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Advancing Versatile Ferroelectric Materials Toward Biomedical Applications
Advanced Science ( IF 14.3 ) Pub Date : 2020-12-03 , DOI: 10.1002/advs.202003074 Wenjun Wang 1 , Jianhua Li 1 , Hong Liu 2 , Shaohua Ge 1
Advanced Science ( IF 14.3 ) Pub Date : 2020-12-03 , DOI: 10.1002/advs.202003074 Wenjun Wang 1 , Jianhua Li 1 , Hong Liu 2 , Shaohua Ge 1
Affiliation
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Ferroelectric materials (FEMs), possessing piezoelectric, pyroelectric, inverse piezoelectric, nonlinear optic, ferroelectric‐photovoltaic, and many other properties, are attracting increasing attention in the field of biomedicine in recent years. Because of their versatile ability of interacting with force, heat, electricity, and light to generate electrical, mechanical, and optical signals, FEMs are demonstrating their unique advantages for biosensing, acoustics tweezer, bioimaging, therapeutics, tissue engineering, as well as stimulating biological functions. This review summarizes the current‐available FEMs and their state‐of‐the‐art fabrication techniques, as well as provides an overview of FEMs‐based applications in the field of biomedicine. Challenges and prospects for future development of FEMs for biomedical applications are also outlined.
中文翻译:
推进多功能铁电材料的生物医学应用
铁电材料(FEM)具有压电、热电、逆压电、非线性光学、铁电光伏等诸多特性,近年来在生物医学领域受到越来越多的关注。由于 FEM 具有与力、热、电和光相互作用产生电、机械和光信号的多功能能力,因此 FEM 正在展示其在生物传感、声学镊子、生物成像、治疗、组织工程以及刺激生物方面的独特优势。功能。本综述总结了当前可用的有限元法及其最先进的制造技术,并概述了基于有限元法在生物医学领域的应用。还概述了生物医学应用有限元法未来发展的挑战和前景。
更新日期:2021-01-07
中文翻译:
推进多功能铁电材料的生物医学应用
铁电材料(FEM)具有压电、热电、逆压电、非线性光学、铁电光伏等诸多特性,近年来在生物医学领域受到越来越多的关注。由于 FEM 具有与力、热、电和光相互作用产生电、机械和光信号的多功能能力,因此 FEM 正在展示其在生物传感、声学镊子、生物成像、治疗、组织工程以及刺激生物方面的独特优势。功能。本综述总结了当前可用的有限元法及其最先进的制造技术,并概述了基于有限元法在生物医学领域的应用。还概述了生物医学应用有限元法未来发展的挑战和前景。
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