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http://dx.doi.org/10.5573/ieie.2016.53.2.117

pH Sensitive Graphene Field-Effect Transistor(FET)  

Park, Woo Hwan (Kumoh National Institute of Technology)
Song, Kwang Soup (Kumoh National Institute of Technology)
Publication Information
Journal of the Institute of Electronics and Information Engineers / v.53, no.2, 2016 , pp. 117-122 More about this Journal
Abstract
Recently, the detection of pH with real-time and in vivo has been focal pointed in the environmental or medical fields. In this work, we developed the pH sensor using graphene sheet. Graphene has high biocompatibility. We fabricated flexible solution-gated field-effect transistors (SGFETs) on graphene sheet transferred on the polyethylene terephthalate (PET) substrate to detect pH in electrolyte solution. The gate length was $500{\mu}m$ and the gate width was 8 mm. We evaluated the current-voltage (I-V) transfer characteristics of graphene SGFETs in pH solution. The drain-source current ($I_{DS}$) and the gate-source voltage ($V_{GS}$) curves of graphene SGFETs were depended on pH value. The Dirac point of graphene SGFETs linearly shifted to the positive direction about 19.32 mV/pH depending on the pH value in electrolyte solution.
Keywords
Dirac point;
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1 J.M. Alexander, B. Jeff, A.B.D. Colin, and R.L. Christopher, "pH-Sensitive Holographic Sensors," Anal. Chem., Vol. 75, no. 17, pp. 4423-4431, 2003.   DOI
2 K.S. Song, Y. Nakamura, Y. Sasaki, M. Degawa, J.H. Yang, H. Kawarada, "pH-sensitive diamond field-effect transistors (FETs) with directly aminated channel surface," Anal. Chim. Acta., Vol. 573-574, no. 12, pp. 3-8, 2006.   DOI
3 L. Manjakkal, B. Synkiewicz, K. Zaraska, K. Cvejin, J. Kulawik, D. Szwagierczak, "Development and characterization of miniaturized LTCC pH sensors with RuO2 based sensing electrodes," Sens. & Actuat. B, Vol. 223, pp. 641-649, 2016.   DOI
4 N. Uria, N. Abramova, A. Bratov, F. M. Pascual, E. Baldrich, "Miniaturized metal oxide pH sensors for bacteria detection," Talanta, Vol 147, pp. 364-369, 2016.   DOI
5 Y. Qiao, T. Xu, Y. Zhang, C. Zhang, L. Shi, G. Zhang, S. Shuang, C. Dong, "Green synthesis of fluorescent copper nanoclusters for reversible pH-sensors," Sens. & Actuat. B, Vol. 220, pp. 1064-1069, 2015.   DOI
6 J. Ma, C. Ding, J. Zhou, Y. Tian, "2D ratiometric fluorescent pH sensor for tracking of cells proliferation and metabolism," Biosen. & Bioele., Vol 70, pp. 202-208, 2015.   DOI
7 이병훈, 황현준, 장경은, 김윤지, 김소영, 유원범, "그래핀 소자 기술," 대한전자공학회지 제42권, 제7호, 76-87쪽, 2015년 7월
8 K.S. Song "Detection of SNPs using electrical biased method on diamond FETs," IEIE, Vol. 52, 3, pp. 190-195, 2015.
9 I.Y. Sohn, D.J. Kim, J.H. Jung, O.J. Yoon, T.N. Thanh, T.T. Quang, N.E. Lee, "pH sensing characteristics and biosensing application of solution-gated reduced graphene oxide field-effect transistors," Biosen. & Bioele., Vol. 45 pp. 70-76, 2013.   DOI
10 W. Yue, S. Jiang, S. Xu, Y. Ma, C. Bai, "Fabrication of graphene FETs combined with fluorescence and its double read-out system," Sens. & Actuat. B, Vol 214, pp. 204-210, 2015.   DOI
11 S. Bae, H. Kim, Y. Lee, X.F. Xu, J.S. Park, Y. Zheng, B.H. Hong, "Roll-to-roll production of 30-inch graphene films for transparent electrodes," Nat. Nanotech., Vol. 5, no. 8, pp. 574-578, 2010.   DOI
12 H.G. Oh, H.G. Nam, D.H. Kim, M.H. Kim, K.H. Jhee, K.S. Song, "Neuroblastoma cells grown on fluorine or oxygen treated graphenes sheets," Mate. Lett., Vol. 131, pp. 328-331, 2014.   DOI