PDF Publication Title:
Text from PDF Page: 070
105. Wang, C., X. Li, X. Xi, P. Xu, Q. Lai, and H. Zhang, Relationship between activity and structure of carbon materials for Br2/Br- in zinc bromine flow batteries. RSC Adv., 2016; 6: 40169-74. 106. Munaiah, Y., S. Dheenadayalan, P. Ragupathy, and V.K. Pillai, High performance carbon nanotube based electrodes for zinc bromine redox flow batteries. J. Solid State Sci. Technol., 2013; 2: M3182-6. 107. Munaiah, Y., S. Suresh, S. Dheenadayalan, V.K. Pillai, and P. Ragupathy, Comparative electrocatalytic performance of single-walled and multiwalled carbon nanotubes for zinc bromine redox flow batteries. J. Phys. Chem. C, 2014; 118: 14795-804. 108. Munaiaha, Y., P. Ragupathy, and V.K. Pillai, Single-step synthesis of halogenated graphene through electrochemical exfoliation and its utilization as electrodes for zinc bromine redox flow battery. J. Electrochem. Soc., 2016; 163: A2899-910. 109. Lai, Q., H. Zhang, X. Li, L. Zhang, and Y. Cheng, A novel single flow zinc–bromine battery with improved energy density. J. Power Sources, 2013; 235: 1-4. 110. Allen, C.J., S. Abraham, and K.L. Hardee. Electrode for electrochemical cells and composition thereof. WO2016097217. 2016. 111. Cho, K.T., P. Albertus, V. Battaglia, A. Kojic, V. Srinivasan, and A.Z. Weber, Optimization and analysis of high-power hydrogen/bromine-flow batteries for grid-scale energy storage. Energy Technol., 2013; 1: 596-608. 112. Bender, D., R. Byrne, and D. Borneo, ARRA energy storage demonstration projects: lessons learned and recommendations. United States of America. Sandia National Laboratories (SNL- NM), Albuquerque, NM (United States), U.S. Department of Energy, Oak Ridge, TN. 2015. 113. Rose, D.M., B.L. Schenkman, and D.R. Borneo, Test report : Raytheon / KTech RK30 energy storage system. United States of America. Sandia National Laboratories (SNL-NM), Albuquerque, NM (United States). 2013. 114. Redflow Limited. Redflow Sustainable Energy Storage. www.redflow.com; 2017 [accessed 29.08.17]. 115. Donghyeon, K. and J. Joonhyeon, Study on durability and stability of an aqueous electrolyte solution for zinc bromide Hybrid flow batteries. J. Phys.: Conf. Ser, 2015; 574: 1-4. 116. Evans, T.I. and R.E. White, A review of mathematical modeling of the zinc/bromine flow cell and battery. J. Electrochem. Soc., 1987; 134: 2725-33. 117. Yang, S.-C., An approximate model for estimating the faradaic efficiency loss in zinc/bromine batteries caused by cell self-discharge. J. Power Sources, 1994; 50: 343-60. 118. Lee, J. and J.R. Selman, Effects of separator and terminal on the current distribution in parallel-plate electrochemical flow reactors. J. Electrochem. Soc., 1982; 129: 1670-8. 119. Jia, Y., S. Cheng, D. Chu, and X. Li. Numerical simulation of bromine crossover behavior in flow battery. In: Advances in Materials, Machinery, Electronics I. 2017. 70PDF Image | hybrid redox flow batteries with zinc negative electrodes
PDF Search Title:
hybrid redox flow batteries with zinc negative electrodesOriginal File Name Searched:
Zn_Negative_RFB_Review_24_Jan_2018.pdfDIY PDF Search: Google It | Yahoo | Bing
Salgenx Redox Flow Battery Technology: Power up your energy storage game with Salgenx Salt Water Battery. With its advanced technology, the flow battery provides reliable, scalable, and sustainable energy storage for utility-scale projects. Upgrade to a Salgenx flow battery today and take control of your energy future.
| CONTACT TEL: 608-238-6001 Email: greg@salgenx.com | RSS | AMP |