D
Din Ping Tsai
Researcher at Hong Kong Polytechnic University
Publications - 572
Citations - 22884
Din Ping Tsai is an academic researcher from Hong Kong Polytechnic University. The author has contributed to research in topics: Metamaterial & Plasmon. The author has an hindex of 65, co-authored 532 publications receiving 18101 citations. Previous affiliations of Din Ping Tsai include University of Toronto & Industrial Technology Research Institute.
Papers
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Journal ArticleDOI
Magnetically controlled planar hyperbolic metamaterials for subwavelength resolution.
TL;DR: This work proposes and analyzes a magnetically controlled InSb-dielectric multi-layered structure with ability of subwavelength resolution at THz region and the mechanism of achieving super resolution is elucidated.
Journal ArticleDOI
Near-field scanning optical microscopy using a super-resolution cover glass slip
Yu-Hsuan Lin,Din Ping Tsai +1 more
TL;DR: In this article, a near-field cover glass slip (NF-CGS) was developed to improve the resolution of optical microscopy beyond the diffraction limit, where a multi-layered structure of cover glass/ZnS-SiO2 (130 nm)/AgOx (15 nm)/ ZnS−SiO 2 (40 nm) was employed to generate the optical coupling effect for increasing the contrast and enhancing resolution of imaging.
Journal ArticleDOI
Real-time vascular imaging and photodynamic therapy efficacy with micelle-nanocarrier delivery of chlorin e6 to the microenvironment of melanoma
Chien-Hsing Lee,Ping-Shan Lai,Yen-Pei Lu,Hsuan-Ying Chen,Chee-Yin Chai,Rong-Kung Tsai,Kang-Tang Fang,Ming-Hsien Tsai,Chia-Yen Hsu,Chun-Cheng Hung,Deng-Chyang Wu,Hsin-Su Yu,Chung-Hsing Chang,Din Ping Tsai,Din Ping Tsai +14 more
TL;DR: Micelle Ce6 can serve as a bifunctional PS for vascular imaging and PDT, which facilitates its delivery in the tumor microenvironment.
Proceedings ArticleDOI
Study of air-driving fluid jet polishing
TL;DR: In this article, an air-driving fluid jet polishing (FJP) system is proposed, which is mainly comprised by an air/water mixer, slurry tank with stirrer, compressed air, pressure and flow rate regulators, and a nozzle.
Journal ArticleDOI
New perspective on the reciprocity theorem of classical electrodynamics
TL;DR: In this paper, a simple physical proof of the reciprocity theorem of classical electrodynamics in the general case of material media that contain linearly polarizable as well as linearly magnetizable substances was provided.