Tailored Design of a Nanoporous Structure Suitable for Thick Si Electrodes on a Stiff Oxide-Based Solid Electrolyte.

IF 5.4 2区医学 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Biomaterials Science & Engineering Pub Date : 2024-11-13 Epub Date: 2024-10-29 DOI:10.1021/acsami.4c15894

Kohei Marumoto, Kiyotaka Nakano, Yuki Kondo, Minoru Inaba, Takayuki Doi

{"title":"Tailored Design of a Nanoporous Structure Suitable for Thick Si Electrodes on a Stiff Oxide-Based Solid Electrolyte.","authors":"Kohei Marumoto, Kiyotaka Nakano, Yuki Kondo, Minoru Inaba, Takayuki Doi","doi":"10.1021/acsami.4c15894","DOIUrl":null,"url":null,"abstract":"Oxide-based all-solid-state batteries are ideal next-generation batteries that combine high energy density and high safety, but their realization requires the development of interface bonding technology between the stiff solid electrolyte and electrode. Even if the interface could be bonded, it is difficult to hold the interface, because only the electrode expands/contracts unilaterally during charge/discharge reactions. In particular, silicon (Si), which has eagerly awaited as a next-generation negative-electrode material for many years, changes in volume by several hundred percent. To solve these problems, in this work, highly porous silicon oxide (SiOx) electrodes with different porous structures were fabricated on a stiff garnet-type Li7La3Zr2O12 solid electrolyte, the three-dimensional nanoporous structure was analyzed quantitatively, and the charge/discharge characteristics were investigated. The microscopic observation and electrochemical analysis revealed how we should control the porous structure, such as sizes of pores and SiOx, size distribution, and porosity, for repeated and stable charge/discharge cycles. In addition, the resultant porous SiOx electrodes demonstrated superior charge/discharge cycle performance even when it thickened to 5 μm, whereas non-porous SiOx easily peeled off from the solid electrolyte when its thickness exceeded 0.1 μm. The thick SiOx films greatly improved the energy density per unit area (mAh cm-2). Nanosized fine pores with an interconnected open-pore architecture effectively mitigated the internal and interfacial stress upon expansion (charge)/contraction (discharge) of Si, and as a result, the thick and porous SiOx electrode maintained the interfacial joint with the stiff solid electrolyte after repeated charge/discharge cycles. These results will provide useful insights for effectively designing more practical porous SiOx powder effectively.","PeriodicalId":8,"journal":{"name":"ACS Biomaterials Science & Engineering","volume":null,"pages":null},"PeriodicalIF":5.4000,"publicationDate":"2024-11-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"ACS Biomaterials Science & Engineering","FirstCategoryId":"88","ListUrlMain":"https://doi.org/10.1021/acsami.4c15894","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"2024/10/29 0:00:00","PubModel":"Epub","JCR":"Q2","JCRName":"MATERIALS SCIENCE, BIOMATERIALS","Score":null,"Total":0}

引用次数: 0

Abstract

Oxide-based all-solid-state batteries are ideal next-generation batteries that combine high energy density and high safety, but their realization requires the development of interface bonding technology between the stiff solid electrolyte and electrode. Even if the interface could be bonded, it is difficult to hold the interface, because only the electrode expands/contracts unilaterally during charge/discharge reactions. In particular, silicon (Si), which has eagerly awaited as a next-generation negative-electrode material for many years, changes in volume by several hundred percent. To solve these problems, in this work, highly porous silicon oxide (SiO_x) electrodes with different porous structures were fabricated on a stiff garnet-type Li₇La₃Zr₂O₁₂ solid electrolyte, the three-dimensional nanoporous structure was analyzed quantitatively, and the charge/discharge characteristics were investigated. The microscopic observation and electrochemical analysis revealed how we should control the porous structure, such as sizes of pores and SiO_x, size distribution, and porosity, for repeated and stable charge/discharge cycles. In addition, the resultant porous SiO_x electrodes demonstrated superior charge/discharge cycle performance even when it thickened to 5 μm, whereas non-porous SiO_x easily peeled off from the solid electrolyte when its thickness exceeded 0.1 μm. The thick SiO_x films greatly improved the energy density per unit area (mAh cm^-2). Nanosized fine pores with an interconnected open-pore architecture effectively mitigated the internal and interfacial stress upon expansion (charge)/contraction (discharge) of Si, and as a result, the thick and porous SiO_x electrode maintained the interfacial joint with the stiff solid electrolyte after repeated charge/discharge cycles. These results will provide useful insights for effectively designing more practical porous SiO_x powder effectively.

Abstract Image

查看原文

微信好友朋友圈 QQ好友复制链接

本刊更多论文

在硬质氧化物固体电解质上量身设计适合厚硅电极的纳米多孔结构。

基于氧化物的全固态电池是兼具高能量密度和高安全性的理想下一代电池，但要实现这一点，需要开发刚性固体电解质与电极之间的界面粘合技术。即使可以粘合界面，也很难固定界面，因为在充放电反应过程中，只有电极会单边膨胀/收缩。特别是硅 (Si)，多年来人们一直热切期待它成为下一代负电极材料，但它的体积却会发生几百分之一的变化。为了解决这些问题，本研究在硬质石榴石型 Li7La3Zr2O12 固体电解质上制备了具有不同多孔结构的高多孔氧化硅（SiOx）电极，对其三维纳米多孔结构进行了定量分析，并研究了其充放电特性。显微观察和电化学分析揭示了我们应如何控制多孔结构，如孔隙和 SiOx 的大小、尺寸分布和孔隙率，以实现反复稳定的充放电循环。此外，所制备的多孔氧化硅电极即使增厚到 5 μm 也能表现出卓越的充放电循环性能，而无孔氧化硅在厚度超过 0.1 μm 时很容易从固体电解质中剥离。厚的氧化硅薄膜大大提高了单位面积的能量密度（mAh cm-2）。具有相互连接的开孔结构的纳米级细孔有效地减轻了硅在膨胀（充电）/收缩（放电）时的内应力和界面应力，因此，厚而多孔的氧化硅电极在反复充电/放电循环后仍能与坚硬的固体电解质保持界面连接。这些结果将为有效设计更实用的多孔氧化硅粉末提供有益的启示。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文去求助

来源期刊

ACS Biomaterials Science & Engineering Materials Science-Biomaterials

CiteScore

10.30

自引率

3.40%

发文量

413

期刊介绍： ACS Biomaterials Science & Engineering is the leading journal in the field of biomaterials, serving as an international forum for publishing cutting-edge research and innovative ideas on a broad range of topics: Applications and Health – implantable tissues and devices, prosthesis, health risks, toxicology Bio-interactions and Bio-compatibility – material-biology interactions, chemical/morphological/structural communication, mechanobiology, signaling and biological responses, immuno-engineering, calcification, coatings, corrosion and degradation of biomaterials and devices, biophysical regulation of cell functions Characterization, Synthesis, and Modification – new biomaterials, bioinspired and biomimetic approaches to biomaterials, exploiting structural hierarchy and architectural control, combinatorial strategies for biomaterials discovery, genetic biomaterials design, synthetic biology, new composite systems, bionics, polymer synthesis Controlled Release and Delivery Systems – biomaterial-based drug and gene delivery, bio-responsive delivery of regulatory molecules, pharmaceutical engineering Healthcare Advances – clinical translation, regulatory issues, patient safety, emerging trends Imaging and Diagnostics – imaging agents and probes, theranostics, biosensors, monitoring Manufacturing and Technology – 3D printing, inks, organ-on-a-chip, bioreactor/perfusion systems, microdevices, BioMEMS, optics and electronics interfaces with biomaterials, systems integration Modeling and Informatics Tools – scaling methods to guide biomaterial design, predictive algorithms for structure-function, biomechanics, integrating bioinformatics with biomaterials discovery, metabolomics in the context of biomaterials Tissue Engineering and Regenerative Medicine – basic and applied studies, cell therapies, scaffolds, vascularization, bioartificial organs, transplantation and functionality, cellular agriculture