Your search keyword '"Capuano, Christopher B."' showing total 36 results

1. Amorphous Iridium Oxide-Integrated Anode Electrodes with Ultrahigh Material Utilization for Hydrogen Production at Industrial Current Densities

Author

Ding, Lei, Li, Kui, Wang, Weitian, Xie, Zhiqiang, Yu, Shule, Yu, Haoran, Cullen, David A., Keane, Alex, Ayers, Kathy, Capuano, Christopher B., Liu, Fangyuan, Gao, Pu-Xian, and Zhang, Feng-Yuan

Published

2024

2. Electrochemically Grown Ultrathin Platinum Nanosheet Electrodes with Ultralow Loadings for Energy-Saving and Industrial-Level Hydrogen Evolution

Author

Ding, Lei, Xie, Zhiqiang, Yu, Shule, Wang, Weitian, Terekhov, Alexander Y., Canfield, Brian K., Capuano, Christopher B., Keane, Alex, Ayers, Kathy, Cullen, David A., and Zhang, Feng-Yuan

Published

2023

3. Ionomer-free nanoporous iridium nanosheet electrodes with boosted performance and catalyst utilization for high-efficiency water electrolyzers

Author

Xie, Zhiqiang, Ding, Lei, Yu, Shule, Wang, Weitian, Capuano, Christopher B., Keane, Alex, Ayers, Kathy, Cullen, David A., Meyer, Harry M., III, and Zhang, Feng-Yuan

Published

2024

4. 3D structured liquid/gas diffusion layers with flow enhanced microchannels for proton exchange membrane electrolyzers

Author

Wang, Weitian, Ding, Lei, Xie, Zhiqiang, Yu, Shule, Capuano, Christopher B., Keane, Alex, Ayers, Kathy, and Zhang, Feng-Yuan

Published

2023

5. Insights into the rapid two-phase transport dynamics in different structured porous transport layers of water electrolyzers through high-speed visualization

Author

Wang, Weitian, Yu, Shule, Li, Kui, Ding, Lei, Xie, Zhiqiang, Li, Yifan, Yang, Gaoqiang, Cullen, David A., Yu, Haoran, Kang, Zhenye, Wrubel, Jacob A., Ma, Zhiwen, Bender, Guido, Capuano, Christopher B., Keane, Alex, and Zhang, Feng-Yuan

Published

2021

6. How Low Can You Go? Nanoscale Membranes for Efficient Water Electrolysis

Author

Cohen, Lucas A., primary, Weimer, Matthew S., additional, Yim, Kyungmin, additional, Jin, Jingjing, additional, Fraga Alvarez, Daniela V., additional, Dameron, Arrelaine A., additional, Capuano, Christopher B., additional, Ouimet, Ryan J., additional, Fortiner, Serafina, additional, and Esposito, Daniel V., additional

Published

2024

7. Chemically durable polymer electrolytes for solid-state alkaline water electrolysis

Author

Park, Eun Joo, Capuano, Christopher B., Ayers, Katherine E., and Bae, Chulsung

Published

2018

8. Highly Porous Iridium Thin Electrodes with Low Loading and Improved Reaction Kinetics for Hydrogen Generation in PEM Electrolyzer Cells

Author

Ding, Lei, primary, Wang, Weitian, additional, Xie, Zhiqiang, additional, Li, Kui, additional, Yu, Shule, additional, Capuano, Christopher B., additional, Keane, Alex, additional, Ayers, Kathy, additional, and Zhang, Feng-Yuan, additional

Published

2023

9. Tailoring the Mass Transport to Achieve High-Performing Unitized Regenerative Fuel Cells (Urfcs) Considering Practical Operating Conditions

Author

Wang, Shiyi, primary, Taie, Zachary, additional, Satjaritanun, Pongsarun, additional, Keane, Alex, additional, Capuano, Christopher B., additional, Zenyuk, Iryna V., additional, Danilovic, Nemanja, additional, Weber, Adam Z., additional, and Peng, Xiong, additional

Published

2023

10. Tuning Catalyst Activation and Utilization Via Controlled Electrode Patterning for Low‐Loading and High‐Efficiency Water Electrolyzers

Author

Yu, Shule, primary, Li, Kui, additional, Wang, Weitian, additional, Xie, Zhiqiang, additional, Ding, Lei, additional, Kang, Zhenye, additional, Wrubel, Jacob, additional, Ma, Zhiwen, additional, Bender, Guido, additional, Yu, Haoran, additional, Baxter, Jefferey, additional, Cullen, David A., additional, Keane, Alex, additional, Ayers, Kathy, additional, Capuano, Christopher B., additional, and Zhang, Feng‐Yuan, additional

Published

2022

11. Exploring the Impacts of Conditioning on Proton Exchange Membrane Electrolyzers by In Situ Visualization and Electrochemistry Characterization

Author

Wang, Weitian, primary, Li, Kui, additional, Ding, Lei, additional, Yu, Shule, additional, Xie, Zhiqiang, additional, Cullen, David A., additional, Yu, Haoran, additional, Bender, Guido, additional, Kang, Zhenye, additional, Wrubel, Jacob A., additional, Ma, Zhiwen, additional, Capuano, Christopher B., additional, Keane, Alex, additional, Ayers, Kathy, additional, and Zhang, Feng-Yuan, additional

Published

2022

12. Honeycomb IR Thin Electrodes with Reaction and Transport Enhancement for Highly Efficient Hydrogen Generation in Water Electrolyzer Cells

Author

Ding, Lei, primary, Yu, Shule, additional, Wang, Weitian, additional, Li, Kui, additional, Xie, Zhiqiang, additional, Capuano, Christopher B., additional, Keane, Alex, additional, Ayers, Kathy, additional, and Zhang, Feng-Yuan, additional

Published

2022

13. Honeycomb IR Integrated Thin Electrodes with Reaction and Transport Enhancement for Highly Efficient Hydrogen Generation in Water Electrolyzer Cells

Author

Ding, Lei, primary, Wang, Weitian, additional, Xie, Zhiqiang, additional, Li, Kui, additional, Yu, Shule, additional, Capuano, Christopher B., additional, Keane, Alex, additional, Ayers, Kathy, additional, and Zhang, Feng-Yuan, additional

Published

2022

14. The Effect of Material Properties on Oxygen Evolution Activity and Assessing Half-Cell Screening as a Predictive Tool in Electrolysis

Author

Alia, Shaun M., primary, Manco, Judith, additional, Anderson, Grace C., additional, Hurst, Katherine E., additional, and Capuano, Christopher B., additional

Published

2021

15. Development of Proton Exchange Membrane Water Electrolyzers with Low Catalyst Loadings and Recombination Layers By Reactive Spray Deposition Technology

Author

Ouimet, Ryan J., primary, Yu, Haoran, additional, Mirshekari, Gholamreza, additional, Zeng, Zhiqiao, additional, Bonville, Leonard J., additional, Mani, Prasanna, additional, Niedzwiecki, Allison, additional, Capuano, Christopher B, additional, Ayers, Katherine E., additional, and Maric, Radenka, additional

Published

2020

16. (Invited) Manufacturing Challenges and Opportunities for PEM Electrolysis

Author

Capuano, Christopher B, primary, Ayers, Kathy, additional, Manco, Judith, additional, Wiles, Luke, additional, and Keane, Alex, additional

Published

2020

17. Research and Development Practices within PEM Water Electrolyzer Manufacturing to Support a Circular Economy.

Author

Carmo, Marcelo, Motz, Andrew R, Capuano, Christopher B., Dalton, Luke T., and Ayers, Katherine E.

Published

2024

18. Optimization of Transport Components and Electrode Interfaces for Low Iridium Oxide Loading PEM Electrolysis.

Author

Lang, Jack Todd, Fortiner, Serafina, Ouimet, Ryan J., Kulkarni, Devashish, Glenn, Jennifer, Capuano, Christopher B., Erb, Bryan, Smeltz, Andrew, and Zenyuk, Iryna

Published

2024

19. (Invited) Growing Production Capacity in PEM Electrolysis: Learnings and Technical Accomplishments.

Author

Ayers, Katherine E., Capuano, Christopher B., Carmo, Marcelo, and Dalton, Luke T.

Published

2024

20. (Invited) Challenges and Successes of an Industrial Start-up to Global Electrolyzer Company.

Author

Capuano, Christopher B., Ayers, Katherine E., Dalton, Luke T., Anderson, Everett, and Carmo, Marcelo

Published

2024

21. AEM Electrolysis Testing Update and Industrial Device Requirements

Author

Capuano, Christopher B, primary, Ayers, Kathy, additional, and Keane, Alex, additional

Published

2019

22. A Pathway to Significant Reduction of Hydrogen Crossover with Pt Recombination Layer in Proton Exchange Membrane Water Electrolyzers

Author

Mirshekari, Gholamreza, primary, Ouimet, Ryan J., additional, Yu, Haoran, additional, Zeng, Zhiqiao, additional, Bonville, Leonard J., additional, Mani, Prasanna, additional, Niedzwiecki, Allison, additional, Capuano, Christopher B, additional, Ayers, Katherine E., additional, and Maric, Radenka, additional

Published

2019

23. High Efficiency PEM Water Electrolysis Enabled By Advanced Catalysts, Membranes and Processes

Author

Capuano, Christopher B, primary, Ayers, Kathy, additional, Manco, Judith, additional, Wiles, Luke, additional, Zenyuk, Iryna V., additional, Leonard, Emily, additional, Kusoglu, Ahmet, additional, Weber, Adam Z., additional, Danilovic, Nemanja, additional, Alia, Shaun M, additional, Ulsh, Michael, additional, Mauger, Scott A, additional, Pfeilsticker, Jason, additional, and More, Karren L., additional

Published

2019

24. (Invited) Development of Standards and Best Practices for Materials Testing in Low Temperature Electrolysis

Author

Ayers, Katherine E., primary, Capuano, Christopher B, additional, Motz, Andrew R, additional, and Mani, Prasanna, additional

Published

2019

25. Bifunctional PGM-Free Hydrogen Evolution and Oxidation Electrocatalysts for AEM Electrodes

Author

Serov, Alexey, primary, Lubers, Alia, additional, McKinney, Samuel, additional, McCool, Geoffrey, additional, Romero, Henry, additional, Odgaard, Madeleine, additional, Kendrick, Ian, additional, Pann, Serge, additional, Mukerjee, Sanjeev, additional, Capuano, Christopher B, additional, Ayers, Kathy, additional, and Zulevi, Barr, additional

Published

2019

26. Exploring the Impacts of Conditioning on Proton Exchange Membrane Electrolyzers by In SituVisualization and Electrochemistry Characterization

Author

Wang, Weitian, Li, Kui, Ding, Lei, Yu, Shule, Xie, Zhiqiang, Cullen, David A., Yu, Haoran, Bender, Guido, Kang, Zhenye, Wrubel, Jacob A., Ma, Zhiwen, Capuano, Christopher B., Keane, Alex, Ayers, Kathy, and Zhang, Feng-Yuan

Abstract

For a proton exchange membrane electrolyzer cell (PEMEC), conditioning is an essential process to enhance its performance, reproducibility, and economic efficiency. To get more insights into conditioning, a PEMEC with Ir-coated gas diffusion electrode (IrGDE) was investigated by electrochemistry and in situvisualization characterization techniques. The changes of polarization curves, electrochemical impedance spectra (EIS), and bubble dynamics before and after conditioning are analyzed. The polarization curves show that the cell efficiency increased by 9.15% at 0.4 A/cm2, and the EIS and Tafel slope results indicate that both the ohmic and activation overpotential losses decrease after conditioning. The visualization of bubble formation unveils that the number of bubble sites increased greatly from 14 to 29 per pore after conditioning, at the same voltage of 1.6 V. Under the same current density of 0.2 A/cm2; the average bubble detachment size decreased obviously from 35 to 25 μm. The electrochemistry and visualization characterization results jointly unveiled the increase of reaction sites and the surface oxidation on the IrGDE during conditioning, which provides more insights into the conditioning and benefits for the future GDE design and optimization.

Published

2022

27. Earth-Abundant Oxygen Electrocatalysts for Alkaline Anion-Exchange-Membrane Water Electrolysis: Effects of Catalyst Conductivity and Comparison with Performance in Three-Electrode Cells

Author

Xu, Dongyu, primary, Stevens, Michaela Burke, additional, Cosby, Monty R., additional, Oener, Sebastian Z., additional, Smith, Adam M., additional, Enman, Lisa J., additional, Ayers, Katherine E., additional, Capuano, Christopher B., additional, Renner, Julie N., additional, Danilovic, Nemanja, additional, Li, Yaogang, additional, Wang, Hongzhi, additional, Zhang, Qinghong, additional, and Boettcher, Shannon W., additional

Published

2018

28. High Efficiency Proton Exchange Membrane Electrolysis: Potential for H2@Scale

Author

Ayers, Katherine E., primary, Capuano, Christopher B, additional, and Mani, Prasanna, additional

Published

2018

29. Stable and Active Polymer Electrolyte Membrane Electrolyzers Utilizing Transition Metal Phosphide Hydrogen Evolution Catalysts

Author

King, Laurie Ann, primary, Hubert, McKenzie, additional, Capuano, Christopher B, additional, Manco, Judith, additional, Danilovic, Nemanja, additional, Hellstern, Thomas, additional, and Jaramillo, Thomas F, additional

Published

2018

30. AEM Electrolysis Progress and Impact on the Cost of Hydrogen

Author

Ayers, Katherine E, primary, Capuano, Christopher B, additional, and Wiles, Luke, additional

Published

2017

31. Earth-Abundant Oxygen Electrocatalysts for Alkaline Anion-Exchange-Membrane Water Electrolysis: Effects of Catalyst Conductivity and Comparison with Performance in Three-Electrode Cells.

Author

Xu, Dongyu, Stevens, Michaela Burke, Cosby, Monty R., Oener, Sebastian Z., Smith, Adam M., Enman, Lisa J., Ayers, Katherine E., Capuano, Christopher B., Renner, Julie N., Danilovic, Nemanja, Li, Yaogang, Wang, Hongzhi, Zhang, Qinghong, and Boettcher, Shannon W.

Published

2019

32. Manufacturing Challenges, Opportunities, and Successes for PEM Electrolysis at Scale.

Author

Capuano, Christopher B., Ayers, Katherine E., Fortiner, Serafina, and Ouimet, Ryan

Published

2023

33. Ultralow charge-transfer resistance with ultralow Pt loading for hydrogen evolution and oxidation using Ru@Pt core-shell nanocatalysts

Author

Wang, Jia X., primary, Zhang, Yu, additional, Capuano, Christopher B., additional, and Ayers, Katherine E., additional

Published

2015

34. Calculating the Electrochemically Active Surface Area of Iridium Oxide in Operating Proton Exchange Membrane Electrolyzers

Author

Zhao, Shuai, primary, Yu, Haoran, additional, Maric, Radenka, additional, Danilovic, Nemanja, additional, Capuano, Christopher B., additional, Ayers, Katherine E., additional, and Mustain, William E., additional

Published

2015

35. Characterization of Anion Exchange Membrane Technology for Low Cost Electrolysis

Author

Ayers, Katherine E., primary, Anderson, Everett B., additional, Capuano, Christopher B., additional, Niedzwiecki, Michael, additional, Hickner, Michael A., additional, Wang, Chao-Yang, additional, Leng, Yongjun, additional, and Zhao, Wei, additional

Published

2013

36. Calculating the Electrochemically Active Surface Area of Iridium Oxide in Operating Proton Exchange Membrane Electrolyzers.

Author

Shuai Zhao, Haoran Yu, Marie, Radenka, Danilovic, Nemanja, Capuano, Christopher B., Ayers, Katherine E., and Mustain, William E.

Subjects

IRIDIUM oxide, PROTON exchange membrane fuel cells, ELECTROLYTIC cells, OXYGEN evolution reactions, ELECTROCATALYSTS

Abstract

Iridium oxide is one of the most common anode catalysts in commercial proton exchange membrane (PEM) electrolyzers because of its strong mix of high activity and stability under oxygen evolution reaction (OER) conditions. Unfortunately, benchmarking iridium oxide OER catalysts has proven difficult since IrO2 cannot undergo proton underpotential deposition like platinum and other transition metal eletrocatalysts, making it difficult to estimate the electrochemically active surface area (ECSA), as well as OER specific and mass activity. In this work, we propose a method to calculate the ECSA of iridium oxide in an operating PEM electrolyzer. A universal constant, 596 (±21) µC/cm², was obtained from the correlation of pseudocapacitive charge and ECSA of iridium oxide. In the membrane electrode assembly (MEA), the calculated ECSA (1.81 (±0.065) m² over a 25-cm² geometric area) showed an iridium oxide catalyst utilization of ~93%. Additionally, the IrO2 OER specific and mass activities at 80°C, 1.6 V in an operating PEM electrolyzer were 0.401 (±0.014) mA/cm² and 132 mA/mg, respectively. [ABSTRACT FROM AUTHOR]

Published

2015