A new generation gas sensing material based on high-quality graphene

Sensors and Actuators, B: Chemical

Volumn 221, Issue , 2015, Pages 1188-1194

  Karaduman, Irmak ^a   Er, Engin ^b   Çelikkan, Hüseyin ^a   Acar, Selim ^a  

^a GAZI UNIVERSITY   (Turkey)

^b ANKARA UNIVERSITY   (Turkey)

Author keywords

[No Author keywords available]

Indexed keywords

CHEMICAL DETECTION; COST EFFECTIVENESS; FOURIER TRANSFORM INFRARED SPECTROSCOPY; GAS DETECTORS; GASES; HIGH RESOLUTION TRANSMISSION ELECTRON MICROSCOPY; IONIZATION OF GASES; THERMOGRAVIMETRIC ANALYSIS; TRANSMISSION ELECTRON MICROSCOPY;

EFFECTIVE SYNTHESIS; GAS CONCENTRATION; GAS SENSING MATERIAL; GAS SENSING PROPERTIES; MEASUREMENT TEMPERATURES; REDUCTION METHOD; ROOM TEMPERATURE; WATER ELIMINATION;

GRAPHENE;

EID: 84938838605     PISSN: 09254005     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.snb.2015.07.063     Document Type: Article

References (60)

1. S. Ghosh, I. Calizo, D. Teweldebrhan, E.P. Pokatilov, D.L. Nika, A.A. Balandin, W. Bao, F. Miao, and C.N. Lau Extremely high thermal conductivity of graphene: prospects for thermal management applications in nanoelectronic circuits Appl. Phys. Lett. 92 151911 2008 1 3
2. D.Y. Wang, I.S. Wang, I.S. Huang, Y.C. Yeh, S.S. Li, K.H. Tu, C.C. Chen, and C.W. Chen Quantum dot light-emitting diode using solution-processable graphene oxide as the anode interfacial layer J. Phys. Chem. C 116 2012 10181 10185
3. S. Vaziri, G. Lupina, C. Henkel, A.D. Smith, M. Östling, J. Dabrowski, G. Lippert, W. Mehr, and M.C. Lemme A graphene-based hot electron transistor Nano Lett. 13 2013 1435 1439
4. C.M. Lee, J.H. Ahn, K.B. Lee, D.H. Kim, and J.H. Kim Graphene-based flexible NO2 chemical sensors Thin Solid Films 520 2012 5459 5462
5. F. Schedin, A.K. Geim, S.V. Morozov, E.W. Hill, P. Blake, M.I. Katsnelson, and K.S. Novoselov Detection of individual gas molecules adsorbed on graphene Nat. Mater. 6 2007 652 655
6. Y.B. Zhang, Y.W. Tan, H.L. Stormer, and P. Kim Experimental observation of the quantum Hall effect and Berry's phase in graphene Nature 438 2005 201 204
7. K.S. Novoselov, A.K. Geim, S.V. Morozov, D. Jiang, M.I. Katsnelson, I.V. Grigorieva, S.V. Dubonos, and A.A. Firsov Two-dimensional gas of massless Dirac fermions in graphene' Nature 438 2005 197 200
8. V.V. Quang, V.N. Hung, L.A. Tuan, V.N. Phan, Q. Huy, and N.V. Quy Graphene-coated quartz crystal microbalance for detection of volatile organic compounds at room temperature Thin Solid Films 568 2014 6 12
9. R. Ritikos, T.J. Whitcher, N.Md. Razib, D.C.S. Bien, N. Chanlek, H. Nakajima, T. Saisopac, P. Song, N.M. Huang, S.A. Rahman, and S.M. Hafiz A practical carbon dioxide gas sensor using room-temperature hydrogen plasma reduced graphene oxide Sens. Actuators B 193 2014 692 700
10. J. Wang, B. Singh, J.H. Park, S. Rathi, I.Y. Lee, S. Maeng, H.I. Joh, C.H. Lee, and G.H. Kim Dielectrophoresis of graphene oxide nanostructures for hydrogen gas sensor at room temperature Sens. Actuators B 194 2014 296 302
11. Y. Zhou, Y. Jiang, T. Xie, H. Tai, and G. Xie A novel sensing mechanism for resistive gas sensors based on layered reduced graphene oxide thin films at room temperature Sens. Actuators B 203 2014 135 142
12. H. Park, H. Ahn, Y. Chung, S.B. Cho, Y.S. Yoon, and D.J. Kim Transition of gas sensing behavior in non-reduced graphene oxides with thermal annealing Mater. Lett. 136 2014 164 167
13. M. Pumera, A. Ambrosi, A. Bonanni, E.L.K. Chng, and H.L. Poh Graphene for electrochemical sensing and biosensing TrAC Trends Anal. Chem. 29 2010 954 965
14. J. Liu, C.K. Poh, D. Zhan, L.F. Lai, S.H. Lim, L. Wang, X. Liu, N.G. Sahoo, C. Li, Z. Shena, and J. Lin Improved synthesis of graphene flakes from the multiple electrochemical exfoliation of graphite rod Nano Energy 2 2013 377 386
15. L. Staudenmaier, Verfahren zur Darstellung der Graphitsaure, Ber. Dtsch. Chem. Ges. (1898) 31, 1481-1487.
16. O. Jankovsky, S. Hrdlickova Kuckova, M. Pumera, P. Simek, D. Sedmidubsky, and Z. Sofer Carbon fragments are ripped off from graphite oxide sheets during their thermal reduction New J. Chem. 38 2014 5700 5705
17. H.J. Shin, K.K. Kim, A. Benayad, S.M. Yoon, H.K. Park, I.S. Jung, M.H. Jin, H.K. Jeong, J.M. Kim, J.Y. Choi, and Y.H. Lee Efficient reduction of graphite oxide by sodium borohydride and its effect on electrical conductance Adv. Funct. Mater. 19 2009 1987 1992
18. S. Park, J. An, J.R. Potts, A. Velamakanni, S. Murali, and R.S. Ruoff Hydrazine-reduction of graphite- and graphene oxide Carbon 49 2011 3019 3023
19. S. Wakeland, R. Martinez, J.K. Grey, and C.C. Luhrs Production of graphene from graphite oxide using urea as expansion-reduction agent Carbon 48 2010 3463 3470
20. M. Cittadini, M. Bersani, F. Perrozzi, L. Ottaviano, W. Wlodarski, and A. Martucci Graphene oxide couples with gold nanoparticles for localized surface plasmon resonance based gas sensor Carbon 69 2014 452 459
21. Z. Wua, X. Chena, S. Zhub, Z. Zhoub, Y. Yaoa, W. Quana, and B. Liua Enhanced sensitivity of ammonia sensor usinggraphene/polyanilinenanocomposite Sens. Actuators B 178 2013 485 493
22. T. Alizadeh, and L.H. Soltani Graphene/poly(methylmethacrylate) chemiresistor sensor for formaldehyde odor sensing J. Hazard. Mater. 248-249 2013 401 406
23. X. Huang, N. Hu, L. Zhang, L. Wei, H. Wei, and Y. Zhang The NH3 sensing properties of gas sensors based on aniline reduced graphene oxide Synth. Met. 185-186 2013 25 30
24. S. Sena, M. Sharmaa, V. Kumarc, K.P. Muthea, P.V. Satyamb, U.M. Bhattab, M. Royd, N.K. Gaurc, S.K. Gupta, and J.V. Yakhmia Chlorine gas sensors using one-dimensional tellurium nanostructures Talanta 77 2009 1567 1572
25. R. Jaaniso, T. Kahroa, J. Kozlovaa, J. Aarika, L. Aarika, H. Alles, A. Floren, A. Gerst, A. Kasikov, A. Niilisk, and V. Sammelselg Temperature induced inversion of oxygen response in CVD graphene on SiO2 Sens. Actuators B 190 2014 1006 1013
26. M.G. Chung, D.H. Kim, H.M. Lee, T. Kim, J.H. Choi, D.K. Seo, J.B. Yoo, S.H. Hong, T.J. Kang, and Y.H. Kim Highly sensitive NO2 gas sensor based on ozone treated graphene Sens. Actuators B 166-167 2012 172 176
27. W.S. Hummers, and R.E. Offeman Preparation of graphitic oxide J. Am. Chem. Soc. 80 1958 1339
28. E. Er, and H. Çelikkan An efficient way to reduce graphene oxide by water elimination using phosphoric acid RSC Adv. 4 2014 29173 29179
29. K. Satheesh, and R. Jayavel Synthesis and electrochemical properties of reduced graphene oxide via chemical reduction using thiourea as a reducing agent Mater. Lett. 113 2013 5 8
30. S. Some, Y. Kim, Y. Yoon, H. Yoo, S. Lee, Y. Park, and H. Lee High-quality reduced graphene oxide by a dual-function chemical reduction and healing process Scient. Rep. 3 1929 2013 1 5
31. D.T. Phan, and G.S. Chung Effects of oxygen-functional groups on humidity sensor based graphene oxide thin films Sensors 2012 IEEE
32. Y. Li, C. Deng, and M. Yang Facilely prepared composites of polyelectrolytes and graphene as the sensing materials for the detection of very low humidity Sens. Actuators B 194 2014 51 58
33. D. Zhang, J. Tong, and B. Xia Humidity-sensing properties of chemically reduced grapheneoxide/polymer nanocomposite film sensor based on layer-by-layernano self-assembly Sens. Actuators B 197 2014 66 72
34. Y. Yao, X. Chen, J. Zhu, B. Zeng, Z. Wu, and X. Li The effect of ambient humidity on the electrical properties of graphene oxide films Nanoscale Res. Lett. 363 2012 1 7
35. T. Pustelny, M. Setkiewicz, S. Drewniak, E. Maciak, A. Stolarczyk, M. Procek, M. Urbaczyk, K. Gut, Z. Opilski, I. Pasternak, and W. Strupinski The infuence of humidity on the resistance structures with graphene sensor layer Acta Phys. Pol. A 122 5 2012 870 873
36. M. Hjiri, R. Dhahri, K. Omri, L. ElMir, S.G. Leonardi, N. Donato, and G. Neri Effect of indium doping on ZnO based-gas sensor for CO Mater. Sci. Semi. Process. 27 2014 319 325
37. S. Krutovertseva, M. Chuprin, O. Ivanova, A. Pislyakov, A. Shevchenko, V. Konovalov, and V. Kalinovsky Nitric oxide monitoring system based on ZnO sensors for exhaled air Proced. Eng. 5 2010 244 247
38. Y. Zhou, G.Z. Xie, T. Xie, H. Yuan, H.L. Tai, Y.D. Jiang, and Z. Chen A sensitive film structure improvement of reduced graphene oxide based resistive gas sensors Appl. Phys. Lett. 105 2014 033502
39. D. Kim, P. Pikhitsa, H. Yang, and M. Choi Room temperature CO and H2 sensing with carbon nanoparticles Nanotechnology 22 2011 485501
40. A. Omidvar, and A. Mohajeri Edge-functionalized graphene nanoflakes as selective gas sensors Sens. Actuators B 202 2014 622 630
41. S.M. Hafiz, R. Ritikos, T.J. Whitcher, N.Md. Razib, D.C.S. Bien, N. Chanlek, H. Nakajima, T. Saisopac, P. Songsiriritthigul, N.M. Huang, and S.A. Rahman A practical carbon dioxide gas sensor using room-temperature hydrogen plasma reduced graphene oxide Sens. Actuators B 193 2014 692 700
42. A. Ghosh, D.J. Late, L.S. Panchakarla, A. Govindaraj, and C.N.R. Rao NO2 and humidity sensing characteristics of few-layer graphenes J. Exp. Nanosc. 4 4 2009 313 322
43. A.S.M.I. Uddin, and G.S. Chung High performance acetylene sensor based on ZnO/reduced graphene oxide nanocomposite The 9th International Forum on Strategic Technology (IFOST) October 21-23, 2014, Cox's Bazar, Bangladesh 2014
44. Z.B. Aziza, Q. Zhang, and D. Baillargeat Graphene/mica based ammonia gas sensors Appl. Phys. Lett. 105 2014 254102
45. R. Jaanisoa, T. Kahro, J. Kozlova, J. Aarik, L. Aarik, H. Alles, A. Floren, A. Gerst, A. Kasikova, A. Niilisk, and V. Sammelselg Temperature induced inversion of oxygen response in CVD graphene on SiO2 Sens. Actuators B 190 2014 1006 1013
46. P.G. Su, and H.C. Shieh Flexible NO2 sensors fabricated by layer-by-layer covalent anchoring and in situ reduction of graphene oxide Sens. Actuators B 190 2014 865 872
47. A. Esfandiar, A. Irajizad, O. Akhavan, S. Ghasemi, and M.R. Gholami Pd-WO3/reduced graphene oxide hierarchical nanostructures as efficient hydrogen gas sensors Int. J. Hydrogen Energy 39 2014 8169 8179
48. Y. Zhou, Y. Jiang, G. Xie, X. Du, and H. Tai Gas sensors based on multiple-walled carbon nanotubes-polyethylene oxide films for toluene vapor detection Sens. Actuators B 191 2014 24 30
49. Y.G. Du, Q. Xue, Z. Zhang, F. Xia, Great enhancement in H2 response using graphene-based Schottky junction, Mater. Lett. 135 (2014) 151-153.
50. I.S. Kang, H.M. So, G.S. Bang, J.H. Kwak, J.O. Lee, and C.W. Ahn Recovery improvement of graphene-based gas sensors functionalized with nanoscale heterojunctions Appl. Phys. Lett. 101 2012 123504
51. Z. Bo, X. Shuai, S. Mao, H. Yang, J. Qian, J. Chen, J. Yan, and K. Cen Green preparation of reduced graphene oxide for sensing and energy storage applications Scient. Rep. 4 2014 4684
52. Y.M. Liu, C. Punckt, M.A. Pope, A. Gelperin, and I.A. Aksay Electrochemical sensing of nitric oxide with functionalized graphene electrodes Appl. Mater. Interfaces 5 2013 12624 12630
53. K.C. Kemp, H. Seema, M. Saleh, N.H. Le, K. Mahesh, V. Chandra, and K.S. Kim Environmental applications using graphene composites:water remediation and gas adsorption Nanoscale 5 2013 3149 3171
54. M. Mitra, K. Chatterjee, K. Kargupta, S. Ganguly, and D. Banerjee Reduction of graphene oxide through a green and metal-free approach using formic acid Diamond Relat. Mater. 37 2013 74 79
55. F.W. Low, C.W. Lain, and S.B. AbdHamid Easy preparation of ultrathin reduced graphene oxide sheets at a high stirring speed Ceram. Int. 41 2015 5798 5806
56. T.T. Tung, M. Castro, J.F. Feller, T.Y. Kim, and K.S. Suh Hybrid film of chemically modified graphene and vapor-phase-polymerized PEDOT for electronic nose applications Organ. Electron. 14 2013 2789 2794
57. Y. Zhou, G.Z. Xie, T. Xie, H. Yuan, H.L. Tai, Y. Jiang, and Z. Chen A sensitive film structure improvement of reduced graphene oxide based resistive gas sensors Appl. Phys. Lett. 105 2014 033502
58. G. Lu, L.E. Ocola, and J. Chen Reduced graphene oxide for room-temperature gas sensors Nanotechnology 20 2009 445502
59. W. Yuan, and G. Shi Graphene-based gas sensors J. Mater. Chem. A 1 2013 10078
60. H. Mu, Z. Zhang, X. Zhao, F. Liu, K. Wang, and H. Xie High sensitive formaldehyde graphene gas sensor modified by atomic layer deposition zinc oxide films Appl. Phys. Lett. 105 2014 033107