Electrochemically reduced graphene oxide

Mani, V., B. Devadas, and S.-M. Chen, Direct electrochemistry of glucose oxidase at electrochemically reduced graphene oxide-multiwalled carbon nanotubes hybrid material modified electrode for glucose biosensor. Biosensors and Bioelectronics, 2012. 41 p. 309-315. 

Lindfors,T,and Latonen,R-M. (2014). Improved charging/discharging behavior of electropolymerized nanostructured composite films of polyanlllne and electrochemically reduced graphene oxide. Carbon, 69, pp. 122-131. 

Deng S, Lei J, Cheng L, Zhang Y, Ju H (2011) Amplified electrochemiluminescence of quantum dots by electrochemically reduced graphene oxide for nanobiosensing of acetylcholine. Biosens Bioelectron 26(ll) 4552-4558. doi 10.1016/j.bios.2011.05.023... 

Huang D, Lu J, li S, Luo Y, Zhao C, Hu B, Wang M, Shen Y. Fabrication of cobalt porphyrin. Electrochemically reduced graphene oxide hybrid films for electrocatalytic hydrogen evolution in aqueous solution. Langmuir 2014 30 6990-8. 

Hu, X., Dou, W., Fu, L. and Zhao, G. (2013) A disposable immunosensor for Enterobacter sakazakii based on an electrochemically reduced graphene oxide-modified electrode AnflZ. Biochem., 434,218-220. 

Ping, J., Y. Wang, Y. Ying, and J. Wu. 2012. Application of electrochemically reduced graphene oxide on screen-printed ion-selective electrode. Anal. Chem. 84 3473-3479. 

Yin Z, Wu S, Zhou X et al (2010) Electrochemical deposition of ZnO nanorods on transparent reduced graphene oxide electrodes for hybrid solar cells. Small 6 307-312... 

Kim, J., and Kim, S. (2014). Surface-modified reduced graphene oxide electrodes for capacitors by ionic liquids and their electrochemical properties, App/. Surf. Sci., 295, pp. 31-37. 

Zhao, H., Ran, L., Xing, S., Luo, J., and Xu,). (2013). Vanadium oxides-reduced graphene oxide composite for lithium-ion batteries and supercapacitors with improved electrochemical performance,/ Power Sources, 222, pp. 21-31. 

Zhao, Z.-Q., Chen,X.,Yang, Q., Liu,J.-H.,and Huang,X.-J. [2012]. Selective adsorption toward toxic metal ions results in selective response Electrochemical studies on a polypyrrole/reduced graphene oxide nanocomposite, Chem. Commum, 48, pp. 2180-2182. 

Lei, W., Wu, Q., Si, W., Gu, Z., Zhang, Y, Deng, J and Hao, Q. (2013]. Electrochemical determination of imldacloprid using poly(carbazole]/chemically reduced graphene oxide modified glassy carbon electrode. Sens. Actuators B, 183, pp. 102-109. 

N. A. Kumar, H.-J. Choi, Y. R. Shin, D. W. Chang, L. Dai, J.-B. Back, Polyaniline-Grafted Reduced Graphene Oxide for Efficient Electrochemical Supercapacitors. ACS Nano 2012,6,1715-1723. 

Z. Q. Zhao, X. Chen, Q. Yang, J. H. Liu, X. J. Huang, Beyond the selective adsorption of polypyrrole-reduced graphene oxide nanocomposite toward Hg + Ultra-sensitive and -selective sensing Pb by stripping voltammetry. Electrochem Commun 2012,23, 21-24. 

Lithium-ion batteries require novel materials for increasing their cychng stability and power delivering capability. Polypyrrole/reduced graphene oxide nanocomposite is used as cathode in a lithium-ion battery and enhanced electrochemical properties are observed such as high rate capability and improved cycling stability [71 ]. 

Yang, S., Xu, B., Zhang, J., Huang, X., Ye, J., Yu, C. Controllable adsorption of reduced graphene oxide onto self-assembled alkanethiol monolayers on gold electrodes tunable electrode dimension and potential electrochemical applications. J. Phys. Chem. C 114, 4389 393 (2010). doi 10.1021/jp911760b... 

Rajkumar, M., Devadas, B, Chen, S.M., and Yeh, P.C. (2014) Single step electrochemical fabrication of highly loaded palladium nanoparticles decorated chemically reduced graphene oxide and its electrocatalytic applications. Colloids Surf., A, 452, 39 -45. 

X., Shi, J., and Hao, A. (2014) Reduced graphene oxide-carbon dots composite as an enhanced material for electrochemical determination of dopamine. Electrochim. Acta, 130, 805 -809. 

CB, and in particular Vulcan XC-72, is the standard support material in fuel cell research. Therefore, it is hardly surprising that most recent publications do no longer focus on ways to describe, analyze, and optimize the support, but rather report on strategies to, for example, increase the dispersion of the catalytically active metal nanoparticles on the carbon surface by various treatments [43-47]. Apart from that, also the investigation of CB composites, such as CB blended with CNT [48] and CB/reduced graphene oxide [49], came into the focus of recent fuel cell research, as well as its application in the microporous layer (MPL) of the GDLs, which are not subject of this chapter [50, 51]. In addition, the comparison of low-surface-area Vulcan XC-72 with high-surface-area black pearls or Ketjen-black with respect to their electrochemical properties, capacitive behavior [52], and durability [53] has been a frequent subject of recent publications. 

A cobalt 5,10,15-tetrakis(l-methylpyridinio-4-yl)porphyrin/poly(sodium p-styrene sulfonate)/reduced graphene oxide composite (CoTPyP/PSS-RGO), was fabricated using an in situ solvothermal synthesis method [92]. It showed excellent catalytic activity for ORR, attributed by the authors to its large electrochemically accessible surface area, to the excellent electrical conductivity of PS S-RGO, and to the synergistic effect between CoTPyP and PSS-RGO. 

Wang Zhijuan, Wu Shixin, Zhang Juan, et al. Comparative studies on single-layer reduced graphene oxide films obtained by electrochemical reduction and hydrazine vapor reduction. Nanoscale Res. Lett. 1 no. 1 (2012) 161-167. 

Yu Lili, Wu Hui, Wu Beina, et al. Magnetic Fe304—Reduced graphene oxide nano— Composites—Based electrochemical biosensing. Nano-Micro Lett. 6 no. 3 (2014) 258-267. 

Srivastava, S., Kumar, V., Ali, M.A. et al. (2013) Electrophoretically deposited reduced graphene oxide platform for food toxin detection Nanoscale, 5,3043-3051. Paniel, N., Radoi, A. and Marty, J.-L. (2010) Development of an electrochemical biosensor for the detection of aflatoxin Ml in milk Sensors, 10,9439-9448. 

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