Browsing by Author "Gu, Shuang"
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Item Manipulating Water in High-Performance Hydroxide Exchange Membrane Fuel Cells through Asymmetric Humidification and Wetproofing(The Electrochemical Society, 2015-02-20) Kaspar, Robert B.; Letterio, Michael P.; Wittkopf, Jarrid A.; Gong, Ke; Gu, Shuang; Yan, Yushan; Robert B. Kaspar, Michael P. Letterio, Jarrid A.Wittkopf, Ke Gong, Shuang Gu and Yushan Yan; Kaspar, Robert B.; Letterio, Michael P.; Wittkopf, Jarrid A.; Gong, Ke; Gu, Shuang; Yan, YushanHydroxide exchange membrane fuel cells (HEMFCs) are an emerging low-cost alternative to conventional proton exchange membrane fuel cells. In addition to producing water at the anode, HEMFCs consume water at the cathode, leading to distinctive water transport behavior. We report that gas diffusion layer (GDL) wetproofing strictly lowers cell performance, but that the penalty is much higher when the anode side is wetproofed compared to the cathode side. We attribute this penalty primarily to mass transport losses from anode flooding, suggesting that cathode humidification may be more beneficial than anode humidification for this device. GDLs with little or no wetproofing perform best, yielding a competitive peak power density of 737 mW cm−2.Item Nonaqueous redox-flow batteries: organic solvents, supporting electrolytes, and redox pairs(Royal Society of Chemistry, 2015-08-17) Gong, Ke; Fang, Qianrong; Gu, Shuang; Li, Sam Fong Yau; Yan, Yushan; Ke Gong, Qianrong Fang, Shuang Gu, Sam Fong Yau Li and Yushan Yan; Gong, Ke; Fang, Qianrong; Gu, Shuang; Yan, YushanAs members of the redox-flow battery (RFB) family, nonaqueous RFBs can offer a wide range of working temperature, high cell voltage, and potentially high energy density. These key features make nonaqueous RFBs an important complement of aqueous RFBs, broadening the spectrum of RFB applications. The development of nonaqueous RFBs is still at its early research stage and great challenges remain to be addressed before their successful use for practical applications. As such, it is essential to understand the major components in order to advance the nonaqueous RFB technology. In this perspective, three key major components of nonaqueous RFBs: organic solvents, supporting electrolytes, and redox pairs are selectively focused and discussed, with emphasis on providing an overview of those components and on highlighting the relationship between structure and properties. Urgent challenges are also discussed. To advance nonaqueous RFBs, the understanding of both components and systems is critically needed and it calls for inter-disciplinary collaborations across expertise including electrochemistry, organic chemistry, physical chemistry, cell design, and system engineering. In order to demonstrate the key features of nonaqueous RFBs, herein we also present an example of designing a 4.5 V ultrahigh-voltage nonaqueous RFB by combining a BP/BP˙− redox pair and an OFN˙+/OFN redox pair.Item Permethyl Cobaltocenium (Cp* 2Co+) as an Ultra-Stable Cation for Polymer Hydroxide-Exchange Membranes(Nature Publishing Group, 2015-06-29) Gu, Shuang; Wang, Junhua; Kaspar, Robert B.; Fang, Qianrong; Zhang, Bingzi; Coughlin, E. Bryan; Yan, Yushan; Shuang Gu, Junhua Wang, Robert B. Kaspar, Qianrong Fang, Bingzi Zhang, E. Bryan Coughlin & Yushan Yan; Gu, Shuang; Wang, Junhua; Kspar, Robert B.; Fang, Qianrong; Zhang, Bingzi; Yan, YushanHydroxide (OH−)-exchange membranes (HEMs) are important polymer electrolytes enabling the use of affordable and earth-abundant electrocatalysts for electrochemical energy-conversion devices such as HEM fuel cells, HEM electrolyzers, and HEM solar hydrogen generators. Many HEM cations exist, featuring desirable properties, but new cations are still needed to increase chemical stability at elevated temperatures. Here we introduce the permethyl cobaltocenium [(C5Me5)2Co(III)+ or Cp*2Co+] as an ultra-stable organic cation for polymer HEMs. Compared with the parent cobaltocenium [(C5H5)2Co(III)+ or Cp2Co+], Cp*2Co+ has substantially higher stability and basicity. With polysulfone as an example, we demonstrated the feasibility of covalently linking Cp*2Co+ cation to polymer backbone and prepared Cp*2Co+-functionalized membranes as well. The new cation may be useful in designing more durable HEM electrochemical devices.