about
Nanocoaxes for optical and electronic devicesSelf-catalyzed Growth of InAs Nanowires on InP SubstrateGrowth of Well-Aligned InN Nanorods on Amorphous Glass SubstratesFundamental limit of nanophotonic light trapping in solar cellsPlatinum-free counter electrode comprised of metal-organic-framework (MOF)-derived cobalt sulfide nanoparticles for efficient dye-sensitized solar cells (DSSCs)Tip-enhanced Raman imaging and nano spectroscopy of etched silicon nanowires.Highly-ordered silicon inverted nanocone arrays with broadband light antireflectanceProbing photo-carrier collection efficiencies of individual silicon nanowire diodes on a wafer substrate.Structural modulation of silicon nanowires by combining a high gas flow rate with metal catalysts.Semiconductor Nanowire Light-Emitting Diodes Grown on Metal: A Direction Toward Large-Scale Fabrication of Nanowire Devices.A comparison of light-harvesting performance of silicon nanocones and nanowires for radial-junction solar cellsCore-shell silicon nanowire solar cells.A High-Efficiency Si Nanowire Array/Perovskite Hybrid Solar Cell.Morphology Controlled Fabrication of InN Nanowires on Brass Substrates.Small-sized silicon nanoparticles: new nanolights and nanocatalysts.Assembly of one dimensional inorganic nanostructures into functional 2D and 3D architectures. Synthesis, arrangement and functionality.Silicon nanowires for biosensing, energy storage, and conversion.Light management for photovoltaics using high-index nanostructures.Semiconductor and metallic core-shell nanostructures: synthesis and applications in solar cells and catalysis.Synchrotron soft X-ray absorption spectroscopy study of carbon and silicon nanostructures for energy applications.Review of one-dimensional and two-dimensional nanostructured materials for hydrogen generation.Low bandgap semiconducting polymers for polymeric photovoltaics.Shallow V-Shape Nanostructured Pit Arrays in Germanium Using Aqua Regia Electroless Chemical Etching.Semiconductor nanowires directly grown on graphene--towards wafer scale transferable nanowire arrays with improved electrical contact.Flexible, transparent contacts for inorganic nanostructures and thin films.Enhanced broadband and omnidirectional performance of Cu(In,Ga)Se2 solar cells with ZnO functional nanotree arrays.Dandelion-shaped nanostructures for enhancing omnidirectional photovoltaic performance.Flexible, polymer-supported, Si wire array photoelectrodes.Addressing carrier extraction from optically-optimized nanopillar arrays for thin-film photovoltaics.Incorporation of a self-aligned selective emitter to realize highly efficient (12.8%) Si nanowire solar cells.Electrical properties of flexible multi-channel Si nanowire field-effect transistors depending on the number of Si nanowires.Optical and Electrical Characteristics of Hybrid ZnO Nanowire/a-Si:H Solar Cells on Flexible Substrates under Mechanical Bending.Fabrication of silicon nanowire arrays by macroscopic galvanic cell-driven metal catalyzed electroless etching in aerated HF solution.The effects of shell layer morphology and processing on the electrical and photovoltaic properties of silicon nanowire radial p+ - n+ junctions.Thermo-compressive transfer printing for facile alignment and robust device integration of nanowires.Photoelectric Properties of Electrodeposited Copper(I) Oxide NanowiresProgress in Indium Gallium Nitride Materials for Solar Photovoltaic Energy ConversionConformal Coating of Conductive ZnO:Al Films as Transparent Electrodes on High Aspect Ratio Si MicrorodsNi-catalyzed growth of silicon wire arrays for a Schottky diodeHigh-performance Schottky solar cells using ZrS2 nanobelt networks
P2860
Q28650726-3CA3678F-9337-41D6-80AC-62CDA44BBC60Q28817278-CB109025-56A6-480E-BFF6-6DCFE99006E4Q28833423-1165A05D-3358-4BD4-8A43-06F7DA3226F7Q34199981-0D074160-F645-4A83-990A-11B6A1E4DB03Q34477836-7E877FE9-D189-4431-BCF4-CB52290D18F9Q35000450-F8565D1B-C526-496A-BC8D-17A87D3097A0Q35003066-30439A04-41BE-47E9-9D7F-2B747C1EB611Q35169034-B4ABE146-40C8-4551-BDB1-52B520DAB5DDQ35661587-03481F86-AEF5-46A2-A178-22FE78EE1E0AQ35755476-8D43DFBA-255D-452C-8044-9F21170A9EC4Q35784677-66CD0045-A264-450F-93B3-940FD90A0CC5Q36715318-4BAB4E08-A06F-42E1-ABC5-45A35102B15EQ37562253-C2CCBA1E-45EF-4C7B-9CE9-2CD515B46FBBQ37594436-71BDEAD9-04E1-4334-86FE-AB48B85EEE01Q37821315-79A71B07-1225-4A57-BC0A-336136EFA722Q38020767-BA32AEE1-064A-4704-B8CF-209FF8219F4AQ38119416-4203CBD9-2724-42A3-970A-50240DFBA1DFQ38206051-68C032D6-44F7-4EA5-8A92-747950EC8CF3Q38231986-284D936E-DE72-4153-9CD3-5C529AB73B3FQ38247639-1A9455A1-10DE-488B-9630-1798833D82A5Q38299068-A344607D-E10C-4D46-BE73-99ED54F59EE5Q38628025-742FF499-BF4E-4BA4-BDCC-D8ECA181264AQ41574705-D313D5F6-904C-4D9E-9FA4-2B1B1BF68D24Q43465674-423B6E66-E86E-4A2D-98B5-E17C4C211EDAQ43807312-7F51C596-790C-4D77-AB58-3720CAEE0FF8Q44060541-5C6CA353-01B6-4486-8652-D28C9D14D4B4Q44370469-D6AFBFDB-3B9C-4AED-B05A-57ECC9BAE612Q46100335-46CC2B70-1F37-4CDD-8869-13BD472FDFFFQ47585191-64F43A63-D37D-45DB-AF01-2678101A915DQ50223584-3F4DBA5C-6156-4FC6-93E3-B660D08BFDCFQ51344350-38292B83-68C2-4156-B460-01B8A9898ABEQ51406936-A6E59B20-6EF8-4F57-BB86-770BCCE5B32EQ51767742-7C7576AE-2558-4B83-A97E-72545179DF37Q53227611-B8B92937-2336-4677-9999-7BF500F2513EQ53378098-9B8A11E7-8007-42F8-9766-558B4C4DB11CQ56453495-9F2FE7FD-21E8-4657-B940-15C247CB282FQ57535506-7D856CA8-BA84-4E7C-B3E6-ACFA88EA92F6Q58198954-E3C8D72A-A584-462D-9977-1D4375A44188Q58198973-1D07FF98-904A-41B4-9A05-CAA4EA7F0EC4Q58202415-D71F314D-F1EA-44B2-8CDB-E1D326CFB9DC
P2860
description
im Dezember 2007 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в грудні 2007
@uk
name
Silicon nanowire solar cells
@en
Silicon nanowire solar cells
@nl
type
label
Silicon nanowire solar cells
@en
Silicon nanowire solar cells
@nl
prefLabel
Silicon nanowire solar cells
@en
Silicon nanowire solar cells
@nl
P2093
P2860
P356
P1476
Silicon nanowire solar cells
@en
P2093
B. A. Korevaar
J. Fronheiser
L. Tsakalakos
P2860
P304
P356
10.1063/1.2821113
P407
P577
2007-12-03T00:00:00Z