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Deyang Ji
Researcher at Tianjin University
Publications - 26
Citations - 418
Deyang Ji is an academic researcher from Tianjin University. The author has contributed to research in topics: Organic semiconductor & Semiconductor. The author has an hindex of 7, co-authored 25 publications receiving 135 citations. Previous affiliations of Deyang Ji include University of Münster.
Papers
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Journal ArticleDOI
Photochemical Phase Transitions Enable Coharvesting of Photon Energy and Ambient Heat for Energetic Molecular Solar Thermal Batteries That Upgrade Thermal Energy.
Zhao-Yang Zhang,Yixin He,Zhihang Wang,Jiale Xu,Mingchen Xie,Peng Tao,Deyang Ji,Kasper Moth-Poulsen,Tao Li +8 more
TL;DR: Photochemical phase transitions-a photochemistry-thermophysics coupled regime-for co-harvesting of solar and thermal energy is explored, showing that photon energy and ambient heat can be stored together and released on demand as high-tem temperature heat, enabled by room-temperature photochemical crystal↔liquid transitions of engineered molecular photoswitches.
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Recent Progress in Organic Phototransistors: Semiconductor Materials, Device Structures and Optoelectronic Applications
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Self-assembled fullerene (C60)-pentacene superstructures for photodetectors
Qin Tang,Qin Tang,Guangpu Zhang,Bohong Jiang,Deyang Ji,Huihui Kong,Kristina Riehemann,Qingmin Ji,Harald Fuchs,Harald Fuchs +9 more
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Breathing-effect assisted transferring large-area PEDOT:PSS to PDMS substrate with robust adhesion for stable flexible pressure sensor
Ziting Tan,Hongwei Li,Yinan Huang,Xue Gong,Jiannan Qi,Jie Li,Xiaosong Chen,Deyang Ji,Weibang Lv,Liqiang Li,Liqiang Li,Liqiang Li,Wenping Hu,Wenping Hu +13 more
TL;DR: In this paper, an original breathing-effect assisted transfer (BEAT) strategy was developed to solve the problem of weak interface adhesion, which can cause the conductive polymer film to slip even peel off under external stimulation, which significantly deteriorates the stability of the device.
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Effectively modulating thermal activated charge transport in organic semiconductors by precise potential barrier engineering.
Yinan Huang,Xue Gong,Xue Gong,Yancheng Meng,Yancheng Meng,Zhongwu Wang,Xiaosong Chen,Jie Li,Deyang Ji,Zhongming Wei,Liqiang Li,Liqiang Li,Wenping Hu,Wenping Hu +13 more
TL;DR: In this article, a potential barrier engineering strategy for modulating thermally-activated charge transport in organic semiconductors has been proposed, which shows that a traditional thermo-stable organic semiconductor (dinaphtho[2,3-b:2′,3′-f]thieno[3,2-b]thiophene, DNTT) achieves a high temperature sensitivity of 155.