請用此 Handle URI 來引用此文件:
http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/92324
完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 何國川 | zh_TW |
dc.contributor.advisor | Kuo-Chuan Ho | en |
dc.contributor.author | 李語昕 | zh_TW |
dc.contributor.author | Yu-Hsin Lee | en |
dc.date.accessioned | 2024-03-21T16:37:22Z | - |
dc.date.available | 2024-03-22 | - |
dc.date.copyright | 2024-03-21 | - |
dc.date.issued | 2024 | - |
dc.date.submitted | 2024-02-18 | - |
dc.identifier.citation | (1) Tsubomura, H.qpslcm@ikd Matsumura, M.qpslcm@ikd Nomura, Y.qpslcm@ikd Amamiya, T. Dye sensitised zinc oxide: aqueous electrolyte: platinum photocell. Nature 1976, 261 (5559), 402-403.
(2) Grätzel, M. Conversion of sunlight to electric power by nanocrystalline dye-sensitized solar cells. Journal of Photochemistry and Photobiology A: Chemistry 2004, 164 (1-3), 3-14. (3) Grätzel, M. Photoelectrochemical cells. nature 2001, 414 (6861), 338-344. (4) Grätzel, M. Solar energy conversion by dye-sensitized photovoltaic cells. Inorganic chemistry 2005, 44 (20), 6841-6851. (5) Grätzel, M. Conversion of sunlight to electric power by nanocrystalline dye-sensitized solar cells. Journal of Photochemistry and Photobiology A: Chemistry 2004, 164 (1), 3-14. (6) Hagfeldt, A.qpslcm@ikd Boschloo, G.qpslcm@ikd Sun, L.qpslcm@ikd Kloo, L.qpslcm@ikd Pettersson, H. Dye-sensitized solar cells. Chemical reviews 2010, 110 (11), 6595-6663. (7) Zhu, S.qpslcm@ikd Liu, X.qpslcm@ikd Lin, J.qpslcm@ikd Chen, X. Low temperature transferring of anodized TiO2 nanotube-array onto a flexible substrate for dye-sensitized solar cells. Optical Materials Express 2015, 5 (12), 2754-2760. (8) Weerasinghe, H.qpslcm@ikd Sirimanne, P.qpslcm@ikd Franks, G.qpslcm@ikd Simon, G.qpslcm@ikd Cheng, Y. Low temperature chemically sintered nano-crystalline TiO2 electrodes for flexible dye-sensitized solar cells. Journal of Photochemistry and Photobiology A: Chemistry 2010, 213 (1), 30-36. (9) Grätzel, M. Photoelectrochemical cells. nature 414. 2001. (10) O'regan, B.qpslcm@ikd Grätzel, M. A low-cost, high-efficiency solar cell based on dye-sensitized colloidal TiO2 films. nature 1991, 353 (6346), 737-740. (11) Feng, X.qpslcm@ikd Shankar, K.qpslcm@ikd Varghese, O. K.qpslcm@ikd Paulose, M.qpslcm@ikd Latempa, T. J.qpslcm@ikd Grimes, C. A. Vertically aligned single crystal TiO2 nanowire arrays grown directly on transparent conducting oxide coated glass: synthesis details and applications. Nano letters 2008, 8 (11), 3781-3786. (12) Jiu, J.qpslcm@ikd Isoda, S.qpslcm@ikd Wang, F.qpslcm@ikd Adachi, M. Dye-sensitized solar cells based on a single-crystalline TiO2 nanorod film. The Journal of Physical Chemistry B 2006, 110 (5), 2087-2092. (13) Nazeeruddin, M. K.qpslcm@ikd Kay, A.qpslcm@ikd Rodicio, I.qpslcm@ikd Humphry-Baker, R.qpslcm@ikd Müller, E.qpslcm@ikd Liska, P.qpslcm@ikd Vlachopoulos, N.qpslcm@ikd Grätzel, M. Conversion of light to electricity by cis-X2bis (2, 2'-bipyridyl-4, 4'-dicarboxylate) ruthenium (II) charge-transfer sensitizers (X= Cl-, Br-, I-, CN-, and SCN-) on nanocrystalline titanium dioxide electrodes. Journal of the American Chemical Society 1993, 115 (14), 6382-6390. (14) Wang, P.qpslcm@ikd Klein, C.qpslcm@ikd Humphry-Baker, R.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Grätzel, M. A High Molar Extinction Coefficient Sensitizer for Stable Dye-Sensitized Solar Cells. Journal of the American Chemical Society 2005, 127 (3), 808-809. (15) Chen, C.-Y.qpslcm@ikd Wang, M.qpslcm@ikd Li, J.-Y.qpslcm@ikd Pootrakulchote, N.qpslcm@ikd Alibabaei, L.qpslcm@ikd Ngoc-le, C.-h.qpslcm@ikd Decoppet, J.-D.qpslcm@ikd Tsai, J.-H.qpslcm@ikd Grätzel, C.qpslcm@ikd Wu, C.-G. Highly efficient light-harvesting ruthenium sensitizer for thin-film dye-sensitized solar cells. ACS nano 2009, 3 (10), 3103-3109. (16) Yu, Q.qpslcm@ikd Wang, Y.qpslcm@ikd Yi, Z.qpslcm@ikd Zu, N.qpslcm@ikd Zhang, J.qpslcm@ikd Zhang, M.qpslcm@ikd Wang, P. High-efficiency dye-sensitized solar cells: the influence of lithium ions on exciton dissociation, charge recombination, and surface states. ACS nano 2010, 4 (10), 6032-6038. (17) Nazeeruddin, M. K.qpslcm@ikd De Angelis, F.qpslcm@ikd Fantacci, S.qpslcm@ikd Selloni, A.qpslcm@ikd Viscardi, G.qpslcm@ikd Liska, P.qpslcm@ikd Ito, S.qpslcm@ikd Takeru, B.qpslcm@ikd Grätzel, M. Combined experimental and DFT-TDDFT computational study of photoelectrochemical cell ruthenium sensitizers. Journal of the American Chemical Society 2005, 127 (48), 16835-16847. (18) Chen, C.-Y.qpslcm@ikd Wang, M.qpslcm@ikd Li, J.-Y.qpslcm@ikd Pootrakulchote, N.qpslcm@ikd Alibabaei, L.qpslcm@ikd Ngoc-le, C.-h.qpslcm@ikd Decoppet, J.-D.qpslcm@ikd Tsai, J.-H.qpslcm@ikd Grätzel, C.qpslcm@ikd Wu, C.-G.qpslcm@ikd et al. Highly Efficient Light-Harvesting Ruthenium Sensitizer for Thin-Film Dye-Sensitized Solar Cells. ACS Nano 2009, 3 (10), 3103-3109. (19) Bessho, T.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Yeh, C. Y.qpslcm@ikd Diau, E. W. G.qpslcm@ikd Grätzel, M. Highly efficient mesoscopic dye‐sensitized solar cells based on donor–acceptor‐substituted porphyrins. Angewandte Chemie International Edition 2010, 49 (37), 6646-6649. (20) Yella, A.qpslcm@ikd Lee, H.-W.qpslcm@ikd Tsao, H. N.qpslcm@ikd Yi, C.qpslcm@ikd Chandiran, A. K.qpslcm@ikd Nazeeruddin, M. K.qpslcm@ikd Diau, E. W.-G.qpslcm@ikd Yeh, C.-Y.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Grätzel, M. Porphyrin-sensitized solar cells with cobalt (II/III)–based redox electrolyte exceed 12 percent efficiency. science 2011, 334 (6056), 629-634. (21) Mathew, S.qpslcm@ikd Yella, A.qpslcm@ikd Gao, P.qpslcm@ikd Humphry-Baker, R.qpslcm@ikd Curchod, B. F.qpslcm@ikd Ashari-Astani, N.qpslcm@ikd Tavernelli, I.qpslcm@ikd Rothlisberger, U.qpslcm@ikd Nazeeruddin, M. K.qpslcm@ikd Grätzel, M. Dye-sensitized solar cells with 13% efficiency achieved through the molecular engineering of porphyrin sensitizers. Nature chemistry 2014, 6 (3), 242-247. (22) Ito, S.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Humphry‐Baker, R.qpslcm@ikd Liska, P.qpslcm@ikd Charvet, R.qpslcm@ikd Comte, P.qpslcm@ikd Nazeeruddin, M. K.qpslcm@ikd Péchy, P.qpslcm@ikd Takata, M.qpslcm@ikd Miura, H. High‐efficiency organic‐dye‐sensitized solar cells controlled by nanocrystalline‐TiO2 electrode thickness. Advanced Materials 2006, 18 (9), 1202-1205. (23) Ito, S.qpslcm@ikd Miura, H.qpslcm@ikd Uchida, S.qpslcm@ikd Takata, M.qpslcm@ikd Sumioka, K.qpslcm@ikd Liska, P.qpslcm@ikd Comte, P.qpslcm@ikd Péchy, P.qpslcm@ikd Grätzel, M. High-conversion-efficiency organic dye-sensitized solar cells with a novel indoline dye. Chemical Communications 2008, (41), 5194-5196. (24) Zhang, G.qpslcm@ikd Bala, H.qpslcm@ikd Cheng, Y.qpslcm@ikd Shi, D.qpslcm@ikd Lv, X.qpslcm@ikd Yu, Q.qpslcm@ikd Wang, P. High efficiency and stable dye-sensitized solar cells with an organic chromophore featuring a binary π-conjugated spacer. Chemical Communications 2009, (16), 2198-2200. (25) Zeng, W.qpslcm@ikd Cao, Y.qpslcm@ikd Bai, Y.qpslcm@ikd Wang, Y.qpslcm@ikd Shi, Y.qpslcm@ikd Zhang, M.qpslcm@ikd Wang, F.qpslcm@ikd Pan, C.qpslcm@ikd Wang, P. Efficient dye-sensitized solar cells with an organic photosensitizer featuring orderly conjugated ethylenedioxythiophene and dithienosilole blocks. Chemistry of Materials 2010, 22 (5), 1915-1925. (26) Kakiage, K.qpslcm@ikd Aoyama, Y.qpslcm@ikd Yano, T.qpslcm@ikd Oya, K.qpslcm@ikd Fujisawa, J.-i.qpslcm@ikd Hanaya, M. Highly-efficient dye-sensitized solar cells with collaborative sensitization by silyl-anchor and carboxy-anchor dyes. Chemical communications 2015, 51 (88), 15894-15897. (27) Cao, F.qpslcm@ikd Oskam, G.qpslcm@ikd Searson, P. C. A solid state, dye sensitized photoelectrochemical cell. The journal of physical chemistry 1995, 99 (47), 17071-17073. (28) Wolfbauer, G.qpslcm@ikd Bond, A. M.qpslcm@ikd Eklund, J. C.qpslcm@ikd MacFarlane, D. R. A channel flow cell system specifically designed to test the efficiency of redox shuttles in dye sensitized solar cells. Solar energy materials and solar cells 2001, 70 (1), 85-101. (29) Nakade, S.qpslcm@ikd Kanzaki, T.qpslcm@ikd Kubo, W.qpslcm@ikd Kitamura, T.qpslcm@ikd Wada, Y.qpslcm@ikd Yanagida, S. Role of electrolytes on charge recombination in dye-sensitized TiO2 solar cell (1): the case of solar cells using the I-/I3-redox couple. The Journal of Physical Chemistry B 2005, 109 (8), 3480-3487. (30) Harikisun, R.qpslcm@ikd Desilvestro, H. Long-term stability of dye solar cells. Solar Energy 2011, 85 (6), 1179-1188. (31) Balraju, P.qpslcm@ikd Suresh, P.qpslcm@ikd Kumar, M.qpslcm@ikd Roy, M.qpslcm@ikd Sharma, G. Effect of counter electrode, thickness and sintering temperature of TiO2 electrode and TBP addition in electrolyte on photovoltaic performance of dye sensitized solar cell using pyronine G (PYR) dye. Journal of Photochemistry and photobiology A: Chemistry 2009, 206 (1), 53-63. (32) Stergiopoulos, T.qpslcm@ikd Arabatzis, I. M.qpslcm@ikd Katsaros, G.qpslcm@ikd Falaras, P. Binary polyethylene oxide/titania solid-state redox electrolyte for highly efficient nanocrystalline TiO2 photoelectrochemical cells. Nano letters 2002, 2 (11), 1259-1261. (33) Agrell, H. G.qpslcm@ikd Lindgren, J.qpslcm@ikd Hagfeldt, A. Coordinative interactions in a dye-sensitized solar cell. Journal of Photochemistry and Photobiology A: Chemistry 2004, 164 (1-3), 23-27. (34) Hamann, T. W. The end of iodide? Cobalt complex redox shuttles in DSSCs. Dalton Transactions 2012, 41 (11), 3111-3115. (35) Feldt, S. M.qpslcm@ikd Wang, G.qpslcm@ikd Boschloo, G.qpslcm@ikd Hagfeldt, A. Effects of Driving Forces for Recombination and Regeneration on the Photovoltaic Performance of Dye-Sensitized Solar Cells using Cobalt Polypyridine Redox Couples. The Journal of Physical Chemistry C 2011, 115 (43), 21500-21507. (36) Srivishnu, K.qpslcm@ikd Prasanthkumar, S.qpslcm@ikd Giribabu, L. Cu (II/I) redox couples: Potential alternatives to traditional electrolytes for dye-sensitized solar cells. Materials Advances 2021, 2 (4), 1229-1247. (37) Hattori, S.qpslcm@ikd Wada, Y.qpslcm@ikd Yanagida, S.qpslcm@ikd Fukuzumi, S. Blue copper model complexes with distorted tetragonal geometry acting as effective electron-transfer mediators in dye-sensitized solar cells. Journal of the American Chemical Society 2005, 127 (26), 9648-9654. (38) Cong, J.qpslcm@ikd Kinschel, D.qpslcm@ikd Daniel, Q.qpslcm@ikd Safdari, M.qpslcm@ikd Gabrielsson, E.qpslcm@ikd Chen, H.qpslcm@ikd Svensson, P. H.qpslcm@ikd Sun, L.qpslcm@ikd Kloo, L. Bis (1, 1-bis (2-pyridyl) ethane) copper (I/II) as an efficient redox couple for liquid dye-sensitized solar cells. Journal of Materials Chemistry A 2016, 4 (38), 14550-14554. (39) Bai, Y.qpslcm@ikd Yu, Q.qpslcm@ikd Cai, N.qpslcm@ikd Wang, Y.qpslcm@ikd Zhang, M.qpslcm@ikd Wang, P. High-efficiency organic dye-sensitized mesoscopic solar cells with a copper redox shuttle. Chemical Communications 2011, 47 (15), 4376-4378. (40) Freitag, M.qpslcm@ikd Giordano, F.qpslcm@ikd Yang, W.qpslcm@ikd Pazoki, M.qpslcm@ikd Hao, Y.qpslcm@ikd Zietz, B.qpslcm@ikd Grätzel, M.qpslcm@ikd Hagfeldt, A.qpslcm@ikd Boschloo, G. Copper phenanthroline as a fast and high-performance redox mediator for dye-sensitized solar cells. The Journal of Physical Chemistry C 2016, 120 (18), 9595-9603. (41) Saygili, Y.qpslcm@ikd Söderberg, M.qpslcm@ikd Pellet, N.qpslcm@ikd Giordano, F.qpslcm@ikd Cao, Y.qpslcm@ikd Muñoz-García, A. B.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Vlachopoulos, N.qpslcm@ikd Pavone, M.qpslcm@ikd Boschloo, G.qpslcm@ikd et al. Copper Bipyridyl Redox Mediators for Dye-Sensitized Solar Cells with High Photovoltage. Journal of the American Chemical Society 2016, 138 (45), 15087-15096. (42) Freitag, M.qpslcm@ikd Teuscher, J.qpslcm@ikd Saygili, Y.qpslcm@ikd Zhang, X.qpslcm@ikd Giordano, F.qpslcm@ikd Liska, P.qpslcm@ikd Hua, J.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Moser, J.-E.qpslcm@ikd Grätzel, M. Dye-sensitized solar cells for efficient power generation under ambient lighting. Nature Photonics 2017, 11 (6), 372-378. (43) Tanaka, E.qpslcm@ikd Michaels, H.qpslcm@ikd Freitag, M.qpslcm@ikd Robertson, N. Synergy of co-sensitizers in a copper bipyridyl redox system for efficient and cost-effective dye-sensitized solar cells in solar and ambient light. Journal of Materials Chemistry A 2020, 8 (3), 1279-1287. (44) Jiang, H.qpslcm@ikd Ren, Y.qpslcm@ikd Zhang, W.qpslcm@ikd Wu, Y.qpslcm@ikd Socie, E. C.qpslcm@ikd Carlsen, B. I.qpslcm@ikd Moser, J. E.qpslcm@ikd Tian, H.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Zhu, W. H. Phenanthrene‐Fused‐Quinoxaline as a Key Building Block for Highly Efficient and Stable Sensitizers in Copper‐Electrolyte‐Based Dye‐Sensitized Solar Cells. Angewandte Chemie 2020, 132 (24), 9410-9415. (45) Freitag, M.qpslcm@ikd Daniel, Q.qpslcm@ikd Pazoki, M.qpslcm@ikd Sveinbjörnsson, K.qpslcm@ikd Zhang, J.qpslcm@ikd Sun, L.qpslcm@ikd Hagfeldt, A.qpslcm@ikd Boschloo, G. High-efficiency dye-sensitized solar cells with molecular copper phenanthroline as solid hole conductor. Energy & Environmental Science 2015, 8 (9), 2634-2637. (46) Freitag, M.qpslcm@ikd Giordano, F.qpslcm@ikd Yang, W.qpslcm@ikd Pazoki, M.qpslcm@ikd Hao, Y.qpslcm@ikd Zietz, B.qpslcm@ikd Grätzel, M.qpslcm@ikd Hagfeldt, A.qpslcm@ikd Boschloo, G. Copper Phenanthroline as a Fast and High-Performance Redox Mediator for Dye-Sensitized Solar Cells. The Journal of Physical Chemistry C 2016, 120 (18), 9595-9603. (47) De Rossi, F.qpslcm@ikd Pontecorvo, T.qpslcm@ikd Brown, T. M. Characterization of photovoltaic devices for indoor light harvesting and customization of flexible dye solar cells to deliver superior efficiency under artificial lighting. Applied Energy 2015, 156, 413-422. (48) Liu, Y.qpslcm@ikd Cao, Y.qpslcm@ikd Zhang, W.qpslcm@ikd Stojanovic, M.qpslcm@ikd Dar, M. I.qpslcm@ikd Péchy, P.qpslcm@ikd Saygili, Y.qpslcm@ikd Hagfeldt, A.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Grätzel, M. Electron‐affinity‐triggered variations on the optical and electrical properties of dye molecules enabling highly efficient dye‐sensitized solar cells. Angewandte Chemie 2018, 130 (43), 14321-14324. (49) Grobelny, A.qpslcm@ikd Shen, Z.qpslcm@ikd Eickemeyer, F. T.qpslcm@ikd Antariksa, N. F.qpslcm@ikd Zapotoczny, S.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Grätzel, M. A Molecularly Tailored Photosensitizer with an Efficiency of 13.2% for Dye‐Sensitized Solar Cells. Advanced Materials 2023, 35 (5), 2207785. (50) Ren, Y.qpslcm@ikd Zhang, D.qpslcm@ikd Suo, J.qpslcm@ikd Cao, Y.qpslcm@ikd Eickemeyer, F. T.qpslcm@ikd Vlachopoulos, N.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Hagfeldt, A.qpslcm@ikd Grätzel, M. Hydroxamic acid pre-adsorption raises the efficiency of cosensitized solar cells. Nature 2023, 613 (7942), 60-65. (51) Zhang, D.qpslcm@ikd Stojanovic, M.qpslcm@ikd Ren, Y.qpslcm@ikd Cao, Y.qpslcm@ikd Eickemeyer, F. T.qpslcm@ikd Socie, E.qpslcm@ikd Vlachopoulos, N.qpslcm@ikd Moser, J.-E.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Hagfeldt, A. A molecular photosensitizer achieves a V oc of 1.24 V enabling highly efficient and stable dye-sensitized solar cells with copper (II/I)-based electrolyte. Nature communications 2021, 12 (1), 1777. (52) Cao, Y.qpslcm@ikd Liu, Y.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Hagfeldt, A.qpslcm@ikd Grätzel, M. Direct contact of selective charge extraction layers enables high-efficiency molecular photovoltaics. Joule 2018, 2 (6), 1108-1117. (53) Michaels, H.qpslcm@ikd Rinderle, M.qpslcm@ikd Freitag, R.qpslcm@ikd Benesperi, I.qpslcm@ikd Edvinsson, T.qpslcm@ikd Socher, R.qpslcm@ikd Gagliardi, A.qpslcm@ikd Freitag, M. Dye-sensitized solar cells under ambient light powering machine learning: towards autonomous smart sensors for the internet of things. Chemical Science 2020, 11 (11), 2895-2906. (54) Cao, Y.qpslcm@ikd Saygili, Y.qpslcm@ikd Ummadisingu, A.qpslcm@ikd Teuscher, J.qpslcm@ikd Luo, J.qpslcm@ikd Pellet, N.qpslcm@ikd Giordano, F.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Moser, J. E.qpslcm@ikd Freitag, M.qpslcm@ikd et al. 11% efficiency solid-state dye-sensitized solar cells with copper(II/I) hole transport materials. Nature Communications 2017, 8 (1), 15390. (55) Lee, Y.-L.qpslcm@ikd Chen, C.-L.qpslcm@ikd Chong, L.-W.qpslcm@ikd Chen, C.-H.qpslcm@ikd Liu, Y.-F.qpslcm@ikd Chi, C.-F. A platinum counter electrode with high electrochemical activity and high transparency for dye-sensitized solar cells. Electrochemistry Communications 2010, 12 (11), 1662-1665. (56) Li, L.-L.qpslcm@ikd Chang, C.-W.qpslcm@ikd Wu, H.-H.qpslcm@ikd Shiu, J.-W.qpslcm@ikd Wu, P.-T.qpslcm@ikd Diau, E. W.-G. Morphological control of platinum nanostructures for highly efficient dye-sensitized solar cells. Journal of Materials Chemistry 2012, 22 (13), 6267-6273. (57) Chen, C. C.qpslcm@ikd Nguyen, V. S.qpslcm@ikd Chiu, H. C.qpslcm@ikd Chen, Y. D.qpslcm@ikd Wei, T. C.qpslcm@ikd Yeh, C. Y. Anthracene‐Bridged Sensitizers for Dye‐Sensitized Solar Cells with 37% Efficiency under Dim Light. Advanced Energy Materials 2022, 12 (20), 2104051. (58) Gilbert, J. M.qpslcm@ikd Balouchi, F. Comparison of energy harvesting systems for wireless sensor networks. International Journal of automation and computing 2008, 5, 334-347. (59) Mathews, I.qpslcm@ikd King, P. J.qpslcm@ikd Stafford, F.qpslcm@ikd Frizzell, R. Performance of III–V solar cells as indoor light energy harvesters. IEEE Journal of Photovoltaics 2015, 6 (1), 230-235. (60) Tingare, Y. NS n. Vinh, HH Chou, YC Liu, YS Long, TC Wu, TC Wei and CY Yeh, Adv. Energy Mater 2017, 7, 1700032. (61) Tsai, M.-C.qpslcm@ikd Wang, C.-L.qpslcm@ikd Chang, C.-W.qpslcm@ikd Hsu, C.-W.qpslcm@ikd Hsiao, Y.-H.qpslcm@ikd Liu, C.-L.qpslcm@ikd Wang, C.-C.qpslcm@ikd Lin, S.-Y.qpslcm@ikd Lin, C.-Y. A large, ultra-black, efficient and cost-effective dye-sensitized solar module approaching 12% overall efficiency under 1000 lux indoor light. Journal of Materials Chemistry A 2018, 6 (5), 1995-2003, 10.1039/C7TA09322E. (62) Kubo, W.qpslcm@ikd Murakoshi, K.qpslcm@ikd Kitamura, T.qpslcm@ikd Wada, Y.qpslcm@ikd Hanabusa, K.qpslcm@ikd Shirai, H.qpslcm@ikd Yanagida, S. Fabrication of quasi-solid-state dye-sensitized TiO2 solar cells using low molecular weight gelators. Chemistry Letters 1998, 27 (12), 1241-1242. (63) Kubo, W.qpslcm@ikd Kitamura, T.qpslcm@ikd Hanabusa, K.qpslcm@ikd Wada, Y.qpslcm@ikd Yanagida, S. Quasi-solid-state dye-sensitized solar cells using room temperature molten salts and a low molecular weight gelator. Chemical communications 2002, (4), 374-375. (64) Wang, C.qpslcm@ikd Wang, L.qpslcm@ikd Shi, Y.qpslcm@ikd Zhang, H.qpslcm@ikd Ma, T. Printable electrolytes for highly efficient quasi-solid-state dye-sensitized solar cells. Electrochimica Acta 2013, 91, 302-306. (65) Saygili, Y.qpslcm@ikd Söderberg, M.qpslcm@ikd Pellet, N.qpslcm@ikd Giordano, F.qpslcm@ikd Cao, Y.qpslcm@ikd Muñoz-García, A. B.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Vlachopoulos, N.qpslcm@ikd Pavone, M.qpslcm@ikd Boschloo, G. Copper bipyridyl redox mediators for dye-sensitized solar cells with high photovoltage. Journal of the American Chemical Society 2016, 138 (45), 15087-15096. (66) Rogelj, J.qpslcm@ikd Den Elzen, M.qpslcm@ikd Höhne, N.qpslcm@ikd Fransen, T.qpslcm@ikd Fekete, H.qpslcm@ikd Winkler, H.qpslcm@ikd Schaeffer, R.qpslcm@ikd Sha, F.qpslcm@ikd Riahi, K.qpslcm@ikd Meinshausen, M. Paris Agreement climate proposals need a boost to keep warming well below 2 C. Nature 2016, 534 (7609), 631-639. (67) Panwar, N. L.qpslcm@ikd Kaushik, S. C.qpslcm@ikd Kothari, S. Role of renewable energy sources in environmental protection: A review. Renewable and sustainable energy reviews 2011, 15 (3), 1513-1524. (68) Grifoni, F.qpslcm@ikd Bonomo, M.qpslcm@ikd Naim, W.qpslcm@ikd Barbero, N.qpslcm@ikd Alnasser, T.qpslcm@ikd Dzeba, I.qpslcm@ikd Giordano, M.qpslcm@ikd Tsaturyan, A.qpslcm@ikd Urbani, M.qpslcm@ikd Torres, T. Toward Sustainable, Colorless, and Transparent Photovoltaics: State of the Art and Perspectives for the Development of Selective Near‐Infrared Dye‐Sensitized Solar Cells. Advanced Energy Materials 2021, 11 (43), 2101598. (69) Green, M.qpslcm@ikd Dunlop, E.qpslcm@ikd Hohl‐Ebinger, J.qpslcm@ikd Yoshita, M.qpslcm@ikd Kopidakis, N.qpslcm@ikd Hao, X. Solar cell efficiency tables (version 57). Progress in photovoltaics: research and applications 2021, 29 (1), 3-15. (70) Polman, A.qpslcm@ikd Knight, M.qpslcm@ikd Garnett, E. C.qpslcm@ikd Ehrler, B.qpslcm@ikd Sinke, W. C. Photovoltaic materials: Present efficiencies and future challenges. Science 2016, 352 (6283), aad4424. (71) Bhattacharya, S.qpslcm@ikd John, S. Beyond 30% conversion efficiency in silicon solar cells: a numerical demonstration. Scientific reports 2019, 9 (1), 12482. (72) Muñoz-García, A. B.qpslcm@ikd Benesperi, I.qpslcm@ikd Boschloo, G.qpslcm@ikd Concepcion, J. J.qpslcm@ikd Delcamp, J. H.qpslcm@ikd Gibson, E. A.qpslcm@ikd Meyer, G. J.qpslcm@ikd Pavone, M.qpslcm@ikd Pettersson, H.qpslcm@ikd Hagfeldt, A. Dye-sensitized solar cells strike back. Chemical Society Reviews 2021, 50 (22), 12450-12550. (73) Battaglia, C.qpslcm@ikd Cuevas, A.qpslcm@ikd De Wolf, S. High-efficiency crystalline silicon solar cells: status and perspectives. Energy & Environmental Science 2016, 9 (5), 1552-1576. (74) Kinsey, G. S. Solar cell efficiency divergence due to operating spectrum variation. Solar Energy 2021, 217, 49-57. (75) Jiang, Q.qpslcm@ikd Tong, J.qpslcm@ikd Xian, Y.qpslcm@ikd Kerner, R. A.qpslcm@ikd Dunfield, S. P.qpslcm@ikd Xiao, C.qpslcm@ikd Scheidt, R. A.qpslcm@ikd Kuciauskas, D.qpslcm@ikd Wang, X.qpslcm@ikd Hautzinger, M. P. Surface reaction for efficient and stable inverted perovskite solar cells. Nature 2022, 611 (7935), 278-283. (76) Mathews, I.qpslcm@ikd Kantareddy, S. N.qpslcm@ikd Buonassisi, T.qpslcm@ikd Peters, I. M. Technology and market perspective for indoor photovoltaic cells. Joule 2019, 3 (6), 1415-1426. (77) Sakamoto, R.qpslcm@ikd Katagiri, S.qpslcm@ikd Maeda, H.qpslcm@ikd Nishimori, Y.qpslcm@ikd Miyashita, S.qpslcm@ikd Nishihara, H. Electron transport dynamics in redox-molecule-terminated branched oligomer wires on Au (111). Journal of the American Chemical Society 2015, 137 (2), 734-741. (78) Yang, P.qpslcm@ikd Chan, I.qpslcm@ikd Lin, C.qpslcm@ikd Chang, Y. Thin film solar cells for indoor use. In 2011 37th IEEE Photovoltaic Specialists Conference, 2011qpslcm@ikd IEEE: pp 000696-000698. (79) Lechêne, B. P.qpslcm@ikd Cowell, M.qpslcm@ikd Pierre, A.qpslcm@ikd Evans, J. W.qpslcm@ikd Wright, P. K.qpslcm@ikd Arias, A. C. Organic solar cells and fully printed super-capacitors optimized for indoor light energy harvesting. Nano Energy 2016, 26, 631-640. (80) Barber, G. D.qpslcm@ikd Hoertz, P. G.qpslcm@ikd Lee, S.-H. A.qpslcm@ikd Abrams, N. M.qpslcm@ikd Mikulca, J.qpslcm@ikd Mallouk, T. E.qpslcm@ikd Liska, P.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Gratzel, M.qpslcm@ikd Ho-Baillie, A. Utilization of Direct and Diffuse Sunlight in a Dye-Sensitized Solar Cell Silicon Photovoltaic Hybrid Concentrator System. The Journal of Physical Chemistry Letters 2011, 2 (6), 581-585. (81) Devadiga, D.qpslcm@ikd Selvakumar, M.qpslcm@ikd Shetty, P.qpslcm@ikd Santosh, M. Dye-sensitized solar cell for indoor applications: a mini-review. Journal of Electronic Materials 2021, 50, 3187-3206. (82) Yum, J.-H.qpslcm@ikd Baranoff, E.qpslcm@ikd Kessler, F.qpslcm@ikd Moehl, T.qpslcm@ikd Ahmad, S.qpslcm@ikd Bessho, T.qpslcm@ikd Marchioro, A.qpslcm@ikd Ghadiri, E.qpslcm@ikd Moser, J.-E.qpslcm@ikd Yi, C. A cobalt complex redox shuttle for dye-sensitized solar cells with high open-circuit potentials. Nature communications 2012, 3 (1), 631. (83) Cameron, P. J.qpslcm@ikd Peter, L. M.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Grätzel, M. Electrochemical studies of the Co (III)/Co (II)(dbbip) 2 redox couple as a mediator for dye-sensitized nanocrystalline solar cells. Coordination Chemistry Reviews 2004, 248 (13-14), 1447-1453. (84) Sapp, S. A.qpslcm@ikd Elliott, C. M.qpslcm@ikd Contado, C.qpslcm@ikd Caramori, S.qpslcm@ikd Bignozzi, C. A. Substituted polypyridine complexes of cobalt (II/III) as efficient electron-transfer mediators in dye-sensitized solar cells. Journal of the American Chemical Society 2002, 124 (37), 11215-11222. (85) Magni, M.qpslcm@ikd Giannuzzi, R.qpslcm@ikd Colombo, A.qpslcm@ikd Cipolla, M. P.qpslcm@ikd Dragonetti, C.qpslcm@ikd Caramori, S.qpslcm@ikd Carli, S.qpslcm@ikd Grisorio, R.qpslcm@ikd Suranna, G. P.qpslcm@ikd Bignozzi, C. A. Tetracoordinated bis-phenanthroline copper-complex couple as efficient redox mediators for dye solar cells. Inorganic Chemistry 2016, 55 (11), 5245-5253. (86) Mishra, A.qpslcm@ikd Fischer, M. K.qpslcm@ikd Bäuerle, P. Metal‐free organic dyes for dye‐sensitized solar cells: From structure: Property relationships to design rules. Angewandte Chemie International Edition 2009, 48 (14), 2474-2499. (87) Cao, Y.qpslcm@ikd Saygili, Y.qpslcm@ikd Ummadisingu, A.qpslcm@ikd Teuscher, J.qpslcm@ikd Luo, J.qpslcm@ikd Pellet, N.qpslcm@ikd Giordano, F.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Moser, J.-E.qpslcm@ikd Freitag, M. 11% efficiency solid-state dye-sensitized solar cells with copper (II/I) hole transport materials. Nature communications 2017, 8 (1), 15390. (88) Kim, S.qpslcm@ikd Lee, J. K.qpslcm@ikd Kang, S. O.qpslcm@ikd Ko, J.qpslcm@ikd Yum, J.-H.qpslcm@ikd Fantacci, S.qpslcm@ikd De Angelis, F.qpslcm@ikd Di Censo, D.qpslcm@ikd Nazeeruddin, M. K.qpslcm@ikd Grätzel, M. Molecular engineering of organic sensitizers for solar cell applications. Journal of the American Chemical Society 2006, 128 (51), 16701-16707. (89) Tsao, H. N.qpslcm@ikd Yi, C.qpslcm@ikd Moehl, T.qpslcm@ikd Yum, J. H.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Nazeeruddin, M. K.qpslcm@ikd Grätzel, M. Cyclopentadithiophene Bridged Donor–Acceptor Dyes Achieve High Power Conversion Efficiencies in Dye‐Sensitized Solar Cells Based on the tris‐Cobalt Bipyridine Redox Couple. ChemSusChem 2011, 4 (5), 591-594. (90) Zhu, W.qpslcm@ikd Wu, Y.qpslcm@ikd Wang, S.qpslcm@ikd Li, W.qpslcm@ikd Li, X.qpslcm@ikd Chen, J.qpslcm@ikd Wang, Z. s.qpslcm@ikd Tian, H. Organic D‐A‐π‐A solar cell sensitizers with improved stability and spectral response. Advanced Functional Materials 2011, 21 (4), 756-763. (91) Zhang, X.qpslcm@ikd Xu, Y.qpslcm@ikd Giordano, F.qpslcm@ikd Schreier, M.qpslcm@ikd Pellet, N.qpslcm@ikd Hu, Y.qpslcm@ikd Yi, C.qpslcm@ikd Robertson, N.qpslcm@ikd Hua, J.qpslcm@ikd Zakeeruddin, S. M. Molecular engineering of potent sensitizers for very efficient light harvesting in thin-film solid-state dye-sensitized solar cells. Journal of the American Chemical Society 2016, 138 (34), 10742-10745. (92) Zhang, W.qpslcm@ikd Wu, Y.qpslcm@ikd Bahng, H. W.qpslcm@ikd Cao, Y.qpslcm@ikd Yi, C.qpslcm@ikd Saygili, Y.qpslcm@ikd Luo, J.qpslcm@ikd Liu, Y.qpslcm@ikd Kavan, L.qpslcm@ikd Moser, J.-E. Comprehensive control of voltage loss enables 11.7% efficient solid-state dye-sensitized solar cells. Energy & Environmental Science 2018, 11 (7), 1779-1787. (93) Wu, Y.qpslcm@ikd Zhu, W.-H.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Grätzel, M. Insight into D–A− π–A structured sensitizers: a promising route to highly efficient and stable dye-sensitized solar cells. ACS applied materials & interfaces 2015, 7 (18), 9307-9318. (94) Baumann, A.qpslcm@ikd Curiac, C.qpslcm@ikd Delcamp, J. H. The Hagfeldt Donor and Use of Next‐Generation Bulky Donor Designs in Dye‐Sensitized Solar Cells. ChemSusChem 2020, 13 (10), 2503-2512. (95) Gao, P.qpslcm@ikd Kim, Y. J.qpslcm@ikd Yum, J.-H.qpslcm@ikd Holcombe, T. W.qpslcm@ikd Nazeeruddin, M. K.qpslcm@ikd Grätzel, M. Facile synthesis of a bulky BPTPA donor group suitable for cobalt electrolyte based dye sensitized solar cells. Journal of Materials Chemistry A 2013, 1 (18), 5535-5544. (96) Ren, Y.qpslcm@ikd Flores‐Díaz, N.qpslcm@ikd Zhang, D.qpslcm@ikd Cao, Y.qpslcm@ikd Decoppet, J. D.qpslcm@ikd Fish, G. C.qpslcm@ikd Moser, J. E.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Wang, P.qpslcm@ikd Hagfeldt, A. Blue photosensitizer with copper (II/I) redox mediator for efficient and stable dye‐sensitized solar cells. Advanced Functional Materials 2020, 30 (50), 2004804. (97) Olabi, A.qpslcm@ikd Abdelkareem, M. A. Renewable energy and climate change. Renewable and Sustainable Energy Reviews 2022, 158, 112111. (98) Cameron, P. J.qpslcm@ikd Peter, L. M.qpslcm@ikd Zakeeruddin, S. M.qpslcm@ikd Grätzel, M. Electrochemical studies of the Co (III)/Co (II)(dbbip)2 redox couple as a mediator for dye-sensitized nanocrystalline solar cells. Coordination Chemistry Reviews 2004, 248 (13-14), 1447-1453. (99) Venkatesan, S.qpslcm@ikd Su, S.-C.qpslcm@ikd Hung, W.-N.qpslcm@ikd Liu, I. P.qpslcm@ikd Teng, H.qpslcm@ikd Lee, Y.-L. Printable electrolytes based on polyacrylonitrile and gamma-butyrolactone for dye-sensitized solar cell application. Journal of Power Sources 2015, 298, 385-390. (100) Liu, I.-P.qpslcm@ikd Hung, W.-N.qpslcm@ikd Teng, H.qpslcm@ikd Venkatesan, S.qpslcm@ikd Lin, J.-C.qpslcm@ikd Lee, Y.-L. High-performance printable electrolytes for dye-sensitized solar cells. Journal of Materials Chemistry A 2017, 5 (19), 9190-9197. | - |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/92324 | - |
dc.description.abstract | 這篇論文主要是探討染料敏化太陽能電池(Dye-Sensitized Solar Cells, DSSCs)的應用,主要分為兩個不同的主題,分別為新型有機敏化劑在染料敏化太陽能電池中的應用(第3章)以及膠態電解質於染料敏化太陽能電池上的表現(第4章)。這兩個研究所皆是以銅錯合物為染敏電之電解質,並探討其效應。此外,兩個研究的概述將在引言中呈現(第1章)。此外,實驗步驟將在第2章詳細介紹。
在第3章中,我們合成了一種名為EE186的新型染料作為光敏化劑,應用於以銅電解質為主的DSSCs中。這種光敏化劑之推電子基具有一個巨大的基團。我們對電池在標準太陽光和室內光照條件下的性能進行了分析,此外,也進行了二氧化鈦(TiO2)膜厚的優化。結果顯示了在這兩種照明環境下所需的最佳TiO2膜厚呈現的相反關係。雖然在陽光下的性能不及商業敏化劑Y123(9%),但透過將厚度減少到只有2層TiO2 之主動層(Main layer, ML),進一步使效率改善至8%。另一方面,在使用T5螢光燈的200照度的室內光照射下,具有2層主動層和2層散射層(Scattering layer, SL)的電池,其效率與商業染料Y123相當(21%)。此外,在較高光強度下,特別是6000照度下,效率提升至35%。根據文獻,這項研究為首次針對具有此種新型巨基團之推電子基的染料進行探討,同時揭示了具有這種類型給體的敏化劑在室內光採集方面的潛力。 在第4章中,則是將研究重心放在染敏電池之電解質部分,主要為探討採用Cu2+/Cu1+氧化還原對之電解質加入高分子膠化劑所形成之半固態染敏電池(Qusai-Solid DSSCs),在特定條件下探討其性能和穩定性,並著重在探討其室內光情形下之表現。在標準太陽光情況下則是評估了具有7% PVDF-HFP的元的性能。雖然光電效率略低於液態電池,但膠態電池表現出傑出的性能以及更好的穩定性,而在1200小時後仍保持接近其初始值的效率。 隨後,為優化在室內照明條件下的電解質組成。結果顯示,較低濃度的Cu2+/Cu1+銅離子錯合物更有助於提升短路電流,因為競爭吸光較少的緣故,導致效率提升。再者,通過簡易優化Cu(dmby)2TFSI (Cu1+)、Cu(dmby)2TFSI2 (Cu2+)、NMBI和LiTFSI的組成,使元件在T5 6000照度的室內光照下達到30%的效率。此外,研究還探討了可印刷式於室內光照條件下的應用。結果顯示在6000照度的照明條件下,將PMMA添加到PEO電解質中可以實現29%的效率。在研究的最後,通過直接接觸的電池組裝方式,進一步優化了膠態電池的表現,以獲得更高效率,在6000照度下的效率約36%。 | zh_TW |
dc.description.abstract | This thesis mainly focuses on two different but related parts, namely, novel organic sensitizers for copper-based cells applications (Chapter 3), and the preparation of gel-state DSSCs incorporating copper-based electrolyte (Chapter 4). The overview of these two applications will be displayed in the Introduction (Chapter 1). Moreover, the experimental procedures (Chapter 2).
In Chapter 3, in this research, we synthesized a novel sensitizer called EE186 for integration into copper-mediated dye-sensitized solar cells (DSSCs). This sensitizer features a bulky donor designed to be compatible with the copper redox electrolyte. We conducted a thorough analysis of the cell''s performance under both 1 sun and ambient light conditions. The results revealed a converse relationship in the required TiO2 thickness for these two illumination environments. While the performance under sunlight fell short of the commercial sensitizer Y123 (9%), we achieved an 8% efficiency improvement by reducing the thickness to just 2 main layers from the original TiO2 layer with 2 scattering layers. Surprisingly, when exposed to 200 lux of room light from a T5 fluorescent tube, the cell with 2 main layers plus two scattering layers incorporating the novel sensitizer EE186 achieved a comparable efficiency to the commercial dye Y123. Furthermore, the efficiency soared to 35% under higher light intensity, specifically 6000 lux. This study marks the first investigation of a dye featuring a novel crowded donor, revealing that a sensitizer with this type of donor holds potential applications in dim light harvesting. In Chapter 4, this study delves into the performance and stability of quasi-solid-state dye-sensitized solar cells (QS-DSSCs) employing a Cu2+/Cu1+ redox couple, using various polymer gel electrolytes (PGEs) under specific conditions. Initially, the device''s performance with 7 wt% poly(vinylidene fluoride-co-hexafluoropropylene) (PVDF-HFP) is evaluated under one sun conditions. While the efficiency is slightly lower than the liquid-state cell, the quasi-solid-state cell exhibits promising performance and significantly better stability, maintaining an efficiency of almost 100% of its initial value after 1200 h. Subsequently, electrolyte composition is optimized for indoor lighting conditions. Results indicate that a lower concentration of Cu(dmby)2TFSI / Cu(dmby)2TFSI2 is beneficial for higher short-circuit current density due to lower light absorbance. By optimizing the composition of Cu(dmby)2TFSI, Cu(dmby)2TFSI2, for indoor light conditions, the device achieves an efficiency of 30% under 2000 lux illumination. Furthermore, the study also explores the application of printable PGEs under indoor light conditions. It is observed that the addition of poly (methyl methacrylate) (PMMA) to the poly(ethylene oxide) (PEO) electrolytes achieves efficiencies of 29% respectively, under 6000 lux illumination. Finally, the gel-state cells were optimized by the direct-contact strategies to get higher efficiencies about 36% | en |
dc.description.provenance | Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2024-03-21T16:37:22Z No. of bitstreams: 0 | en |
dc.description.provenance | Made available in DSpace on 2024-03-21T16:37:22Z (GMT). No. of bitstreams: 0 | en |
dc.description.tableofcontents | Table of Contents.VI
List of Figures. IX List of Tables. XIV Chapter 1 Introduction .1 1-1 Overview of Dye-Sensitized Solar Cells (DSSCs). 1 1-2 Working Mechanism for DSSCs .3 1-2-1 Electron Transport Pathways on DSSCs .5 1-3 Introduction to the Structure of Dye-Sensitized Solar Cells.8 1-3-1 Conductive Substrate .9 1-3-2 Oxide Semiconductor.10 1-3-3 Sensitizer.12 1-3-4 Electrolyte .17 1-3-5 Counter Electrode .31 1-3-6 Literature Review.33 1-4 Scope of this Thesis. 43 Chapter 2 Experimental Procedures.46 2-1 General Experimental Details. 46 2-1-1 Materials. 46 2-1-2 Characterization Techniques. 47 2-2 Experimental Details. 65 2-2-1 Preparation of Titanium Dioxide Film. 65 2-2-2 Photovoltaic Electrode Sensitization Procedure . 66 2-2-3 Counter Electrode Preparation Procedure. 66 2-2-4 Electrolyte Preparation Procedure . 67 2-2-5 Assembly of Dye-Sensitized Solar Cell. 69 Chapter 3 Study of Organic Sensitizers in Copper-Based Electrolyte in Dye-Sensitized Solar Cells .72 3-1 Introduction .72 3-2 Results and Discussion.74 3-2-1 Optical Performances.74 3-2-2 Photovoltaic Performance on 1 Sun Condition. 78 3-2-3 The Light Intensity effect on the PCEs. 84 3-2-4 Stability Tests. 88 3-3 Conclusions. 89 Chapter 4 Preparation of Copper Redox Gel Electrolyte for Dye-Sensitized Solar Cells under Room Lighting Condition .90 4-1 Introduction .90 4-2 Results and Discussions . 90 4-2-1 Photovoltaic Performance . 97 4-2-2 Electrochemical Performance .107 4-2-3 Direct Contact Structure. 110 4-2-4 Device Performances under Different Light Intensities. 115 4-2-5 Stability. 118 4-3 Conclusions. 119 Chapter 5 Conclusions and Suggestions. 120 5-1 General Conclusions. 120 References.122 Appendix .135 Curriculum Vitae .143 | - |
dc.language.iso | en | - |
dc.title | 新型巨基團有機染料及膠態電解質於銅錯合物染敏電池之表現 | zh_TW |
dc.title | On the Performance of Copper–Based Dye-Sensitized Solar Cells Using Organic Dyes with Novel Bulky Group and Gel Electrolyte | en |
dc.type | Thesis | - |
dc.date.schoolyear | 112-1 | - |
dc.description.degree | 碩士 | - |
dc.contributor.coadvisor | 孫世勝 | zh_TW |
dc.contributor.coadvisor | Shih-Sheng Sun | en |
dc.contributor.oralexamcommittee | 李君婷;葉旻鑫;林律吟 | zh_TW |
dc.contributor.oralexamcommittee | Chun-Ting Li ;Min-Hsin Yeh;Lu-Yin Lin | en |
dc.subject.keyword | 染料敏化太陽能電池,銅錯合物電解質,膠態電解質,直接接觸,有機染料, | zh_TW |
dc.subject.keyword | Dye-sensitized solar cells,copper-based electrolyte,polymer-gel electrolyte,direct-contact,organic sensitizers, | en |
dc.relation.page | 144 | - |
dc.identifier.doi | 10.6342/NTU202400457 | - |
dc.rights.note | 同意授權(限校園內公開) | - |
dc.date.accepted | 2024-02-18 | - |
dc.contributor.author-college | 工學院 | - |
dc.contributor.author-dept | 化學工程學系 | - |
顯示於系所單位: | 化學工程學系 |
文件中的檔案:
檔案 | 大小 | 格式 | |
---|---|---|---|
ntu-112-1.pdf 目前未授權公開取用 | 5.34 MB | Adobe PDF | 檢視/開啟 |
系統中的文件,除了特別指名其著作權條款之外,均受到著作權保護,並且保留所有的權利。