Z
Zhaolin Wang
Researcher at University of Ontario Institute of Technology
Publications - 69
Citations - 1631
Zhaolin Wang is an academic researcher from University of Ontario Institute of Technology. The author has contributed to research in topics: Hydrogen production & Copper–chlorine cycle. The author has an hindex of 21, co-authored 59 publications receiving 1416 citations. Previous affiliations of Zhaolin Wang include Xiamen University & University of Saskatchewan.
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Comparison of thermochemical, electrolytic, photoelectrolytic and photochemical solar-to-hydrogen production technologies
TL;DR: In this article, the authors discuss the advantages of using solar energy over other forms of energy to produce hydrogen and examine the latest research and development progress of various solar-to-hydrogen production technologies based on thermal, electrical and photon energy.
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Canada’s program on nuclear hydrogen production and the thermochemical Cu–Cl cycle
Greg F. Naterer,S. Suppiah,L. Stolberg,Michele A. Lewis,Zhaolin Wang,V.N. Daggupati,Kamiel Gabriel,Ibrahim Dincer,Marc A. Rosen,P. Spekkens,Serguei N. Lvov,Michael Fowler,Peter R. Tremaine,Javad Mostaghimi,E.B. Easton,Liliana N. Trevani,Ghaus Rizvi,B.M. Ikeda,M. H. Kaye,Lixuan Lu,Igor Pioro,William R. Smith,E. Secnik,J. Jiang,Jurij Avsec +24 more
TL;DR: An overview of the status of Canada's program on nuclear hydrogen production and the thermochemical copper-chlorine (Cu-Cl) cycle is presented in this article, with particular emphasis on hydrogen production with Canada's Super-Critical Water Reactor, SCWR.
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Thermochemical hydrogen production with a copper-chlorine cycle. I: oxygen release from copper oxychloride decomposition
TL;DR: In this paper, the authors examined the thermal requirements of these steps, in efforts to recover as much heat as possible and minimize the net heat supply to the cycle, thereby improving its overall efficiency.
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Comparison of sulfur–iodine and copper–chlorine thermochemical hydrogen production cycles
TL;DR: In this paper, the authors compared the two cycles from the perspectives of heat quantity, heat grade, thermal efficiency, related engineering challenges, and hydrogen production cost, and found that the copper-chlorine cycle has the advantage of a lower maximum temperature of 803 K compared to the sulfur-iodine cycle.
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Comparison of different copper–chlorine thermochemical cycles for hydrogen production
TL;DR: In this paper, different types of copper-chlorine thermochemical cycles with various numbers of steps are compared and the factors that determine the number and effective grouping of steps were analyzed.