Nome |
# |
CoAPO5 as a water oxidation catalyst and a light sensitizer, file e384c42e-1964-d4b2-e053-9f05fe0a1d67
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721
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Syngas Production from Electrochemical Reduction of CO2: Current Status and Prospective Implementation, file e384c42f-738a-d4b2-e053-9f05fe0a1d67
|
602
|
Comparison of photocatalytic and transport properties of TiO2 and ZnO nanostructures for solar-driven water splitting, file e384c42d-bd23-d4b2-e053-9f05fe0a1d67
|
597
|
Core-substituted naphthalenediimides anchored on BiVO4 for visible light-driven water splitting, file e384c42f-7389-d4b2-e053-9f05fe0a1d67
|
542
|
Electrochemical and impedance characterization of Microbial Fuel Cells based on 2D and 3D anodic electrodes working with seawater microorganisms under continuous operation, file e384c42d-cb11-d4b2-e053-9f05fe0a1d67
|
530
|
A new method for studying activity and reaction kinetics of photocatalytic water oxidation systems using a bubbling reactor, file e384c42f-033a-d4b2-e053-9f05fe0a1d67
|
494
|
Recent Advances in the BiVO4 Photocatalyst for Sun-Driven Water Oxidation: Top-Performing Photoanodes and Scale-Up Challenges, file e384c42f-6756-d4b2-e053-9f05fe0a1d67
|
433
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New Transparent Laser-Drilled Fluorine-doped Tin Oxide covered Quartz Electrodes for Photo-Electrochemical Water Splitting, file e384c42f-0338-d4b2-e053-9f05fe0a1d67
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414
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Evaluation of the charge transfer kinetics of spin-coated BiVO4 thin films for sun-driven water photoelectrolysis, file e384c42e-b6b5-d4b2-e053-9f05fe0a1d67
|
399
|
CoAPO5 as a water oxidation catalyst and a light sensitizer, file e384c42e-1965-d4b2-e053-9f05fe0a1d67
|
369
|
Photo-catalytic activity of BiVO4 thin film electrodes for solar-driven water splitting, file e384c42d-c54a-d4b2-e053-9f05fe0a1d67
|
332
|
Spin-Coated vs. Electrodeposited Mn Oxide Films as Water Oxidation Catalysts, file e384c42e-d402-d4b2-e053-9f05fe0a1d67
|
253
|
Electro-oxidation of phenol over electrodeposited MnOx nanostructures and the role of a TiO2 nanotubes interlayer, file e384c42f-35ff-d4b2-e053-9f05fe0a1d67
|
246
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A model for electrode effects based on adsorption theory, file e384c42d-c3ef-d4b2-e053-9f05fe0a1d67
|
242
|
Spin-Coated vs. Electrodeposited Mn Oxide Films as Water Oxidation Catalysts, file e384c42e-d403-d4b2-e053-9f05fe0a1d67
|
234
|
Hydrodynamics and Oxygen Bubble Characterization of Catalytic Cells Used in Artificial Photosynthesis by Means of CFD, file e384c42f-7a1e-d4b2-e053-9f05fe0a1d67
|
229
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CARBON DIOXIDE CAPTURE AND ELECTROCHEMICAL CONVERSION WITH IONIC LIQUIDS, file e384c433-9a1a-d4b2-e053-9f05fe0a1d67
|
178
|
Environmental issues regarding CO2 and recent strategies for alternative fuels through photocatalytic reduction with titania-based materials, file e384c42f-a649-d4b2-e053-9f05fe0a1d67
|
147
|
Sonophotocatalytic degradation mechanisms of Rhodamine B dye via radicals generation by micro- and nano-particles of ZnO, file e384c430-787a-d4b2-e053-9f05fe0a1d67
|
84
|
Strategies for improving GDE performance by a uniform dispersion of catalyst nanoparticles and an optimal Nafion content, file e384c433-7b8c-d4b2-e053-9f05fe0a1d67
|
56
|
Chainlike Mesoporous SnO2 as a Well-Performing Catalyst for Electrochemical CO2 Reduction, file e384c431-32f0-d4b2-e053-9f05fe0a1d67
|
46
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Syngas Production from Electrochemical Reduction of CO2: Current Status and Prospective Implementation, file e384c42f-7678-d4b2-e053-9f05fe0a1d67
|
45
|
Chainlike Mesoporous SnO2 as a Well-Performing Catalyst for Electrochemical CO2 Reduction, file e384c431-531e-d4b2-e053-9f05fe0a1d67
|
45
|
Investigation of Gas Diffusion Electrode systems for the electrochemical CO2 conversion, file e384c433-989e-d4b2-e053-9f05fe0a1d67
|
45
|
Facile and scalable synthesis of Cu2O-SnO2 catalyst for the photoelectrochemical CO2 conversion, file e384c433-887e-d4b2-e053-9f05fe0a1d67
|
44
|
Insights into the sunlight-driven water oxidation by Ce and Er-doped ZrO2, file e384c430-8c8c-d4b2-e053-9f05fe0a1d67
|
37
|
Microwave-Assisted Synthesis of Copper-Based Electrocatalysts for Converting Carbon Dioxide to Tunable Syngas, file e384c432-adc4-d4b2-e053-9f05fe0a1d67
|
36
|
Catalytic vs electrocatalytic reduction of CO2 to added-value products, file e384c432-2e6f-d4b2-e053-9f05fe0a1d67
|
35
|
Development of Cu-based hybrid catalysts for the electrocatalytic CO2 reduction to added value products, file e384c432-631d-d4b2-e053-9f05fe0a1d67
|
35
|
Electrochemical CO2 conversion in Ionic Liquid-based electrolytes, file a9d55b98-52c5-41c7-bd86-a778a933e603
|
32
|
Enhanced electrochemical oxidation of phenol over manganese oxides under mild wet air oxidation conditions, file e384c430-cf81-d4b2-e053-9f05fe0a1d67
|
32
|
Understanding the role of imidazolium-based ionic liquids in the electrochemical CO2 reduction reaction: an experimental and theoretical study, file eb415dff-3d66-47d7-8626-5e2da6c6e41c
|
30
|
Core-substituted naphthalenediimides anchored on BiVO4 for visible light-driven water splitting, file e384c42f-75d6-d4b2-e053-9f05fe0a1d67
|
29
|
Non-monotonic dependence of the current density on the thickness of the photoactive layer, file e384c42f-6812-d4b2-e053-9f05fe0a1d67
|
26
|
Application of Reverse Micelle Sol–Gel Synthesis for Bulk Doping and Heteroatoms Surface Enrichment in Mo-Doped TiO2 Nanoparticles, file e384c431-25da-d4b2-e053-9f05fe0a1d67
|
26
|
IONIC LIQUIDS FOR CAPTURE AND ELECTROCHEMICAL CONVERSION OF CO2 - ISE 2021, file 33de54d7-2519-4404-a147-e0a2397cd414
|
25
|
Catalytic vs. electrocatalytic reduction of CO2 to added-value products, file e384c432-383a-d4b2-e053-9f05fe0a1d67
|
25
|
Optimization of Cu-based catalyst for the electrocatalytic reduction of CO2 to fuels, file e384c432-631e-d4b2-e053-9f05fe0a1d67
|
25
|
IONIC LIQUIDS FOR CAPTURE AND ELECTROCHEMICAL CONVERSION OF CO2 - CIS 2021, file d6a5d1c9-058a-4750-b588-108785da081e
|
24
|
Electrochemical and impedance characterization of Microbial Fuel Cells based on 2D and 3D anodic electrodes working with seawater microorganisms under continuous operation, file e384c42d-cb12-d4b2-e053-9f05fe0a1d67
|
24
|
Comparison of photocatalytic and transport properties of TiO2 and ZnO nanostructures for solar-driven water splitting, file e384c42d-bd25-d4b2-e053-9f05fe0a1d67
|
22
|
Enhanced CO2 Absorption in Organic Solutions of Biobased Ionic Liquids, file e384c431-7a0d-d4b2-e053-9f05fe0a1d67
|
21
|
FACILE AND SCALABLE SYNTHESIS OF CU2O-SNO2 CATALYST FOR THE PHOTOELECTROCHEMICAL CO2 CONVERSION, file 00bbfdf1-0aca-4dfa-b016-9b8ada114c5d
|
20
|
CuZnAl-oxide nanopyramidal mesoporous materials for the electrocatalytic CO2 reduction to syngas: Tuning of H2/CO ratio, file e384c434-9112-d4b2-e053-9f05fe0a1d67
|
19
|
Addressing the stability challenges of Gas Diffusion Electrodes in the presence of ILs-based solutions for the continuous Electrochemical Conversion of CO2, file 685d8b88-03b8-444e-a938-650c289e38cf
|
18
|
CO2 Conversion to Alcohols over Cu/ZnO Catalysts: Prospective Synergies between Electrocatalytic and Thermocatalytic Routes, file e384c434-70b8-d4b2-e053-9f05fe0a1d67
|
18
|
Facile synthesis of cubic cuprous oxide for electrochemical reduction of carbon dioxide, file e384c432-d825-d4b2-e053-9f05fe0a1d67
|
17
|
ZnO Materials as Effective Anodes for the Photoelectrochemical Regeneration of Enzymatically Active NAD+, file e384c433-048e-d4b2-e053-9f05fe0a1d67
|
17
|
Addressing the stability challenges of Gas Diffusion Electrodes in the presence of ILs-based solutions for the continuous Electrochemical Reduction of CO2, file 6b3bbf9b-97e1-4c50-919b-145befc92aa8
|
16
|
Identifying Promising Ionic Liquids for Electrochemical CO2 Reduction, file 70a6d8d3-d3ce-4f12-a368-d9c7ea702e42
|
16
|
Optimization of BiVO4 photoelectrodes made by electrodeposition for sun-driven water oxidation, file e384c431-452d-d4b2-e053-9f05fe0a1d67
|
16
|
Investigation of gas diffusion electrode systems for the electrochemical CO2 conversion, file e384c434-7006-d4b2-e053-9f05fe0a1d67
|
16
|
Electrocatalytic CO2 Reduction on CuZnAl-based Oxide Catalysts: Tuning of the H2/CO Ratio, file e384c434-c389-d4b2-e053-9f05fe0a1d67
|
16
|
Enhanced CO2 Absorption in Organic Solutions of Biobased Ionic Liquids, file e384c431-b62c-d4b2-e053-9f05fe0a1d67
|
15
|
Influence of sonication on co-precipitation synthesis of copper oxide catalyst for CO2 electroreduction, file e384c433-930e-d4b2-e053-9f05fe0a1d67
|
13
|
CO2 valorisation towards alcohols by Cu-based electrocatalysts: challenges and perspectives, file e384c432-f0e2-d4b2-e053-9f05fe0a1d67
|
12
|
Facile and scalable synthesis of Cu2O-SnO2 catalyst for the photoelectrochemical CO2 conversion, file 9a9ebc4e-84c5-4c76-8c3a-20b70d0c5dbe
|
11
|
Investigation of gas diffusion electrode systems for the electrochemical CO2 conversion, file e384c434-8f99-d4b2-e053-9f05fe0a1d67
|
11
|
Enhanced CO2 Absorption in Organic Solutions of Biobased Ionic Liquids, file e384c431-7f95-d4b2-e053-9f05fe0a1d67
|
10
|
Insights on the surface chemistry of BiVO4 photoelectrodes and the role of Al overlayers on its water oxidation activity, file e384c432-64b0-d4b2-e053-9f05fe0a1d67
|
10
|
Solar-driven CO2 reduction catalysed by hybrid supramolecular photocathodes and enhanced by ionic liquids, file 537326f1-1d3a-4cc5-be3f-d4e17c171505
|
9
|
FACILE AND SCALABLE SYNTHESIS OF CU2O-SNO2 CATALYST FOR THE PHOTOELECTROCHEMICAL CO2 CONVERSION, file 8bcb77ea-2ccc-4f2b-9fcb-a2687f667b03
|
9
|
AgCu Bimetallic Electrocatalysts for the Reduction of Biomass-Derived Compounds, file e384c434-6a88-d4b2-e053-9f05fe0a1d67
|
9
|
Catalytic vs electrocatalytic CO2 reduction to added-value products, file e384c434-e4d3-d4b2-e053-9f05fe0a1d67
|
9
|
Identifying Promising Ionic Liquids for Electrochemical CO2 Reduction, file 8758d524-7d95-4a77-8b45-d5ef3c12273d
|
8
|
Insights on the surface chemistry of BiVO4 photoelectrodes and the role of Al overlayers on its water oxidation activity, file e384c432-4522-d4b2-e053-9f05fe0a1d67
|
8
|
CuZnAl-oxide nanopyramidal mesoporous materials for the electrocatalytic CO2 reduction to syngas: Tuning of H2/CO ratio, file e384c434-6ba1-d4b2-e053-9f05fe0a1d67
|
8
|
Catalytic vs. electrocatalytic reduction of CO2 to added-value products, file e384c432-5e08-d4b2-e053-9f05fe0a1d67
|
7
|
Ultrasound-assisted synthesis of copper-based catalysts for the electrocatalytic CO2 reduction: Effect of ultrasound irradiation, precursor concentration and calcination temperature, file 79264390-f7b8-47fb-80a5-1dbbf7a15f45
|
6
|
Facile and scalable synthesis of Cu2O-SnO2 catalyst for the photoelectrochemical CO2 conversion, file 80fb525e-e4f0-4026-b92b-f3af86b8b158
|
6
|
Facile and scalable synthesis of
Cu2O-SnO2 catalyst for the
photoelectrochemical CO2 conversion, file b0f96354-1e98-4e51-a6f7-dbbd744577fd
|
6
|
Visible Light-Driven Catalysts for Water Oxidation: Towards Solar Fuel Biorefineries, file e384c431-ccd6-d4b2-e053-9f05fe0a1d67
|
6
|
CO2 Conversion to Alcohols over Cu/ZnO Catalysts: Prospective Synergies between Electrocatalytic and Thermocatalytic Routes, file e384c434-70b9-d4b2-e053-9f05fe0a1d67
|
5
|
Insights on the role of β-Bi2O3/Bi5O7NO3 heterostructures synthesized by a scalable solid-state method for the sunlight-driven photocatalytic degradation of dyes, file e384c42f-deb1-d4b2-e053-9f05fe0a1d67
|
4
|
Photo/electrocatalytic hydrogen exploitation for CO2 reduction toward solar fuels production, file e384c431-b87f-d4b2-e053-9f05fe0a1d67
|
4
|
Photo/electrocatalytic hydrogen exploitation for CO2 reduction toward solar fuels production, file e384c431-c028-d4b2-e053-9f05fe0a1d67
|
4
|
Piezo- and Photocatalytic Activity of Ferroelectric ZnO:Sb Thin Films for the Efficient Degradation of Rhodamine-β dye Pollutant, file e384c432-19fd-d4b2-e053-9f05fe0a1d67
|
4
|
Facile synthesis of cubic cuprous oxide for electrochemical reduction of carbon dioxide, file e384c432-adc2-d4b2-e053-9f05fe0a1d67
|
4
|
Microwave-Assisted Synthesis of Copper-Based Electrocatalysts for Converting Carbon Dioxide to Tunable Syngas, file e384c432-adc3-d4b2-e053-9f05fe0a1d67
|
4
|
ZnO Materials as Effective Anodes for the Photoelectrochemical Regeneration of Enzymatically Active NAD+, file e384c433-048f-d4b2-e053-9f05fe0a1d67
|
4
|
null, file 26b6b7f5-9ccf-48f8-adb4-9080e104d1a8
|
3
|
Solar H2 production systems: current status and prospective applications, file 34f53a94-af31-467f-af9a-5fe84203f3b6
|
3
|
Facile and scalable synthesis of Cu2O-SnO2 catalyst for the photoelectrochemical CO2 conversion, file 4abbd448-47bf-4836-84dd-fba02e3fc9f3
|
3
|
Modeling Surface Reconstruction of Cu-based catalysts under Electrochemical CO2 Reduction Conditions, file 89ce231c-8fbf-4583-aea9-5e373b795cef
|
3
|
Hydrodynamics and Oxygen Bubble Characterization of Catalytic Cells Used in Artificial Photosynthesis by Means of CFD, file e384c42f-7a20-d4b2-e053-9f05fe0a1d67
|
3
|
Role of the electrode morphology on the optimal thickness of BiVO4 anodes for photoelectrochemical water splitting cells, file e384c42f-89d9-d4b2-e053-9f05fe0a1d67
|
3
|
Single BiFeO3 and mixed BiFeO3/Fe2O3/Bi2Fe4O9 ferromagnetic photocatalysts for solar light driven water oxidation and dye pollutants degradation, file e384c42f-f651-d4b2-e053-9f05fe0a1d67
|
3
|
Visible Light-Driven Catalysts for Water Oxidation: Towards Solar Fuel Biorefineries, file e384c431-ac81-d4b2-e053-9f05fe0a1d67
|
3
|
Piezo- and Photocatalytic Activity of Ferroelectric ZnO:Sb Thin Films for the Efficient Degradation of Rhodamine-β dye Pollutant, file e384c432-1975-d4b2-e053-9f05fe0a1d67
|
3
|
Electrochemical Measurements as Screening Method for Water Oxidation Catalyst, file e384c432-258b-d4b2-e053-9f05fe0a1d67
|
3
|
AgCu Bimetallic Electrocatalysts for the Reduction of Biomass-Derived Compounds, file e384c434-8e71-d4b2-e053-9f05fe0a1d67
|
3
|
Hierarchical TiN-Supported TsFDH Nanobiocatalyst for CO2 Reduction to Formate, file e384c434-c255-d4b2-e053-9f05fe0a1d67
|
3
|
Modeling Surface Reconstruction of Cu-based catalysts under Electrochemical CO2 Reduction Conditions, file 18bbc9d1-ef84-421b-8f25-fdcdb772f537
|
2
|
Covalent Immobilization of Dehydrogenases on Carbon Felt for Reusable Anodes with Effective Electrochemical Cofactor Regeneration, file 410372ff-502c-40bd-bb64-fc3c81ac85e1
|
2
|
Understanding the role of imidazolium-based ionic liquids in the electrochemical CO2 reduction reaction, file 66729487-d883-41ff-a2d9-1d11571e50af
|
2
|
Hydrodynamics and Oxygen Bubble Characterization of Catalytic Cells Used in Artificial Photosynthesis by Means of CFD, file e384c42f-7a1f-d4b2-e053-9f05fe0a1d67
|
2
|
Testing Novel Water Oxidation Catalysts for Solar Fuels Production, file e384c431-75b7-d4b2-e053-9f05fe0a1d67
|
2
|
Preface, file e384c431-dce2-d4b2-e053-9f05fe0a1d67
|
2
|
Sacrificial Oxidants as a Means to Study the Catalytic Activity of Water Oxidation Catalysts, file e384c432-12ad-d4b2-e053-9f05fe0a1d67
|
2
|
Conclusions, file e384c432-1563-d4b2-e053-9f05fe0a1d67
|
2
|
Totale |
8.258 |