Renewable fuels from concentrated solar power: towards practical artificial photosynthesis
about
A miniature solar device for overall water splitting consisting of series-connected spherical silicon solar cells.Solar water splitting by photovoltaic-electrolysis with a solar-to-hydrogen efficiency over 30News Feature: Liquid sunlightNano-sized Mn oxide/agglomerated silsesquioxane composite as a good catalyst for water oxidation.Electrocatalytic Water Oxidation Promoted by 3 D Nanoarchitectured Turbostratic δ-MnOx on Carbon Nanotubes.Modeling, Simulation, and Implementation of Solar-Driven Water-Splitting Devices.Towards Versatile and Sustainable Hydrogen Production through Electrocatalytic Water Splitting: Electrolyte Engineering.Floating rGO-based black membranes for solar driven sterilization.Control of electro-chemical processes using energy harvesting materials and devices.Harnessing sunlight without a photosensitizer for highly efficient consecutive [3+2]/[4+2] annulation to synthesize fused benzobicyclic skeletons.Strategies for Efficient Charge Separation and Transfer in Artificial Photosynthesis of Solar Fuels.Tuning Thiophene-Based Phenothiazines for Stable Photocatalytic Hydrogen Production.Electrocatalytic CO2 Reduction to Formate at Low Overpotentials on Electrodeposited Pd Films: Stabilized Performance by Suppression of CO Formation.Introductory lecture: sunlight-driven water splitting and carbon dioxide reduction by heterogeneous semiconductor systems as key processes in artificial photosynthesis.Bubble-Sheet-Like Interface Design with an Ultrastable Solid Electrolyte Layer for High-Performance Dual-Ion Batteries.Across the Board: Angela Dibenedetto.Efficient solar-driven electrochemical CO2 reduction to hydrocarbons and oxygenatesA highly active hydrogen evolution electrocatalyst based on a cobalt–nickel sulfide composite electrode
P2860
Q27320944-9BA067F0-0124-4BAB-9550-51FC0E774F01Q28596465-B5A44AF1-09DC-4CAE-ADAC-14EC51F18F5CQ28603315-25FE5C78-72D1-4D76-9328-4D00589F5F30Q31043117-9F5ED27D-A4D1-4433-8DFE-FBA4497D8679Q36414267-F9A67E92-13C9-47C0-9F00-EAA467237D61Q38909329-EB3F6525-266C-4CF1-B9B3-77338C350302Q39041493-56C5BE74-9B2D-4344-BB3F-2FC5C4FF6CB2Q47282675-53E05E66-8655-4292-8E96-01E3DEA52E3BQ47361630-4DB1F25C-3979-43B7-B0F6-F38676F188F6Q47671813-81F63459-D12B-4BAA-8175-19C92B507392Q47811280-C08781B5-1154-4227-8619-166F5B29504DQ48097766-B1511444-1C51-47FD-A500-50BC8B4DC65EQ48299679-DCF202CF-96FC-4B1C-8788-9887D06559DAQ48506175-D231A42E-21C3-4136-AE07-3EA6800FEE1DQ48824653-BE523A88-E1D5-4FED-981B-5710B7924F01Q50279091-36A31A61-E9C9-4F9C-8907-C7D38FF45B48Q57623872-297AA1D6-2EFE-4ED5-AB36-90203326E9CBQ57634371-EBBE43FA-0CB4-486C-837C-14AC7AB19556
P2860
Renewable fuels from concentrated solar power: towards practical artificial photosynthesis
description
im Januar 2015 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2015
@uk
name
Renewable fuels from concentra ...... ical artificial photosynthesis
@en
Renewable fuels from concentra ...... ical artificial photosynthesis
@nl
type
label
Renewable fuels from concentra ...... ical artificial photosynthesis
@en
Renewable fuels from concentra ...... ical artificial photosynthesis
@nl
prefLabel
Renewable fuels from concentra ...... ical artificial photosynthesis
@en
Renewable fuels from concentra ...... ical artificial photosynthesis
@nl
P2093
P2860
P356
P1476
Renewable fuels from concentra ...... ical artificial photosynthesis
@en
P2093
Douglas R. MacFarlane
Leone Spiccia
Mathias Wiechen
Shannon A. Bonke
P2860
P304
P356
10.1039/C5EE02214B
P577
2015-01-01T00:00:00Z