Shengpan Peng
Chinese Academy of Sciences
16 Papers
28 Citations
Shengpan Peng is an academic researcher from Chinese Academy of Sciences. The author has contributed to research in topics: Catalysis & Chemistry. The author has an hindex of 8, co-authored 10 publications.
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Papers
Rich surface Co(iii) ions-enhanced Co nanocatalyst benzene/toluene oxidation performance derived from Co(II)Co(III) layered double hydroxide.
TL;DR: The design of a hierarchical CoCo layered double hydroxide nanostructure provides a promising approach for the development of nanocatalysts with exposed desirable defects and induced excellent low-temperature reducibility.
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Highly porous fibrous mullite ceramic membrane with interconnected pores for high performance dust removal
TL;DR: In this article, a molding method was used to construct porous fibrous mullite ceramic membranes with different content of fibers for dust removal and the properties of the samples, such as microstructure, porosity, bulk density and mechanical behavior were analyzed.
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Spherical Al2O3-coated mullite fibrous ceramic membrane and its applications to high-efficiency gas filtration
TL;DR: In this paper, the effect of binder composition and sintering temperature on the porosity, phase composition, bulk density and mechanical strength of PCMs, as well as the impact of the coating thickness of spherical alpha-Al2O3 on PMs filtration efficiency and pressure drop were investigated.
34
Efficient removal of low concentration methyl mercaptan by HKUST-1 membrane constructed on porous alumina granules
TL;DR: A metal-organic framework membrane was constructed on porous Al2O3 granules for the first time for the removal of low concentration CH3SH as mentioned in this paper, and the granules exhibited higher sulfur capacity than the pure HKUST-1 powders owing to the excellent dispersion of the MOF membrane on the Al 2O3 substrate.
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Removal of low concentration CH 3 SH with regenerable Cu-doped mesoporous silica
TL;DR: According to XRD, TEM, BET, NMR and EPR, it is deduce that surface groups on CuO nanoparticles and the SiOCu group are highly possibly transformed into a hydrated complex which is much more effective in capturing CH3SH with its empty Cu-3d orbit.
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