2023
DOI: 10.1002/cey2.374
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High‐efficiency sodium storage of Co0.85Se/WSe2 encapsulated in N‐doped carbon polyhedron via vacancy and heterojunction engineering

Abstract: With the advantage of fast charge transfer, heterojunction engineering is identified as a viable method to reinforce the anodes' sodium storage performance. Also, vacancies can effectively strengthen the Na+ adsorption ability and provide extra active sites for Na+ adsorption. However, their synchronous engineering is rarely reported. Herein, a hybrid of Co0.85Se/WSe2 heterostructure with Se vacancies and N‐doped carbon polyhedron (CoWSe/NCP) has been fabricated for the first time via a hydrothermal and subseq… Show more

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Cited by 39 publications
(7 citation statements)
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“…2b), the peaks located at 162.8, 161.2 eV and 160.7 eV correspond to S 2p 1/2 , S 2p 3/2 and the Ti-S bond, confirming the formation of chemical bonding between SnS 2 and the Ti 3 C 2 T x substrate. Compared with the previously reported binding energy peak of S, 23,32,33 the peaks of S 2p 1/2 , S 2p 3/2 and Ti-S for SnS 2 @Ti 3 C 2 T x move towards the low binding energy region, indicating that binding with Ti 3 C 2 T x increases the electron density of S. The change of binding energy indicates that electron transfer occurs in SnS 2 @Ti 3 C 2 T x , which is due to the strong interaction between SnS 2 and Ti 3 C 2 T x at the heterointerface, leading to electron redistribution and thus regulating the electron structure. Moreover, since Sn is a mixed valence state of Sn 4+ and Sn 2+ , according to the charge compensation mechanism, there are S vacancies in the SnS 2 @Ti 3 C 2 T x heterostructure.…”
Section: Resultsmentioning
confidence: 77%
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“…2b), the peaks located at 162.8, 161.2 eV and 160.7 eV correspond to S 2p 1/2 , S 2p 3/2 and the Ti-S bond, confirming the formation of chemical bonding between SnS 2 and the Ti 3 C 2 T x substrate. Compared with the previously reported binding energy peak of S, 23,32,33 the peaks of S 2p 1/2 , S 2p 3/2 and Ti-S for SnS 2 @Ti 3 C 2 T x move towards the low binding energy region, indicating that binding with Ti 3 C 2 T x increases the electron density of S. The change of binding energy indicates that electron transfer occurs in SnS 2 @Ti 3 C 2 T x , which is due to the strong interaction between SnS 2 and Ti 3 C 2 T x at the heterointerface, leading to electron redistribution and thus regulating the electron structure. Moreover, since Sn is a mixed valence state of Sn 4+ and Sn 2+ , according to the charge compensation mechanism, there are S vacancies in the SnS 2 @Ti 3 C 2 T x heterostructure.…”
Section: Resultsmentioning
confidence: 77%
“…This shift is attributed to strain and lattice distortions in the crystal caused by the formation of S vacancies. 23,28 When compared to pure Ti 3 C 2 T x (Fig. S1a, ESI†), the (002) diffraction peak of SnS 2 @Ti 3 C 2 T x shifts from 7.9° to 7.8°, indicating the successful modification of SnS 2 onto Ti 3 C 2 T x and expansion of the interlayer spacing within Ti 3 C 2 T x .…”
Section: Resultsmentioning
confidence: 99%
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“…With the increasing energy source demands and the rapid reduction of fossil fuels, the development of renewable and clean energy techniques is especially needed. Large-scale electrical energy storage systems (EESs) with safety, low-cost, long-life, and environmentally friendly features are essential to satisfy the sustainable development demands of modern society. Although lithium-ion batteries (LIBs) have been commercially applied in electronic products and daily lives in the past decades, the high cost and limited source of lithium still cause a large barrier to extending their application in EESs. In this regard, sodium-ion batteries (SIBs) have received great attention as a potential alternative to LIBs based on the abundance of Na resources and its similar storage mechanism to LIBs. …”
Section: Introductionmentioning
confidence: 99%
“…This phenomenon might lead to an increase in the number of active sites, so promoting the Fenton-like reaction and ultimately facilitating faster reaction kinetics. [37] The nanocatalyst exhibits glutathione peroxidase-like activity, enabling the consumption of excess glutathione and disrupting the redox balance in tumor cells, consequently inducing apoptosis. Co 3 + ions present in the nanoparticles can utilize a portion of the internal H 2 O 2 to generate O 2 , thus alleviating tumor hypoxia.…”
Section: Introductionmentioning
confidence: 99%