| Nome |
# |
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Economics of CO2 Utilization: A Critical Analysis, file de3e52b3-954c-762d-e053-3705fe0a30e0
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296
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The 2020 plasma catalysis roadmap, file de3e52b3-74b9-762d-e053-3705fe0a30e0
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229
|
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Enhancing N2 Fixation Activity by Converting Ti3 C2 MXenes Nanosheets to Nanoribbons, file de3e52b3-8d67-762d-e053-3705fe0a30e0
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224
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Multifunctional HDO/Selective Cracking Ni/HBEA Catalysts to produce Jet Fuel and Diesel from Bio-oils, file de3e52b3-3553-762d-e053-3705fe0a30e0
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171
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Plasma Technology for CO2 Conversion: A Personal Perspective on Prospects and Gaps, file de3e52b3-bca4-762d-e053-3705fe0a30e0
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156
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Transparent nanostructured titania coatings with selfcleaning and antireflective properties for photovoltaic glass surfaces, file de3e52af-5f45-762d-e053-3705fe0a30e0
|
110
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|
Enhanced performance in the direct electrocatalytic synthesis of ammonia from N2 and H2O by an in-situ electrochemical activation of CNT-supported iron oxide nanoparticles, file de3e52b3-cd1f-762d-e053-3705fe0a30e0
|
87
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Enhancing N2 Fixation Activity by Converting Ti3 C2 MXenes Nanosheets to Nanoribbons, file de3e52b3-b8c7-762d-e053-3705fe0a30e0
|
46
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Enhanced formation of >C1 Products in Electroreduction of CO2 by Adding a CO2 Adsorption Component to a Gas-Diffusion Layer-Type Catalytic Electrode, file de3e52b1-4a5f-762d-e053-3705fe0a30e0
|
43
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|
Hydrogenation of dimethyl oxalate to ethylene glycol on Cu/SiO2 catalysts prepared by a deposition-decomposition method: Optimization of the operating conditions and pre-reduction procedure, file 3374bd4c-a97c-492f-988b-6016b28349a7
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32
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Catalysis by hybrid sp2/sp3 nanodiamonds and their role in the design of advanced nanocarbon materials, file de3e52b4-4dfc-762d-e053-3705fe0a30e0
|
32
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Solar production of fuels from water and CO2: perspectives and opportunities for a sustainable use of renewable energy, file de3e52b2-955e-762d-e053-3705fe0a30e0
|
30
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|
High-throughput screening of heterogeneous catalysts for the conversion of furfural to bio-based fuel components, file de3e52b4-207f-762d-e053-3705fe0a30e0
|
30
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|
Development of low-cost pv devices by using nanocrystal ink of light-absorbing cigs semiconductor layer, file de3e52af-5986-762d-e053-3705fe0a30e0
|
27
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Enhancing N2 Fixation Activity by Converting Ti3 C2 MXenes Nanosheets to Nanoribbons, file de3e52b3-c90c-762d-e053-3705fe0a30e0
|
27
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|
Operando spectroscopy study of the carbon dioxide electro-reduction by iron species on nitrogen-doped carbon, file de3e52b1-60a8-762d-e053-3705fe0a30e0
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22
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|
Enhanced performance in the direct electrocatalytic synthesis of ammonia from N2 and H2O by an in-situ electrochemical activation of CNT-supported iron oxide nanoparticles, file de3e52b2-27c8-762d-e053-3705fe0a30e0
|
21
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|
Enhanced formation of >C1 Products in Electroreduction of CO2 by Adding a CO2 Adsorption Component to a Gas-Diffusion Layer-Type Catalytic Electrode, file de3e52b1-40fa-762d-e053-3705fe0a30e0
|
19
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Reuse of CO2 in energy intensive process industries, file 6ba30d6e-9ed4-4820-9b2f-fc8124531c17
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18
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|
Electrochemical Dinitrogen Activation: To Find a Sustainable Way to Produce Ammonia, file de3e52b1-e4f5-762d-e053-3705fe0a30e0
|
16
|
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Decoupling Electrocatalytic Reactions to Electrify Chemical Production, file b1907dd7-4ce1-477e-9bbf-139fd5f98b18
|
15
|
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In Memoriam: Dang Sheng Su (1961--2019), file de3e52b2-5fb8-762d-e053-3705fe0a30e0
|
14
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|
Highly Efficient Metal-Free Nitrogen-Doped Nanocarbons with Unexpected Active Sites for Aerobic Catalytic Reactions, file de3e52b3-df07-762d-e053-3705fe0a30e0
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14
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Deposition of NiO nanoparticles on nanosized zeolite nay for production of biofuel via hydrogen-free deoxygenation, file de3e52b3-88ad-762d-e053-3705fe0a30e0
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13
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Energy-related catalysis, file de3e52b3-e504-762d-e053-3705fe0a30e0
|
11
|
|
Electrocatalytic production of glycolic acid via oxalic acid reduction on
titania debris supported on a TiO2 nanotube array, file 1260b862-fa43-4ad4-98a6-d04cdc51a1d1
|
10
|
|
Beyond Solar Fuels: Renewable Energy-Driven Chemistry, file de3e52b1-40e1-762d-e053-3705fe0a30e0
|
10
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|
Operando spectroscopy study of the carbon dioxide electro-reduction by iron species on nitrogen-doped carbon, file de3e52b1-672a-762d-e053-3705fe0a30e0
|
10
|
|
THE NEW SCENARIO FOR SUSTAINABLE CHEMICAL AND ENERGY PRODUCTION: OPPORTUNITIES FOR RESEARCH AND INNOVATION, file de3e52b2-a239-762d-e053-3705fe0a30e0
|
10
|
|
Effect of Current Density on Product Distribution for the Electrocatalytic Reduction of CO2, file de3e52b2-8ba7-762d-e053-3705fe0a30e0
|
9
|
|
The role of oxide location in HMF etherification with ethanol over sulfated ZrO2 supported on SBA-15, file de3e52b4-12da-762d-e053-3705fe0a30e0
|
9
|
|
Pd Supported on Carbon Nitride Boosts the Direct Hydrogen Peroxide Synthesis, file de3e52b4-3bd3-762d-e053-3705fe0a30e0
|
9
|
|
Redesign chemical processes to substitute the use of fossil fuels: A viewpoint of the implications on catalysis, file de3e52b4-e61a-762d-e053-3705fe0a30e0
|
9
|
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Role of CuO in the modification of the photocatalytic water splitting behavior of TiO2 nanotube thin films, file de3e52b1-40fc-762d-e053-3705fe0a30e0
|
8
|
|
CO2: a Valuable Source of Carbon, file de3e52ae-ddaf-762d-e053-3705fe0a30e0
|
7
|
|
A novel gas flow-through photocatalytic reactor based on copper-functionalized nanomembranes for the photoreduction of CO2 to C1-C2 carboxylic acids and C1-C3 alcohols, file de3e52b3-9550-762d-e053-3705fe0a30e0
|
7
|
|
Novel carbon capture and utilisation technologies, file de3e52b5-0347-762d-e053-3705fe0a30e0
|
7
|
|
Membrane Reactor Engineering: Applications for a Greener Process Industry, file de3e52b3-460b-762d-e053-3705fe0a30e0
|
6
|
|
Comparing Molecular Mechanisms in Solar NH3 Production and Relations with CO2 Reduction, file de3e52b3-d9ec-762d-e053-3705fe0a30e0
|
6
|
|
The role of acid sites induced by defects in the etherification of HMF on Silicalite-1 catalysts, file de3e52b3-f1c8-762d-e053-3705fe0a30e0
|
6
|
|
Pd Supported on Carbon Nitride Boosts the Direct Hydrogen Peroxide Synthesis, file de3e52b4-1f45-762d-e053-3705fe0a30e0
|
6
|
|
null, file de3e52b4-d611-762d-e053-3705fe0a30e0
|
6
|
|
Transforming catalysis to produce e-fuels: Prospects and gaps, file b95ba908-399d-4d61-aa99-216539f56ce4
|
5
|
|
Semiconductor, molecular and hybrid systems for photoelectrochemical solar fuel production, file de3e52b0-f275-762d-e053-3705fe0a30e0
|
5
|
|
Mechanism of C–C bond formation in the electrocatalytic reduction of CO2 to acetic acid. A challenging reaction to use renewable energy with chemistry, file de3e52b1-00dc-762d-e053-3705fe0a30e0
|
5
|
|
CO2 Reduction of Hybrid Cu2O–Cu/Gas Diffusion Layer Electrodes and their Integration in a Cu-based Photoelectrocatalytic Cell, file de3e52b2-3ee1-762d-e053-3705fe0a30e0
|
5
|
|
Comparison of H+ and NH4 + forms of zeolites as acid catalysts for HMF etherification, file de3e52b2-96c6-762d-e053-3705fe0a30e0
|
5
|
|
null, file de3e52b3-82c9-762d-e053-3705fe0a30e0
|
5
|
|
Reduction of Greenhouse Gas Emissions by Catalytic Processes, file de3e52b3-ee4e-762d-e053-3705fe0a30e0
|
5
|
|
Catalysis, Green Chemistry and Sustainable Energy, file de3e52b3-fefc-762d-e053-3705fe0a30e0
|
5
|
|
null, file de3e52b5-23cf-762d-e053-3705fe0a30e0
|
5
|
|
null, file de3e52b5-779d-762d-e053-3705fe0a30e0
|
5
|
|
null, file de3e52ae-bfaf-762d-e053-3705fe0a30e0
|
4
|
|
Use of modified anodization procedures to prepare advanced TiO2 nanostructured catalytic electrodes and thin film materials, file de3e52af-6032-762d-e053-3705fe0a30e0
|
4
|
|
Functional nano-textured titania-coatings with self-cleaning and antireflective properties for photovoltaic surfaces, file de3e52af-a891-762d-e053-3705fe0a30e0
|
4
|
|
On the nature of the active sites in the selective oxidative esterification of furfural on Au/ZrO2 catalysts, file de3e52b0-7d8d-762d-e053-3705fe0a30e0
|
4
|
|
Electrocatalytic Synthesis of Ammonia at Room Temperature and Atmospheric Pressure from Water and Nitrogen on a Carbon-Nanotube-Based Electrocatalyst, file de3e52b0-aa8a-762d-e053-3705fe0a30e0
|
4
|
|
Engineering of photoanodes based on ordered TiO2-nanotube arrays in solar photo-electrocatalytic (PECa) cells, file de3e52b0-b688-762d-e053-3705fe0a30e0
|
4
|
|
Enhanced performance in the direct electrocatalytic synthesis of ammonia from N2 and H2O by an in-situ electrochemical activation of CNT-supported iron oxide nanoparticles, file de3e52b2-27c7-762d-e053-3705fe0a30e0
|
4
|
|
CO2 reduction reactions: general discussion, file de3e52b4-3090-762d-e053-3705fe0a30e0
|
4
|
|
g-C3N4 Decorated TiO2 Nanotube Ordered Thin Films as Cathodic Electrodes for the Selective Reduction of Oxalic Acid, file de3e52b4-e376-762d-e053-3705fe0a30e0
|
4
|
|
A gas-phase reactor powered by solar energy and ethanol for H2 production, file de3e52ae-f653-762d-e053-3705fe0a30e0
|
3
|
|
Electrolyte-less design of PEC cells for solar fuels: Prospects and open issues in the development of cells and related catalytic electrodes, file de3e52af-abe3-762d-e053-3705fe0a30e0
|
3
|
|
Role of size and pretreatment of Pd particles on their behaviour in the direct synthesis of H2O2, file de3e52af-eb98-762d-e053-3705fe0a30e0
|
3
|
|
Synthesis Characterization and Activity Pattern of Ni-Al Hydrotalcite Catalysts in CO2 Methanation, file de3e52b0-a430-762d-e053-3705fe0a30e0
|
3
|
|
Hydrophobic behavior of self-cleaning and AR sol-gel titania coatings for PV glass surface, file de3e52b0-f539-762d-e053-3705fe0a30e0
|
3
|
|
Photoactive materials based on semiconducting nanocarbons - A challenge opening new possibilities for photocatalysis, file de3e52b1-056f-762d-e053-3705fe0a30e0
|
3
|
|
Electrochemical behaviour of naked sub-nanometre sized copper clusters and effect of CO2, file de3e52b1-51dc-762d-e053-3705fe0a30e0
|
3
|
|
Monodisperse magnetite nanoparticles with high sensitivity as MRI contrast agents, file de3e52b1-b573-762d-e053-3705fe0a30e0
|
3
|
|
New Sustainable Model of Biorefineries: Biofactories and Challenges of Integrating Bio- and Solar Refineries, file de3e52b2-e95e-762d-e053-3705fe0a30e0
|
3
|
|
Highly selective bifunctional Ni zeo-type catalysts for hydroprocessing of methyl palmitate to green diesel, file de3e52b3-1b3c-762d-e053-3705fe0a30e0
|
3
|
|
Electrocatalytic reduction of CO2 over dendritic-type Cu- and Fe-based electrodes prepared by electrodeposition, file de3e52b3-403f-762d-e053-3705fe0a30e0
|
3
|
|
null, file de3e52b3-9bfa-762d-e053-3705fe0a30e0
|
3
|
|
Revealing the Origin of Activity in Nitrogen-Doped Nanocarbons towards Electrocatalytic Reduction of Carbon Dioxide, file de3e52b3-e900-762d-e053-3705fe0a30e0
|
3
|
|
Deactivation mechanism of hydrotalcite-derived Ni--AlO x catalysts during low-temperature CO 2 methanation via Ni-hydroxide formation and the role of Fe in limiting this effect, file de3e52b3-ef90-762d-e053-3705fe0a30e0
|
3
|
|
Effect of the structure and mesoporosity in Ni/zeolite catalysts for the hydroisomerization/hydrocracking of n-hexadecane hydroisomerisation and hydrocracking, file de3e52b4-0e72-762d-e053-3705fe0a30e0
|
3
|
|
null, file de3e52b5-76b5-762d-e053-3705fe0a30e0
|
3
|
|
An artificial leaf device built with earth-abundant materials for combined H2 production and storage as formate with efficiency > 10%, file 190f00f8-f9ab-45ae-a6cb-0c87d49f408d
|
2
|
|
Revealing the role of edges in the electrocatalytic synthesis of H2O2 over metal-free nanocarbon, file 6e368e7b-69f1-4a6f-81e9-f4eeb44df1a3
|
2
|
|
The Role of Substrate Surface Geometry in the Photo-Electrochemical Behaviour of Supported TiO2 Nanotube Arrays: A Study Using Electrochemical Impedance Spectroscopy (EIS), file b4811ed4-f43d-4053-a777-091ed2ce5e2b
|
2
|
|
SECOND GENERATION BIODIESEL: FROM CELLULOSE TO 5-HMF DERIVATES, file de3e52ae-c025-762d-e053-3705fe0a30e0
|
2
|
|
Synthesis of solar fuels by a novel photoelectrocatalytic approach, file de3e52ae-c81e-762d-e053-3705fe0a30e0
|
2
|
|
Development of Hydrogen Leak Sensors for Fuel Cell Transportation, file de3e52ae-e446-762d-e053-3705fe0a30e0
|
2
|
|
Core-shell Cu /TiO2 nanoparticle and Pt/TiO2 nanotubular photoelectrodes for H2 production, file de3e52ae-e7f9-762d-e053-3705fe0a30e0
|
2
|
|
A Gas-phase Electrochemical Reactor for Carbon Dioxide Reduction back to Liquid Fuels, file de3e52ae-f50c-762d-e053-3705fe0a30e0
|
2
|
|
A Gas-phase Electrochemical Reactor for Carbon Dioxide Reduction back to Liquid Fuels, file de3e52ae-f64b-762d-e053-3705fe0a30e0
|
2
|
|
Solar production of fuels from water and CO2: perspectives and opportunities for a sustainable use of renewable energy, file de3e52af-5620-762d-e053-3705fe0a30e0
|
2
|
|
Monitoring of glucose in fermentation processes by using Au/TiO2 composites as novel modified electrodes, file de3e52af-574c-762d-e053-3705fe0a30e0
|
2
|
|
CO2 capture and reduction to liquid fuels in a novel electrochemical setup by using metal-doped conjugated microporous polymers, file de3e52af-57a2-762d-e053-3705fe0a30e0
|
2
|
|
CO2 utilization: an enabling element to move to a resource and energy efficient chemical and fuel production, file de3e52af-5eb3-762d-e053-3705fe0a30e0
|
2
|
|
Electrocatalytic conversion of CO2 to produce solar fuels in electrolyte or electrolyte-less configurations of PEC cells, file de3e52af-b363-762d-e053-3705fe0a30e0
|
2
|
|
A Comparative Catalyst Evaluation for the Selective Oxidative Esterification of Furfural, file de3e52b0-811a-762d-e053-3705fe0a30e0
|
2
|
|
Analysis of the factors controlling performances of Au-modified TiO2 nanotube array based photoanode in photo-electrocatalytic (PECa) cells, file de3e52b0-fa1e-762d-e053-3705fe0a30e0
|
2
|
|
Development of photoanodes for photoelectrocatalytic solar cells based on copper-based nanoparticles on titania thin films of vertically aligned nanotubes, file de3e52b1-40fd-762d-e053-3705fe0a30e0
|
2
|
|
Development of photoanodes for photoelectrocatalytic solar cells based on copper-based nanoparticles on titania thin films of vertically aligned nanotubes, file de3e52b1-43f6-762d-e053-3705fe0a30e0
|
2
|
|
Water splitting on 3D-type meso/macro porous structured photoanodes based on Ti mesh, file de3e52b1-47d8-762d-e053-3705fe0a30e0
|
2
|
|
Role of small Cu nanoparticles in the behaviour of nanocarbon-based electrodes for the electrocatalytic reduction of CO2, file de3e52b1-48c0-762d-e053-3705fe0a30e0
|
2
|
|
Nanostructured two-dimensional titania films for solar fuels and PV applications, file de3e52b1-49ff-762d-e053-3705fe0a30e0
|
2
|
|
null, file de3e52b2-347e-762d-e053-3705fe0a30e0
|
2
|
|
Chemical engineering role in the use of renewable energy and alternative carbon sources in chemical production, file de3e52b2-5fb3-762d-e053-3705fe0a30e0
|
2
|
| Totale |
2.018 |