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Xing Zhu
Researcher at North Carolina State University
Publications - 7
Citations - 562
Xing Zhu is an academic researcher from North Carolina State University. The author has contributed to research in topics: Chemical looping combustion & Dehydrogenation. The author has an hindex of 6, co-authored 7 publications receiving 271 citations. Previous affiliations of Xing Zhu include Kunming University of Science and Technology.
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Chemical looping beyond combustion – a perspective
TL;DR: In this article, the use of oxygen carriers or redox catalysts for chemical production has been investigated and shown to offer significant opportunities for process intensification and exergy loss minimization.
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Perovskites as Geo-inspired Oxygen Storage Materials for Chemical Looping and Three-Way Catalysis: A Perspective
TL;DR: In this paper, the effects of compositional, structural, and surface properties of perovskites on their oxygen storage and donation properties as well as their interactions with various gaseous reactants are discussed.
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Self-enhanced and efficient removal of arsenic from waste acid using magnetite as an in situ iron donator.
TL;DR: A green process for the self-enhanced and efficient removal of arsenic from waste acid using magnetite as an in situ iron donator using a mutually improved cycle composed of arsenic precipitation and magnetite dissolution on the surface of magnetite particles is reported.
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A tailored multi-functional catalyst for ultra-efficient styrene production under a cyclic redox scheme.
Xing Zhu,Xing Zhu,Yunfei Gao,Xijun Wang,Vasudev Pralhad Haribal,Junchen Liu,Luke Neal,Zhenghong Bao,Zili Wu,Hua Wang,Fanxing Li +10 more
TL;DR: In this paper, a redox-oxidative dehydrogenation scheme and a tailored core-shell redox catalyst were proposed to convert ethylbenzene to styrene with up to 91.4% single-pass yield and 82% energy savings.
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Chemical Looping Co-splitting of H2O–CO2 for Efficient Generation of Syngas
TL;DR: In this article, a thermochemical H2O-CO2 splitting method was proposed for syngas generation via thermochemical HS splitting, which relies heavily on a high-temperature decomposition of metal oxides into a reduced state.