Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
about
Alcohol-soluble Star-shaped Oligofluorenes as Interlayer for High Performance Polymer Solar Cells.Ultrathin polyaniline-based buffer layer for highly efficient polymer solar cells with wide applicabilitySingle junction inverted polymer solar cell reaching power conversion efficiency 10.31% by employing dual-doped zinc oxide nano-film as cathode interlayer.Uncovering the role of cathode buffer layer in organic solar cells.Low Work-function Poly(3,4-ethylenedioxylenethiophene): Poly(styrene sulfonate) as Electron-transport Layer for High-efficient and Stable Polymer Solar Cells.Inverted polymer fullerene solar cells exceeding 10% efficiency with poly(2-ethyl-2-oxazoline) nanodots on electron-collecting buffer layers.Water/alcohol soluble conjugated polymers for the interface engineering of highly efficient polymer light-emitting diodes and polymer solar cells.Low bandgap semiconducting polymers for polymeric photovoltaics.Stability of organic solar cells: challenges and strategies.Surface Structure Modification of ZnO and the Impact on Electronic Properties.Naphthobischalcogenadiazole Conjugated Polymers: Emerging Materials for Organic Electronics.Multiple electron transporting layers and their excellent properties based on organic solar cell.Dithienocarbazole and isoindigo based amorphous low bandgap conjugated polymers for efficient polymer solar cells.Toward Highly Sensitive Polymer Photodetectors by Molecular Engineering.Regioregular pyridyl[2,1,3]thiadiazole-co-indacenodithiophene conjugated polymers.Efficient solution-processed small-molecule solar cells with inverted structure.Highly efficient hybrid thin-film solar cells using a solution-processed hole-blocking layer.An Unfused-Core-Based Nonfullerene Acceptor Enables High-Efficiency Organic Solar Cells with Excellent Morphological Stability at High Temperatures.Cerium oxide as an efficient electron extraction layer for p-i-n structured perovskite solar cells.Organic solar cells using a high-molecular-weight benzodithiophene-benzothiadiazole copolymer with an efficiency of 9.4%.Side-chain engineering of benzodithiophene-fluorinated quinoxaline low-band-gap co-polymers for high-performance polymer solar cells.Isoindigo fluorination to enhance photovoltaic performance of donor-acceptor conjugated copolymers.Interface passivation and electron transport improvement of polymer solar cells through embedding a polyfluorene layer.In Situ Photocatalytically Heterostructured ZnO-Ag Nanoparticle Composites as Effective Cathode-Modifying Layers for Air-Processed Polymer Solar Cells.The effect of polymer solubilizing side-chains on solar cell stability.Alternative alcohol-soluble conjugated small molecule electrolytes for high-efficiency inverted polymer solar cells.An organosilane self-assembled monolayer incorporated into polymer solar cells enabling interfacial coherence to improve charge transport.3-Dimensional ZnO/CdS nanocomposite with high mobility as an efficient electron transport layer for inverted polymer solar cells.Comparison of the Impact of Zinc Vacancies on Charge Separation and Charge Transfer at ZnO/Sexithienyl and ZnO/Fullerene Interfaces.Elucidating the Role of Conjugated Polyelectrolyte Interlayers for High-Efficiency Organic Photovoltaics.Fully understanding the positive roles of plasmonic nanoparticles in ameliorating the efficiency of organic solar cells.From charge-transfer to a charge-separated state: a perspective from the real-time TDDFT excitonic dynamics.Amine-Based Interfacial Molecules for Inverted Polymer-Based Optoelectronic Devices.Hydrophilic Conjugated Polymers with Large Bandgaps and Deep-Lying HOMO Levels as an Efficient Cathode Interlayer in Inverted Polymer Solar Cells.Poly(N-vinylpyrrolidone)-decorated reduced graphene oxide with ZnO grown in situ as a cathode buffer layer for polymer solar cells.Donor-acceptor-type copolymers based on a naphtho[1,2-c:5,6-c]bis(1,2,5-thiadiazole) scaffold for high-efficiency polymer solar cells.Recent advances in polymer solar cells: realization of high device performance by incorporating water/alcohol-soluble conjugated polymers as electrode buffer layer.An easy and effective method to modulate molecular energy level of the polymer based on benzodithiophene for the application in polymer solar cells.Fluorinated Polymer Yields High Organic Solar Cell Performance for a Wide Range of MorphologiesDomain Purity, Miscibility, and Molecular Orientation at Donor/Acceptor Interfaces in High Performance Organic Solar Cells: Paths to Further Improvement
P2860
Q27304865-9E222136-A670-4A23-8463-DE3759881E3CQ34317962-F604E6CF-E4D4-4B20-A5E7-4C98EBD29D3EQ34417434-36466BC5-E26A-4EA4-AD7C-E9991802BD8DQ34965806-1F1E3F5D-3212-4F93-99DE-A38DC9EDD06EQ35913356-3A0DF743-8E15-4BA1-859C-1C7C410B90A7Q36379605-9DDB6BDB-D30A-46F0-BA99-98595E2BE8F3Q38343646-1B35E0CE-A76D-4686-B46C-CA78DF52F17FQ38628025-13C57C28-9B97-49EE-9CFB-E4CB1F6B628CQ38738887-1F96A0C2-F803-4C26-BCBE-59F413E712F9Q38758504-3082EFCE-1D15-4309-88AC-9E6A3AF7B672Q39152638-9B31E626-408A-495C-9DEB-4707AE8876CFQ41550509-E3A0514B-6CCC-4995-93FF-5AC731B68629Q45761239-52FBD705-97FC-4D0B-BF77-33053210ECD3Q46037254-4FC8F02B-35BE-456F-B975-7250109900ACQ46667723-1ECA1AF1-AF3E-4EB3-8DA2-CE666261E429Q46708624-39087F19-C05E-404F-84D3-10C64A0B544BQ46846659-A00834E0-AB92-4AA2-9E81-9F87832B8E2EQ47224983-65B9B84A-F741-4BCD-A07A-7866ED29650EQ47236238-84D92FB1-1BBA-496E-AAF9-A4D3C8FEE0A2Q47423747-AC024A8F-D147-4F6C-95C5-1A99A6782A60Q50450382-94201E68-6706-47E7-9E82-AD5DD0CF294CQ50468507-0CE0D4F6-F25B-4A1B-97DE-857083B4E036Q50857927-F5A4D00B-7316-414F-A6F8-2F4F8710F583Q50957956-540539BC-CE95-44EB-AFCE-7234C3633C12Q50989647-6ABB3940-B812-4F0F-9A45-141ED60FF56BQ51020816-0283CCBA-5A4C-436E-9375-0DB1C5474023Q51311322-11C7B58F-43B7-4F8B-8DC0-E362563460BBQ51372790-8970295C-ABD1-4BED-A70B-CE8389347392Q51652121-35FD082B-2301-47A0-970E-29E7F37625ACQ51727759-2300A16D-ADC8-4F84-8026-2028383FFC8BQ52991247-01AF10B1-14AA-4607-B8A7-E1C8DD158F0BQ53046027-B221E3B3-BDA2-4BEA-9307-653C5BF641DCQ53219431-3FC4B29B-71EC-4E59-BF2C-9896D9B3C3BFQ53238364-C4633104-47A8-43A0-BAAF-AAE8F0DEE442Q53404494-BD4E7B12-88A8-4BB8-AEF1-E0CCFBCB9EBFQ53572847-BC6A7050-E3AB-4937-AC5F-902506C13DA4Q53655113-B2AEF994-ED66-4769-98A5-A28B998313C0Q54426721-99D11716-325C-4DA3-B252-5626AFF4F654Q57426319-2A638288-91A5-4A07-A5E0-6E71E9B15C1AQ57426368-F1968550-E800-4D7C-9CED-3158C10497A5
P2860
Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
description
im Januar 2012 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2012
@uk
name
Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
@en
Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
@nl
type
label
Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
@en
Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
@nl
prefLabel
Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
@en
Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
@nl
P2093
P2860
P356
P1476
Inverted polymer solar cells with 8.4% efficiency by conjugated polyelectrolyte
@en
P2093
Chunhui Duan
Junbiao Peng
Tingbin Yang
Xiaowen Hu
Xiong Gong
P2860
P356
10.1039/C2EE22296E
P577
2012-01-01T00:00:00Z