Metal oxide nanoparticles as an electron-transport layer in high-performance and stable inverted polymer solar cells.
about
A polymer tandem solar cell with 10.6% power conversion efficiency.19.2% Efficient InP Heterojunction Solar Cell with Electron-Selective TiO2 Contact.A soluble ladder-conjugated star-shaped oligomer composed of four perylene diimide branches and a fluorene core: synthesis and properties.Downscaling the Sample Thickness to Sub-Micrometers by Employing Organic Photovoltaic Materials as a Charge-Generation Layer in the Time-of-Flight Measurement.High-performance ternary blend polymer solar cells involving both energy transfer and hole relay processes.Low Work-function Poly(3,4-ethylenedioxylenethiophene): Poly(styrene sulfonate) as Electron-transport Layer for High-efficient and Stable Polymer Solar Cells.Interfacial Materials for Organic Solar Cells: Recent Advances and PerspectivesNanochemistry and nanomaterials for photovoltaics.Prospects of Graphene as a Potential Carrier-Transport Material in Third-Generation Solar Cells.Colloidal metal oxide nanocrystals as charge transporting layers for solution-processed light-emitting diodes and solar cells.Understanding low bandgap polymer PTB7 and optimizing polymer solar cells based on it.'Inorganics-in-organics': recent developments and outlook for 4G polymer solar cells.Hybrid graphene-metal oxide solution processed electron transport layers for large area high-performance organic photovoltaics.Incorporation of a Metal Oxide Interlayer using a Virus-Templated Assembly for Synthesis of Graphene-Electrode-Based Organic Photovoltaics.Extended conjugated donor-acceptor molecules with E-(1,2-difluorovinyl) and diketopyrrolopyrrole (DPP) moieties toward high-performance ambipolar organic semiconductors.Bandgap engineering and shape control of colloidal Cd(x)Zn(1-x)O nanocrystals.10.2% power conversion efficiency polymer tandem solar cells consisting of two identical sub-cells.Graphene quantum dots as the hole transport layer material for high-performance organic solar cells.Pure Formamidinium-Based Perovskite Light-Emitting Diodes with High Efficiency and Low Driving Voltage.Efficient solution-processed small-molecule solar cells with inverted structure.Transferable graphene oxide by stamping nanotechnology: electron-transport layer for efficient bulk-heterojunction solar cells.Planar-Structure Perovskite Solar Cells with Efficiency beyond 21.Enhancement of Open-Circuit Voltage by Using the 58-π Silylmethyl Fullerenes in Small-Molecule Organic Solar Cells.3-Dimensional ZnO/CdS nanocomposite with high mobility as an efficient electron transport layer for inverted polymer solar cells.Amine-Based Interfacial Molecules for Inverted Polymer-Based Optoelectronic Devices.High-efficiency inverted organic solar cells with polyethylene oxide-modified Zn-doped TiO2 as an interfacial electron transport layer.Characterization of ALD Processed Gallium Doped TiO2 Hole Blocking Layer in an Inverted Organic Solar CellReducing burn-in voltage loss in polymer solar cells by increasing the polymer crystallinityRoom temperature-processed inverted organic solar cells using high working-pressure-sputtered ZnO filmsLow-Temperature Combustion-Synthesized Nickel Oxide Thin Films as Hole-Transport Interlayers for Solution-Processed Optoelectronic DevicesEnhanced charge extraction in organic solar cells through electron accumulation effects induced by metal nanoparticlesPlasmonic Electrically Functionalized TiO2for High-Performance Organic Solar CellsElectrophoretic deposited oxide thin films as charge transporting interlayers for solution-processed optoelectronic devices: the case of ZnO nanocrystalsEthanedithiol Treatment of Solution-Processed ZnO Thin Films: Controlling the Intragap States of Electron Transporting Interlayers for Efficient and Stable Inverted Organic PhotovoltaicsHighly efficient and thermally stable fullerene-free organic solar cells based on a small molecule donor and acceptorA facile approach to alleviate photochemical degradation in high efficiency polymer solar cellsEffect of π-conjugated bridges of TPD-based medium bandgap conjugated copolymers for efficient tandem organic photovoltaic cellsImproving Structural Order for a High-Performance Diketopyrrolopyrrole-Based Polymer Solar Cell with a Thick Active LayerInvestigation on Thermal Degradation Process of Polymer Solar Cells Based on Blend of PBDTTT-C andPC70BMStable Inverted Low-Bandgap Polymer Solar Cells with Aqueous Solution Processed Low-Temperature ZnO Buffer Layers
P2860
Q34326461-857C1C7E-D20B-43E4-91FE-BEDDD6F6EF4EQ35031783-0617ACA9-9571-4F12-94BC-84A130D4B0D1Q35197193-A16236C9-7757-423F-B392-966F027ABD32Q35636080-FBE1717C-9B5C-415C-AC30-CF7C4416F714Q35746586-20605507-BA43-481C-87C0-2CE20EE6EFFDQ35913356-C55FB788-1B71-451C-8885-30F91FBAC2DFQ37345634-D68D9945-AB4E-469C-B3E7-BE94773CB2F4Q38122654-E3B2D90B-C1CF-4574-BC8F-6D5D8A5262BBQ38713480-6D4A7162-0823-463A-9BC1-6DC1C086CCB9Q38752383-32B50F0C-820F-4BF1-8F36-5A28A336945EQ39221000-5C60AC9C-BCBC-4124-8259-4F445B251CFAQ39375296-141BB370-9D1D-4C69-B44E-BCFAA8782E08Q42121586-F45B5727-066B-4011-8347-BFCB933C7248Q42152647-C9CD8FA6-3A53-4BFC-89EB-47910DB99922Q43594997-0E013892-EE84-4926-8E89-47B6E8AE5070Q44297380-597FB1FF-D168-4DE4-BAB6-ACD7489DACABQ45953301-0EFF0298-1525-4FDF-8E04-8E6E53986329Q46141641-C3B2AA37-16D0-4685-A2F2-AE543EC74D7DQ46159825-A26798B7-376A-4F4F-9AC9-FA0426583B3DQ46708624-922233C0-452A-46F2-B39D-10B6D439EA43Q46877215-C8A3B1D4-1D07-4D07-A45C-A6CBF1474F83Q47433474-F963B672-8106-43BF-9D27-649970AC907AQ48247948-7E3BC6E1-6200-4CF4-AA40-95435CA39A76Q51372790-897EB5DF-7FC5-483D-A2F0-063CBD5F5FE5Q53219431-F01183A2-E2A5-4477-80B1-C95C3CFECEF0Q53514513-3B7CA9EC-E393-4C3A-ABBF-A9D094D21E32Q56562399-50892C47-918B-4E3E-85F7-323C99131ECFQ57563181-EFE1EBEA-BA54-4197-9569-05BD80C462FEQ57768672-A724852B-ACCD-4F4D-A099-3F3D24F65C6EQ57798232-8AD42A13-2230-4D65-8E25-10803AF188ABQ57967190-4BC198C2-58EC-4C21-ADAB-EE8E9B90505AQ57967204-F2A121FF-2B29-4715-A073-739CCDE03B9AQ57967921-7DC6E365-6B7A-407E-8BCA-B9EDB7A84B1CQ57967933-42EE1955-F69E-4A8B-B4D8-2B608A10B7B9Q58001161-66FDACBB-A30D-4546-BA8C-BFBEE57313CEQ58036511-87E9B663-B6E7-49F1-90F8-52CBC68C817AQ58072567-4F8AB142-87AD-4655-A008-529F8BA7B0B1Q58172988-847D4435-778C-4A42-AB74-26FABB09FC55Q59044991-E45D71DE-84DE-4CE6-9ACC-C3801B1F2F06Q59124740-13D56CB0-D52B-4B3A-8D7E-369559B3AAD8
P2860
Metal oxide nanoparticles as an electron-transport layer in high-performance and stable inverted polymer solar cells.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
2012年學術文章
@zh
2012年學術文章
@zh-hant
name
Metal oxide nanoparticles as a ...... inverted polymer solar cells.
@en
Metal oxide nanoparticles as a ...... inverted polymer solar cells.
@nl
type
label
Metal oxide nanoparticles as a ...... inverted polymer solar cells.
@en
Metal oxide nanoparticles as a ...... inverted polymer solar cells.
@nl
prefLabel
Metal oxide nanoparticles as a ...... inverted polymer solar cells.
@en
Metal oxide nanoparticles as a ...... inverted polymer solar cells.
@nl
P2093
P2860
P50
P356
P1433
P1476
Metal oxide nanoparticles as a ...... inverted polymer solar cells.
@en
P2093
Chun-Chao Chen
Hae Jung Son
Hsin-Sheng Duan
Letian Dou
Seiichiro Murase
P2860
P304
P356
10.1002/ADMA.201201958
P407
P577
2012-07-26T00:00:00Z