Xingwen Yu
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Explore the profile of Xingwen Yu including associated specialties, affiliations and a list of published articles.
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Articles
21
Citations
127
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Recent Articles
1.
Fetrow C, Carugati C, Yu X, Zhou X, Wei S
ACS Appl Mater Interfaces
. 2023 Mar;
15(10):12908-12914.
PMID: 36867502
As an emerging energy storage concept, Al-CO batteries have not yet been demonstrated as a rechargeable system that can deliver a high discharge voltage and a high capacity. In this...
2.
Yu X, Yu W, Manthiram A
Small Methods
. 2021 Dec;
5(5):e2001196.
PMID: 34928095
Insertion compounds have been dominating the cathodes in commercial lithium-ion batteries. In contrast to layered oxides and polyanion compounds, the development of spinel-structured cathodes is a little behind. Owing to...
3.
Wang N, Zhang X, Ju Z, Yu X, Wang Y, Du Y, et al.
Nat Commun
. 2021 Jul;
12(1):4519.
PMID: 34312377
Increasing the energy density of lithium-sulfur batteries necessitates the maximization of their areal capacity, calling for thick electrodes with high sulfur loading and content. However, traditional thick electrodes often lead...
4.
Yu X, Liu Y, Goodenough J, Manthiram A
ACS Appl Mater Interfaces
. 2021 Jun;
13(26):30703-30711.
PMID: 34180236
A novel composite electrolyte is rationally designed with a polyethylene glycol diacrylate (PEGDA) polymer and a garnet-type fast lithium-ion conductor (LiLaZrTaO, LLZTO) for solid-state lithium batteries. The LLZTO ceramic phase...
5.
Yu X, Grundish N, Goodenough J, Manthiram A
ACS Appl Mater Interfaces
. 2021 May;
13(21):24662-24669.
PMID: 34008941
An ionic liquid (IL) laden metal-organic framework (MOF) sodium-ion electrolyte has been developed for ambient-temperature quasi-solid-state sodium batteries. The MOF skeleton is designed according to a UIO-66 (Universitetet i Oslo)...
6.
Yu X, Yu W, Manthiram A
ACS Appl Mater Interfaces
. 2020 Oct;
12(43):48654-48661.
PMID: 33064445
Two distinct advantages of nonaqueous redox flow batteries (RFBs) are the feasibility of building a high cell voltage (without a constraint of the water-splitting potential) and the operability at low...
7.
Wei Y, Yu X, Liu C, Ma J, Wei S, Chen T, et al.
J Hazard Mater
. 2019 Mar;
373:97-105.
PMID: 30904817
Although Fe-chitosan adsorbents are attractive for removing arsenite from water, the practical applications of these granular adsorbents are mainly limited by slow adsorption kinetics. In this study, radially porous Fe-chitosan...
8.
Yu X, Wei Y, Liu C, Ma J, Liu H, Wei S, et al.
Chemosphere
. 2019 Feb;
222:258-266.
PMID: 30708160
Bulk adsorbents for fast and deep removal of arsenic in water is highly demanded for practical treatment process, especially fixed-bed column process. In this study, a superior bulk adsorbent of...
9.
Wei Y, Liu H, Liu C, Luo S, Liu Y, Yu X, et al.
Water Res
. 2018 Dec;
150:182-190.
PMID: 30513412
Although oxidation of As(III) to As(V) is deemed necessary to promote arsenic removal, the oxidation process usually involves toxic byproducts, well-defined conditions, energy input or sludge generation. Moreover, extra operations...
10.
Yu X, Manthiram A
Acc Chem Res
. 2017 Nov;
50(11):2653-2660.
PMID: 29112389
Electrode-electrolyte interfacial properties play a vital role in the cycling performance of lithium-sulfur (Li-S) batteries. The issues at an electrode-electrolyte interface include electrochemical and chemical reactions occurring at the interface,...