사물 융합 태양전지 기술 및 전망
|
|
Im, Dong-Chan
(한국재료연구원 나노혁신연구센터, 나노표면재료연구본부 에너지전자재료연구실)
Kim, So-Yeon (한국재료연구원 나노표면재료연구본부 에너지전자재료연구실) |
| 1 | Luyao Lu 외 4인, 2014, Ternary blend polymer solar cells with enhanced power conversion efficiency. |
| 2 | 산업통산자원부, 2020, 보도자료 "탄소중립 사회를 향한 그린뉴딜 첫걸음". |
| 3 | 아시아경제, 2020, 보도자료 "발전량 못따라가는 태양광...'그린뉴딜' 먹구름". |
| 4 | W. K. Metzger 외 15인, 2019, Exceeding 20% efficiency with in situ group V doping in polycrystalline CdTe solar cells. |
| 5 | Alessia Le Donne 외 2인, 2019, New Earth-Abundant Thin Film Solar Cells Based on Chalcogenides. |
| 6 | StartUs insights, 2020, 보도자료, "4 Top Thin-Film Solar Cell Startups" |
| 7 | Pengqing Bi 외 10인, 2021, Reduced non-radiative charge recombination enables organic photovoltaic cell approaching 19% efficiency. |
| 8 | Zhong Zheng 외 8인, 2022, Tandem Organic Solar Cell with 20.2% Efficiency. |
| 9 | n-tech research report, 2016, "Organic Photovoltaic Markets 2016-2025" |
| 10 | Ian Mathews 외 3인, 2019, Technology and Market Perspective for Indoor Photovoltaic Cells. |
| 11 | Junjiang Wu 외 5인, 2021, Towards a bright future: The versatile applications of organic solar cells. |
| 12 | Hwa Sook Ryu 외 4인, 2020, Recent progress in indoor organic photovoltaics. |
| 13 | Pengqing Bi 외 1인, 2018, Versatile Ternary Approach for Novel Organic Solar Cells: A Review. |
| 14 | Runnan Yu 외 2인, 2018, Recent Progress in Ternary Organic Solar Cells Based on Nonfullerene Acceptors. |
| 15 | Wanning Li 외 5인, 2018, A High-Efficiency Organic Solar Cell Enabled by the Strong Intramolecular Electron Push-Pull Effect of the Nonfullerene Acceptor. |
| 16 | Myung Hyun Ann 외 9인, 2020, Device design rules and operation principles of high-power perovskite solar cells for indoor applications. |
| 17 | Jong-Hoon Lee 외 7인, 2018, Reinforcing the Built-In Field for Efficient Charge Collection in Polymer Solar Cells. |
| 18 | Stephan van Reenen 외 5인, 2014, Origin of Work Function Modification by Ionic and Amine-Based Interface Layers. |
| 19 | Hin-Lap Yip 외 1인, 2012, Recent advances in solution-processed interfacial materials for efficient and stable polymer solar cells. |
| 20 | Alan J. Heeger, 2013, 25th Anniversary Article: Bulk Heterojunction Solar Cells: Understanding the Mechanism of Operation. |
| 21 | Ping Li 외 11인, 2014, High-efficiency inverted polymer solar cells controlled by the thickness of polyethylenimine ethoxylated (PEIE) interfacial layers. |
| 22 | Man Ling Jiang 외 6인, 2019, High-Performance Organic Dyes with Electron-Deficient Quinoxalinoid Heterocycles for Dye-Sensitized Solar Cells under One Sun and Indoor Light. |
| 23 | Muhammad Jahandar 외 2인, 2021, Indoor Organic Photovoltaics for Self-Sustaining IoT Devices: Progress, Challenges and Practicalization. |
| 24 | Huiqiong Zhou 외 7인, 2013, High-Efficiency Polymer Solar Cells Enhanced by Solvent Treatment. |
| 25 | Christie L. Cutting 외 2인, 2016, Indoor light recycling: a new home for organic photovoltaics. |
 |
Korea Institute of Science and Technology Information
Gwahangno, Yuseong-gu, Daejeon, 305-806, Korea TEL : +82-42-869-1752
Copyright (c) 2009 KISTI. All Rights Reserved. For more information mail to
webmaster
