Ethan C Self
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Explore the profile of Ethan C Self including associated specialties, affiliations and a list of published articles.
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13
Citations
22
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Recent Articles
1.
Lehmann M, Self E, Saito T, Yang G
Membranes (Basel)
. 2023 Aug;
13(8).
PMID: 37623761
Non-aqueous redox flow batteries (NARFBs) using earth-abundant materials, such as sodium and sulfur, are promising long-duration energy storage technologies. NARFBs utilize organic solvents, which enable higher operating voltages and potentially...
2.
Patil S, Koirala K, Crafton M, Yang G, Tsai W, McCloskey B, et al.
ACS Appl Mater Interfaces
. 2023 Aug;
15(33):39253-39264.
PMID: 37565767
Cobalt-free cation-disordered rocksalt (DRX) cathodes are a promising class of materials for next-generation Li-ion batteries. Although they have high theoretical specific capacities (>300 mA h/g) and moderate operating voltages (∼3.5...
3.
Self E, Chien P, ODonnell L, Morales D, Liu J, Brahmbhatt T, et al.
Mater Today Phys
. 2022 Apr;
21.
PMID: 35425888
Solid-state Li batteries require solid electrolytes which have high Li conductivity and good chemical/mechanical compatibility with Li metal anodes and high energy cathodes. Structure/function correlations which relate local bonding to...
4.
Feng X, Fang H, Liu P, Wu N, Self E, Yin L, et al.
Angew Chem Int Ed Engl
. 2021 Sep;
60(50):26158-26166.
PMID: 34569135
A strategy for modifying the structure of solid-state electrolytes (SSEs) to reduce the cation diffusion activation energy is presented. Two heavily W-doped sodium thioantimonate SSEs, Na W Sb S and...
5.
Zhang Y, Self E, Thapaliya B, Giovine R, Meyer H, Li L, et al.
ACS Appl Mater Interfaces
. 2021 Aug;
13(32):38221-38228.
PMID: 34347420
Disordered rocksalt (DRX) cathodes have attracted interest due to their high capacity and compositional flexibility (e.g., Co-free chemistries). However, the sloping voltage profile and gradual capacity fade during cycling have...
6.
Burdette-Trofimov M, Armstrong B, Nelson Weker J, Rogers A, Yang G, Self E, et al.
ACS Appl Mater Interfaces
. 2020 Dec;
12(50):55954-55970.
PMID: 33263996
In this work, the spatial (in)homogeneity of aqueous processed silicon electrodes using standard poly(acrylic acid)-based binders and slurry preparation conditions is demonstrated. X-ray nanotomography shows segregation of materials into submicron-thick...
7.
Tao R, Yang G, Self E, Liang J, Dunlap J, Men S, et al.
Small
. 2020 Jun;
16(29):e2001884.
PMID: 32567130
Nanoporous TiNb O (NPTNO) material is synthesized by a sol-gel method with an ionic liquid (IL) as the nanoporous structure directing template. NPTNO exhibits a high reversible capacity of 210...
8.
Thapaliya B, Self E, Jafta C, Borisevich A, Meyer 3rd H, Bridges C, et al.
ChemSusChem
. 2020 May;
13(15):3825-3834.
PMID: 32460419
High-capacity metal oxide conversion anodes for lithium-ion batteries (LIBs) are primarily limited by their poor reversibility and cycling stability. In this study, a promising approach has been developed to improve...
9.
Li L, Self E, Darbar D, Zou L, Bhattacharya I, Wang D, et al.
Nano Lett
. 2020 Mar;
20(4):2756-2762.
PMID: 32119550
Structural transformations near surfaces of solid-state materials underpin functional mechanisms of a broad range of applications including catalysis, memory, and energy storage. It has been a long-standing notion that the...
10.
Perras F, Hwang S, Wang Y, Self E, Liu P, Biswas R, et al.
Nano Lett
. 2019 Dec;
20(2):918-928.
PMID: 31815484
We combined advanced TEM (HRTEM, HAADF, EELS) with solid-state (SS)MAS NMR and electroanalytical techniques (GITT, etc.) to understand the site-specific sodiation of selenium (Se) encapsulated in a nanoporous carbon host....