Tunable VO2 cavity enables multispectral manipulation from visible to microwave frequenciesOA北大核心CSTPCD
Tunable VO2 cavity enables multispectral manipulation from visible to microwave frequencies
Optical materials capable of dynamically manipulating electromagnetic waves are an emerging field in memories,optical modulators,and thermal management.Recently,their multispectral design preliminarily attracts much attention,aiming to enhance their efficiency and integration of functionalities.However,the multispectral manipulation based on these materials is challenging due to their ubiquitous wavelength dependence restricting their capacity to narrow wavelengths.In this article,we cascade multiple tunable optical cavities with selective-transparent layers,enabling a universal approach to overcoming wavelength dependence and establishing a multispectral platform with highly integrated functions.Based on it,we demonstrate the multispectral(ranging from 400 nm to 3 cm),fast response speed(0.9 s),and reversible manipulation based on a typical phase change material,vanadium dioxide.Our platform involves tandem VO2-based Fabry-Pérot(F-P)cavities enabling the customization of optical responses at target bands independently.It can achieve broadband color-changing capacity in the visible region(a shift of~60 nm in resonant wavelength)and is capable of freely switching between three typical optical models(transmittance,reflectance,and absorptance)in the infrared to microwave regions with drastic amplitude tunability exceeding 0.7.This work represents a state-of-art advance in multispectral optics and material science,providing a critical approach for expanding the multispectral manipulation ability of optical systems.
Hang Wei;Jinxin Gu;Tao Zhao;Zhiyuan Yan;He-Xiu Xu;Shuliang Dou;Cheng-Wei Qiu;Yao Li
Center for Composite Materials and Structure,Harbin Institute of Technology,Harbin 150001,China||National University of Singapore,Department of Electrical & Computer Engineering,Singapore 117583,SingaporeSchool of Chemical Engineering and Technology,Harbin Institute of Technology,Harbin 150001,China||Suzhou Laboratory,Suzhou 215123,ChinaCenter for Composite Materials and Structure,Harbin Institute of Technology,Harbin 150001,ChinaNational University of Singapore,Department of Electrical & Computer Engineering,Singapore 117583,SingaporeCenter for Composite Materials and Structure,Harbin Institute of Technology,Harbin 150001,China||Suzhou Laboratory,Suzhou 215123,China
《光:科学与应用(英文版)》 2024 (003)
510-518 / 9
We thank the National Key R&D Program of China(2022YFB3902704),the Fundamental Research Funds for the Central Universities(Grant No.HIT.DZJJ.2023038),the Science Foundation of National Key Laboratory of Science and Technology on Advanced Composites(JCKYS2023603C009),the National Natural Science Foundation of China(52272291).the China Scholarship Council(202206120085).
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