.

Vorheriger Artikel The investigation of hydrogenation behavior of furfural over sol–gel prepared Cu/ZrO2 catalysts

Nächster Artikel In situ synthesis and characterization of sulfonic acid functionalized hierarchical silica monoliths

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Zhang D, Sun L, Gang X, Yan C (2006) Size-controllable one-dimensinal SnO₂ nanocrystals: synthesis, growth mechanism, and gas sensing property. Phys Chem Chem Phys 8:4874–4880

Jimenez I, Arbiol J, Dezanneau G, Cornet A, Morante J (2003) Crystalline structure, defects and gas sensor response to NO2 and H2S of tungsten trioxide nanopowders. Sens Actuators B 93:475–485

Baruwati B, Kumar D, Manorama S (2006) Hydrothermal synthesis of highly crystalline ZnO nanoparticles: a competitive sensor for LPG and EtOH. Sens Actuators B 119:676–682

Koebel M, Nadargi D, Cadena G, Romanyuk Y (2012) Transparent, conducting ATO thin films by epoxide-initiated sol−gel chemistry: a highly versatile route to mixed-metal oxide films. ACS Appl Mater 4:2464–2473

Benad A, Jürries F, Vetter B, Klemmed B, Hübner R, Leyens C, Eychmüller A (2018) Mechanical properties of metal oxide aerogels. Chem Mater 30(1):145–152

Nadargi D, Kelly C, Wehrs J, Philippe L (2014) Epoxide assisted metal oxide replication (EAMOR): a new technique for metal oxide patterning. RSC Adv 4:36494–36497

Gash A, Satcher Jr. J, Simpson R (2003) Strong akaganeite aerogel monoliths using epoxides: synthesis and characterization. Chem Mater 15:3268–3275

Gash A, Tillotson T, Satcher Jr. J, Hrubesh L, Simpson R (2001) New sol–gel synthetic route to transition and main-group metal oxide aerogels using inorganic salt precursors. J Non-Cryst Solids 285:22–28

Bunkoed O, Davis F, Kanatharana P, Thavarungkul P, Higson SPJ (2010) Sol-gel based sensor for selective formaldehyde determination. Anal Chim Acta 659:251–257

10.

Zhang Y, Zhang M, Cai ZQ, Chen MQ, Cheng FL (2012) A novel electrochemical sensor for formaldehyde based on palladium nanowire arrays electrode in alkaline media. Electrochim Acta 68:172–177

11.

Chen T, Liu QJ, Zhou ZL, Wang YD (2008) A high sensitivity gas sensor forformaldehyde based on CdO and In₂O₃doped nanocrystalline SnO₂. Nanotechnology 19:095506

12.

Sun W, Sun GQ, Qin B, Xin Q (2007) A fuel-cell-type sensor for detection of formaldehyde in aqueous solution. Sens Actuator B 128:193–198

13.

Nielsen G, Wolkoff P (2010) Cancer effects of formaldehyde: a proposal for an indoor air guideline value. Arch Toxicol 84:423–446

14.

Lee C, Chiang CM, Wang YH, Ma RH (2007) A self-heating gas sensor with integrated NiO thin-film for formaldehyde detection. Sens Actuator B 122:503–510

15.

Wang X, Ding B, Sun M, Yu JY, Sun G (2010) Nanofibrous polyethylene imine membranes as sensitive coatings for quartz crystal microbalance-based formaldehyde sensors. Sens Actuator B 144:11–17

16.

Ritchie I, Lehnen R (1987) Formaldehyde-related health complaints ofresidents living in mobile and conventional homes. Am J Health 77:323–328

17.

Jiang X, Li C, Chi Y, Yan J (2010) TG-FTIR study on urea-formaldehyde resin residue during pyrolysis and combustion. J Hazard Mater 173:205–210

18.

Xu K, Zeng D, Tian S, Zhang S, Xie C (2014) Hierarchical porous SnO₂ micro-rods topologically transferred from tin oxalate for fast response sensors to trace formaldehyde. Sens Actuators B 190:585–592

19.

Nageswari A, Krishna Reddy K, Mukkanti K (2012) Low-level quantitation of formaldehyde in drug substance by HPLC-UV. Chromatographia 75:275–280

20.

Li Y, Chen N, Deng D, Xing X, Xiao X, Wang Y (2017) Formaldehyde detection: SnO₂ microspheres for formaldehyde gassensor with high sensitivity, fast response/recovery and good selectivity. Sens Actuators B 238:264–273

21.

Korpan Y, Soldatkin O, Sosovska O, Klepach H, Csoregi E, Vocanson F, Jaffrezic-Renault N, Gonchar M (2010) Formaldehyde-sensitive conductometric sensors based on commercial and recombinant formaldehyde dehydrogenase. Microchim Acta 170:337–344

22.

Li N, Fan Y, Shi Y, Xiang Q, Wang X, Xu J (2019) A low temperature formaldehyde gas sensor based on hierarchical SnO/SnO₂ nano-flowers assembled from ultrathin nanosheets: synthesis, sensing performance and mechanism. Sens Actuators B 294:106–115

23.

Du H, Wang J, Su M, Yao P, Zheng Y, Yu N (2012) Formaldehyde gas sensor based on SnO₂/In₂O₃hetero-nanofibers by a modified double jetselectrospinning process. Sens Actuator B 166:746–752

24.

Srinives S, Sarkar T, Mulchandani A (2014) Primary amine-functionalized polyaniline nano thin film sensor for detecting formaldehyde. Sens Actuator B B194:255–259

25.

Berry F, Maddock A (1977) A Tin-119 Mössbauer investigation of the thermal decomposition of Tin (IV) hydroxides. Radiochim Acta 24:32

26.

Giri P, Bhattacharyya S, Singh D, Kesavamoorthy R, Panigrahi B, Nair K (2007) Correlation between microstructure and optical properties of ZnO nanoparticles synthesized by ball milling. J Appl Phys 102:093515

27.

Karthik T, Olvera M, Maldonado A, Pozos H (2016) CO gas sensing properties of pure and Cu-incorporated SnO₂ nanoparticles: a study of Cu-induced modifications. Sensors 16:1283

28.

Fang L, Zu X, Li Z, Zhu S, Liu C, Zhou W (2008) Synthesis and characteristics of Fe3+-doped SnO₂ nanoparticles via sol–gel-calcination or sol–gel-hydrothermal route. J Alloy Compd 454:261–267

29.

Shannon RD (1976) Revised effective ionic radii and systematic studies of interatomie distances in halides and chaleogenides. Acta Cryst A32:751

30.

Niu X, Zhong H, Wang X, Jiang K (2006) Sensing properties of rare earth oxide doped In₂O₃ by a sol–gel method. Sens Actuator B 115:434–438

31.

Mohanapriya P, Segawa H, Watanabe K, Samitsu S, Natarajan TS, VictorJaya N, Ohashi N (2013) Enhanced ethanol-gas sensing performance of Ce-doped SnO₂ hollow nanofibers prepared by electrospinning. Sens Actuators B 188:872–878

32.

Cheng J, Wang B, Zhao M, Liu F, Zhang X (2014) Nickel-doped tin oxidehollow nanofibers prepared by electrospinning for acetone sensing. Sens Actuators B 190:78–85

33.

Wang Z, Liu L (2009) Synthesis and ethanol sensing properties of Fe-doped SnO₂ nanofibers. Mater Lett 63:917–919

34.

Myadam N, Nadargi D, Gurav Nadargi J, Shaikh F, Suryavanshi S, Chaskar M (2020) A facile approach of developing Al/SnO₂ xerogels via epoxide assisted gelation: a highly versatile route for formaldehyde gas sensors. Inorg Chem Commun 116:107901–107909

35.

Xie C, Xiao L, Hu M (2010) Fabrication and formaldehyde gas-sensing property of ZnO–MnO₂ coplanar gas sensor arrays. Sens Actuator B 145:457–463

36.

Nadargi D, Dateer R, Tamboli M, Mulla I, Suryavanshi S (2019) A greener approach towards the development of graphene–Ag loaded ZnO nanocomposites for acetone sensing applications. RSC Adv 9:33602–33606

37.

Wang K, Zhao TY, Lian G, Yu QQ, Luan CH, Wang QL, Cui DL (2013) Room temperature CO sensor fabricated from Pt-loaded SnO₂ porous nanosolid. Sens Actuators B 184:33–39

38.

Zeng W, Liu T, Wang Z, Tsukimoto S, Saito M, Ikuhara Y (2009) Selective detection of formaldehyde gas using a Cd-doped TiO₂-SnO₂ sensor. Sensors 9(11):9029–9038

39.

Tian S, Ding X, Zeng D, Wu J, Zhang S, Xie C (2013) A low temperature gas sensor based on Pd-functionalized mesoporous SnO₂ fibers for detecting trace formaldehyde. RSC Adv 3:11823

40.

Chung F, Wu R, Cheng F (2014) Fabrication of a Au@SnO₂ core–shell structure for gaseous formaldehyde sensing at room temperature. Sens Actuators B 190:1–7

41.

Ren H, Zhao W, Wang L, Ryu SO, Gu C (2015) Preparation of porous flower-like SnO₂ micro/nano structures and their enhanced gas sensing property. J Alloy Compd 653:611–618

42.

Xiang X, Zhu D, Wang D (2016) Enhanced formaldehyde gas sensing properties of La-doped SnO₂ nanoparticles prepared by ball-milling solid chemical reaction method. J Mater Sci Mater Electron 27(7):7425–7432

43.

Yang J, Wang S, Dong R, Zhang L, Zhu Z, Gao X (2016) One-pot synthesis of SnO₂ hollow microspheres and their formaldehyde sensor application. Mater Lett 184:9–12

44.

Chen S, Qiao Y, Huang J, Yao H, Zhang Y, Li Y et al. (2016) One-pot synthesis of mesoporous spherical SnO₂@graphene for high-sensitivity formaldehyde gas sensors. RSC Adv 6:25198–25202

45.

Ma X, Shen J, Hu D et al. (2017) Preparation of three-dimensional Ce-doped Sn₃O₄ hierarchical microsphere and its application on formaldehyde gas sensor. J Alloy Compd 726:1092–1100

46.

Zhou T, Zhang T, Zhang R et al. (2017) Hollow ZnSnO₃ cubes with controllable shells enabling highly efficient chemical sensing detection of formaldehyde vapors. ACS Appl Mater Interfaces 9(16):14525–14533

47.

Wei Q, Song P, Li Z, Yang Z, Wang Q (2017) Hierarchical peony-like Sb-doped SnO₂ nanostructures: synthesis, characterization and HCHO sensing properties. Mater Lett 191:173–177

48.

Gu C, Guan W, Liu X, Gao L, Wang L, Shim J-J, Huang J (2017) Controlled synthesis of porous Ni-doped SnO₂ microstructures and their enhanced gas sensing properties. J Alloy Compd 692:855–864

49.

Wang D, Zhang M, Chen Z, Li H, Chen A, Wang X et al. (2017) Enhanced formaldehyde sensing properties of hollow SnO₂ nanofibers by graphene oxide. Sens Actuators B 250:533–542

50.

Gu C, Cui Y, Wang L, Sheng E, Shim J-J, Huang J (2017) Synthesis of the porous NiO/SnO₂ microspheres and microcubes and their enhanced formaldehyde gas sensing performance. Sens Actuators B 241:298–307

51.

Yu H, Yu H, Li J, Tian Y, Li Z (2018) Environmentally friendly recycling of SnO₂/Sn₃O₄ from tin anode slime for application in formaldehyde sensing material by Ag/Ag₂O modification. J Alloy Compd 765:624–634

52.

Tie Y, Ma S, Yang G et al. (2019) Improved formaldehyde sensor of Zn₂SnO₄/SnO₂ microcubes by compositional evolution and Y₂O₃ decoration. Ceram Int 45(5):5384–5391

53.

Zhu K, Ma S, Tie Y et al. (2019) Highly sensitive formaldehyde gas sensors based on Y-doped SnO₂ hierarchical flower-shaped nanostructures. J Alloy Compd 792:938–944

54.

Wang L, Li Y, Yue W, Gao S, Zhang C, Chen Z (2019) High-performance formaldehyde gas sensor based on Cu-doped Sn₃O₄ hierarchical nanoflowers. IEEE (c) 20:1558–1748

Titel: Cu/SnO2 xerogels: a novel epoxide derived nanomaterial as formaldehyde gas sensor
verfasst von: Nagesh L. Myadam
Digambar Y. Nadargi
Jyoti D. Nadargi
Manohar G. Chaskar
Publikationsdatum: 06.08.2020
Verlag: Springer US
Erschienen in: Journal of Sol-Gel Science and Technology / Ausgabe 1/2020
Print ISSN: 0928-0707
Elektronische ISSN: 1573-4846
DOI: https://doi.org/10.1007/s10971-020-05377-x

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