Exceptionally High Ionic Conductivity in Na3P0.62As0.38S4 with Improved Moisture Stability for Solid-State Sodium-Ion Batteries

Zhaoxin Yu; Shun Li Shang; Joo Hwan Seo; Daiwei Wang; Xiangyi Luo; Qingquan Huang; Shuru Chen; Jun Lu; Xiaolin Li; Zi Kui Liu; Donghai Wang

doi:10.1002/adma.201605561

Exceptionally High Ionic Conductivity in Na₃P_0.62As_0.38S₄ with Improved Moisture Stability for Solid-State Sodium-Ion Batteries

Zhaoxin Yu, Shun Li Shang, Joo Hwan Seo, Daiwei Wang, Xiangyi Luo, Qingquan Huang, Shuru Chen, Jun Lu, Xiaolin Li, Zi Kui Liu^*, Donghai Wang

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

178 Citations (Scopus)

Abstract

Researchers develop and test an nitric oxide (NO) delivery platform that directly targets the conventional outflow pathway and locally liberates a controlled dose of NO via enzyme biocatalysis. Enzymes are embedded at the desired sites and serve as biological machinery that can locally convert externally administered NO donors into active therapeutics. To enmesh enzymes deep within the TM, which is the principal resistance-generating region, the researchers encapsulate β-galactosidase in polymer carriers. They fabricate polymer carrier capsules via layer-by-layer adsorption of interacting polymers onto sacrificial particle templates, a versatile technique that allows incorporation of an extensive choice of materials within the multilayer structures and gives fine control over the diffusion of molecules across the shell of the polymer capsules.

Original language	English
Article number	1605561
Journal	Advanced Materials
Volume	29
Issue number	16
DOIs	https://doi.org/10.1002/adma.201605561
Publication status	Published - 25 Apr 2017
Externally published	Yes

Keywords

all-solid-state battery
first-principles calculations
sodium-ion conductor
solid-state electrolyte
sulfide

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10.1002/adma.201605561

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title = "Exceptionally High Ionic Conductivity in Na3P0.62As0.38S4 with Improved Moisture Stability for Solid-State Sodium-Ion Batteries",

abstract = "Researchers develop and test an nitric oxide (NO) delivery platform that directly targets the conventional outflow pathway and locally liberates a controlled dose of NO via enzyme biocatalysis. Enzymes are embedded at the desired sites and serve as biological machinery that can locally convert externally administered NO donors into active therapeutics. To enmesh enzymes deep within the TM, which is the principal resistance-generating region, the researchers encapsulate β-galactosidase in polymer carriers. They fabricate polymer carrier capsules via layer-by-layer adsorption of interacting polymers onto sacrificial particle templates, a versatile technique that allows incorporation of an extensive choice of materials within the multilayer structures and gives fine control over the diffusion of molecules across the shell of the polymer capsules.",

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AU - Yu, Zhaoxin

AU - Shang, Shun Li

AU - Seo, Joo Hwan

AU - Wang, Daiwei

AU - Luo, Xiangyi

AU - Huang, Qingquan

AU - Chen, Shuru

AU - Lu, Jun

AU - Li, Xiaolin

AU - Liu, Zi Kui

AU - Wang, Donghai

PY - 2017/4/25

Y1 - 2017/4/25

N2 - Researchers develop and test an nitric oxide (NO) delivery platform that directly targets the conventional outflow pathway and locally liberates a controlled dose of NO via enzyme biocatalysis. Enzymes are embedded at the desired sites and serve as biological machinery that can locally convert externally administered NO donors into active therapeutics. To enmesh enzymes deep within the TM, which is the principal resistance-generating region, the researchers encapsulate β-galactosidase in polymer carriers. They fabricate polymer carrier capsules via layer-by-layer adsorption of interacting polymers onto sacrificial particle templates, a versatile technique that allows incorporation of an extensive choice of materials within the multilayer structures and gives fine control over the diffusion of molecules across the shell of the polymer capsules.

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KW - first-principles calculations

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KW - solid-state electrolyte

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Exceptionally High Ionic Conductivity in Na₃P_0.62As_0.38S₄ with Improved Moisture Stability for Solid-State Sodium-Ion Batteries

Abstract

Keywords

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