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A high performance dual electrolyte microfluidic reactor for the utilization of CO2

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  • Lu, Xu
  • Leung, Dennis Y.C.
  • Wang, Huizhi
  • Xuan, Jin

Abstract

The pH-differential membraneless architecture could enhance the thermodynamic property and raise the electrochemical performance of a dual electrolyte microfluidic reactor (DEMR) for electrochemical conversion of CO2. Freed from hindrances of membrane structure and thermodynamic limitation, DEMR demonstrates the possibility of altering anolyte and catholyte pHs to achieve higher reactivity rates and efficiencies. Different operation condition parameters of a microfluidic network would affect the reactor performance to a certain extents, constraining further improvement. Therefore, we conducted experimental analysis to study the mechanisms and intrinsic correlations of catalyst to Nafion ratio, microchannel thickness, electrolyte flow rate and CO2 supply for an optimized outcome. A comprehensive investigation on the cell durability was also carried out in the way of repetitiveness and long period operation, regarding both reactivity and efficiency. It was found that the catalyst to Nafion ratio affects the performance in a parabolic relation and there exists optimal values of electrolyte flow rate and microfluidic channel thickness for maximized cell performance. The influence of the reactant CO2 supply rate is not significant above a certain level where kinetics limitation is not dominant. The parametric study provides an operational point of view on the dual electrolyte microfluidic reactor and serves as a tool for DEMR optimization design.

Suggested Citation

  • Lu, Xu & Leung, Dennis Y.C. & Wang, Huizhi & Xuan, Jin, 2017. "A high performance dual electrolyte microfluidic reactor for the utilization of CO2," Applied Energy, Elsevier, vol. 194(C), pages 549-559.
    • Handle: RePEc:eee:appene:v:194:y:2017:i:c:p:549-559
    DOI: 10.1016/j.apenergy.2016.05.091
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    References listed on IDEAS

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    1. Prabowo, Bayu & Aziz, Muhammad & Umeki, Kentaro & Susanto, Herri & Yan, Mi & Yoshikawa, Kunio, 2015. "CO2-recycling biomass gasification system for highly efficient and carbon-negative power generation," Applied Energy, Elsevier, vol. 158(C), pages 97-106.
    2. Wang, Huizhi & Leung, Dennis Y.C. & Xuan, Jin, 2013. "Modeling of a microfluidic electrochemical cell for CO2 utilization and fuel production," Applied Energy, Elsevier, vol. 102(C), pages 1057-1062.
    3. Pérez-Fortes, Mar & Schöneberger, Jan C. & Boulamanti, Aikaterini & Tzimas, Evangelos, 2016. "Methanol synthesis using captured CO2 as raw material: Techno-economic and environmental assessment," Applied Energy, Elsevier, vol. 161(C), pages 718-732.
    4. Wang, Yifei & Leung, Dennis Y.C. & Xuan, Jin & Wang, Huizhi, 2015. "A vapor feed methanol microfluidic fuel cell with high fuel and energy efficiency," Applied Energy, Elsevier, vol. 147(C), pages 456-465.
    5. Xu, Hong & Zhang, Hao & Wang, Huizhi & Leung, Dennis Y.C. & Zhang, Li & Cao, Jun & Jiao, Kui & Xuan, Jin, 2015. "Counter-flow formic acid microfluidic fuel cell with high fuel utilization exceeding 90%," Applied Energy, Elsevier, vol. 160(C), pages 930-936.
    6. Middleton, Richard S. & Carey, J. William & Currier, Robert P. & Hyman, Jeffrey D. & Kang, Qinjun & Karra, Satish & Jiménez-Martínez, Joaquín & Porter, Mark L. & Viswanathan, Hari S., 2015. "Shale gas and non-aqueous fracturing fluids: Opportunities and challenges for supercritical CO2," Applied Energy, Elsevier, vol. 147(C), pages 500-509.
    7. Al-Kalbani, Haitham & Xuan, Jin & García, Susana & Wang, Huizhi, 2016. "Comparative energetic assessment of methanol production from CO2: Chemical versus electrochemical process," Applied Energy, Elsevier, vol. 165(C), pages 1-13.
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    1. Edwards, Jonathan P. & Xu, Yi & Gabardo, Christine M. & Dinh, Cao-Thang & Li, Jun & Qi, ZhenBang & Ozden, Adnan & Sargent, Edward H. & Sinton, David, 2020. "Efficient electrocatalytic conversion of carbon dioxide in a low-resistance pressurized alkaline electrolyzer," Applied Energy, Elsevier, vol. 261(C).
    2. Shi, Yu & Li, Yanxiang & Zhang, Liang & Li, Jun & Fu, Qian & Zhu, Xun & Liao, Qiang, 2022. "Development of a membrane-less microfluidic thermally regenerative ammonia-based battery towards small-scale low-grade thermal energy recovery," Applied Energy, Elsevier, vol. 326(C).

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