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Synthesis, application, and characteristics of mesoporous alumina as a support of promoted Ni-Co bimetallic catalysts in steam reforming of methane
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Fuel,
2023 |
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Catalytic Steam Reforming of Ethanol to Produce Hydrogen: Modern and Efficient Catalyst Modification Strategies
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ChemistrySelect,
2023 |
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[3]
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Plasma steam methane reforming (PSMR) using a microwave torch for commercial-scale distributed hydrogen production
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International Journal of Hydrogen Energy,
2022 |
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[4]
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Tuning the efficiency and product composition for electrocatalytic CO 2 reduction to syngas over zinc films by morphology and wettability
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Green …,
2022 |
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[5]
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Process design and techno-economic analysis of dual hydrogen and methanol production from plastics using energy integrated system
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Qadri, U Ahmed, AGA Jameel, N Ahmad… - International Journal of …,
2022 |
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Deactivation and in-situ regeneration of Dy-doped Ni/SiO2 catalyst in CO2 reforming of methanol
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International Journal of …,
2022 |
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[7]
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CeO2 Nanorod@NiPhy Core‐shell Catalyst for Methane Dry Reforming: Effect of Simultaneous Sintering Prevention of CeO2 Support and Active Ni
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2022 |
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[8]
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Comparative Study of the Catalytic Oxidation of Hydrocarbons on Platinum and Palladium Wires and Nanoparticles
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Energy & …,
2022 |
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[9]
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Tri-reforming of Methane for Syngas Production using Ni catalysts: Current Status and Future Outlook
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Catalysis Today,
2022 |
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[10]
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Fabrication of a Ceramic Foam Catalyst Using Polymer Foam Scrap via the Replica Technique for Dry Reforming
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ACS omega,
2022 |
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[11]
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Simulation and Modelling of Hydrogen Production from Waste Plastics: Technoeconomic Analysis
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Qadri, U Ahmed, AG Abdul Jameel, U Zahid… - Polymers,
2022 |
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[12]
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Hydrogen Generation from CO2 Reforming of Biomass-Derived Methanol on Ni/SiO2 Catalyst
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Topics in …,
2022 |
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Reforming processes for syngas production: A mini-review on the current status, challenges, and prospects for biomass conversion to fuels
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Applications in Energy and Combustion …,
2022 |
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Influence of Catalytic Supports on Methane Steam Reforming: A Short Review
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American Journal of Applied …,
2022 |
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Techno-Economic Analysis of the Conversion of Waste Plastics to Hydrogen Fuel
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32nd European Symposium on …,
2022 |
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Technoeconomic Feasibility of Hydrogen Production from Waste Tires with the Control of CO2 Emissions
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Qadri, U Ahmed, AG Abdul Jameel, U Zahid… - ACS …,
2022 |
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Methanolsynthese aus CO2 an In2O3-basierten Katalysatoren in Slurry-und Festbettreaktoren
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2021 |
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Study of the kinetic regularities of the reaction of methane carbonate conversion
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Asian Journal of …,
2021 |
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THE MAIN CHARACTERISTICS OF STEAM-CARBON-DIOXIDE CONVERSION OF METHANE
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Universum: химия и биология,
2021 |
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[20]
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A novel nickel catalyst supported on activated steel slags for syngas production and tar removal from biomass pyrolysis
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International Journal of Hydrogen Energy,
2021 |
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Thermocatalytic hydrogen production through decomposition of methane-A review
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Frontiers in …,
2021 |
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[22]
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Computational Fluid Dynamics Modeling to Simulate a Combined Reforming Process for Syngas and Hydrogen Production
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2021 |
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[23]
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Current advances in syngas (CO+ H2) production through bi-reforming of methane using various catalysts: A review
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Yaseri… - international journal of …,
2021 |
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Recent progress in ceria-based catalysts for the dry reforming of methane: A review
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Chemical Engineering …,
2021 |
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Methanol economy and net zero emissions: critical analysis of catalytic processes, reactors and technologies
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Green Chemistry,
2021 |
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A comprehensive review on improving the production of rich-hydrogen via combined steam and CO2 reforming of methane over Ni-based catalysts
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2021 |
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Kinetic Modeling of Combined Steam and CO2 Reforming of Methane over the Ni–Pd/Al2O3 Catalyst Using Langmuir–Hinshelwood and Langmuir–Freundlich …
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2021 |
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[28]
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Numerical simulation of commercial scale autothermal chemical looping reforming and bi-reforming for syngas production
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2021 |
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[29]
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Optimization of CO2 reforming of methane process for the syngas production over Ni–Ce/TiO2–ZrO2 catalyst using the Taguchi method
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2021 |
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[30]
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Highly selective production of syngas (> 99%) in the partial oxidation of methane at 480° C over Pd/CeO2 catalyst promoted by HCl
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2021 |
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[31]
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Steering the Catalytic Properties of Intermetallic Compounds and Alloys in Reforming Reactions by Controlled in Situ Decomposition and Self-Activation
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2021 |
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Syngas production with CO2 utilization through the oxidative reforming of methane in a new cermet-carbonate packed-bed membrane reactor
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2021 |
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Oscillatory Behaviour of Ni Supported on ZrO2 in the Catalytic Partial Oxidation of Methane as Determined by Activation Procedure
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2021 |
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Techno-economic analysis of dual methanol and hydrogen production using energy mix systems with CO2 capture
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2021 |
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Katalizatory do konwersji metanu z dwutlenkiem węgla
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2020 |
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2020 |
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Carbide-Modified Pd on Zr [O. sub. 2] as Active Phase for C [O. sub. 2]-Reforming of Methane--A Model Phase Boundary Approach
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2020 |
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[38]
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Elevated CO-free hydrogen productivity through ethanol steam reforming using cubic Co-Nanoparticles based MgO catalyst
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2020 |
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Performance Improvement of VHTR Design Technology
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2020 |
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Combined steam and CO2 reforming of methane (CSCRM) over Ni–Pd/Al2O3 catalyst for syngas formation
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2020 |
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[41]
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Exploration of ceramic supports to be used in membrane reactors for hydrogen production and separation
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2020 |
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FeCrAl as a catalyst support
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2020 |
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[43]
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Catalytic conversion of greenhouse gases (CO2 and CH4) to syngas over Ni-based catalyst: Effects of Ce-La promoters
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2020 |
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[44]
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Valuation of catalytic activity of nickel–zirconia‐based catalysts using lanthanum co‐support for dry reforming of methane
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2020 |
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[45]
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Optimal Design and Energy-Saving Investigation of the Triple CO2 Feeds for Methanol Production System by Combining Steam and Dry Methane Reforming
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2020 |
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[46]
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Influence of feed rate and testing variables for low-temperature tri-reforming of methane on the Ni@ MWCNT/Ce catalyst
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2020 |
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[47]
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Catalytic partial oxidation of methane to syngas: review of perovskite catalysts and membrane reactors
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2020 |
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Catalytic steam reforming of tar for enhancing hydrogen production from biomass gasification: a review
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2020 |
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[49]
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Syngas production through steam and CO 2 reforming of methane over Ni-based catalyst-A Review
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2020 |
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[50]
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Carbide-Modified Pd on ZrO2 as Active Phase for CO2-Reforming of Methane—A Model Phase Boundary Approach
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2020 |
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[51]
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Hydrogen and carbon monoxide derivation over metal supported on fibrous silica KCC-1
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2020 |
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[52]
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Hydrogen from steam methane reforming by catalytic nonthermal plasma using a dielectric barrier discharge reactor
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AIChE Journal,
2019 |
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[53]
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Light-driven proton reduction with in situ supported copper nanoparticles
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2019 |
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[54]
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Role of the nanoparticles of Cu-Co alloy derived from perovskite in dry reforming of methane
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2019 |
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[55]
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Catalytic aqueous phase reforming of the Fischer-Tropsch derived water fraction: Kinetics and reactor modeling
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2019 |
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[56]
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Dry reforming of methane using modified sodium and protonated titanate nanotube catalysts
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2019 |
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[57]
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Étude des performances et de la désactivation par empoisonnement au soufre du catalyseur spinelle Ni-UGSO: cas du reformage autothermique du méthane
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2019 |
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[58]
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Μαθηματική μοντελοποίηση και βελτιστοποίηση τριοδικής λειτουργίας κυψελίδων καυσίμων
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2019 |
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[59]
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Atomic-Level Analysis of Oxygen Exchange Reactions on Ceria-based Catalysts
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2019 |
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[60]
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STEAM REFORMING OF GASIFIED BIOMASS TAR FOR HYDROGEN PRODUCTION OVER NICKEL–DOLOMITE BASED CATALYST
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2019 |
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[61]
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Design of new catalysts for chemical CO2 utilization
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2019 |
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[62]
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Catalytic methane reforming into synthesis gas over developed composite materials prepared by combustion synthesis
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2019 |
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[63]
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Ilmenite ore as an oxygen carrier for pressurized chemical looping reforming: Characterization and process simulation
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2019 |
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[64]
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Combustion vs. Hybrid Sol-Gel-Plasma Surface Design of Coke-Resistant Co-Promoted Ni-Spinel Nanocatalyst Used in Combined Reforming of CH4/CO2/O2 for …
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2019 |
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[65]
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Catalytic steam reforming of complex gasified biomass tar model toward hydrogen over dolomite promoted nickel catalysts
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2019 |
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[66]
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Mesoporous nanostructured Ni/MgAl2O4 catalysts: Highly active and stable catalysts for syngas production in combined dry reforming and partial oxidation
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2019 |
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[67]
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The Fe-Co-Cu supported on MWCNT as catalyst for the tri-reforming of methane–Investigating the structure changes of the catalysts
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2019 |
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[68]
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Simultaneous CO2 and O2 separation coupled to oxy-dry reforming of CH4 by means of a ceramic-carbonate membrane reactor for in situ syngas production
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2019 |
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[69]
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Dry and steam reforming of methane. Comparison and analysis of recently investigated catalytic materials. A short review.
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2019 |
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Spinel Mixed Oxides for Chemical-Loop Reforming: From Solid State to Potential Application
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2019 |
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Catalytic Conversion of Methane at Low Temperatures–A Critical Review
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Energy Technology,
2019 |
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[72]
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Design of Multi‐Metallic‐Based Electrocatalysts for Enhanced Water Oxidation
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2019 |
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Innovative hydrocarbons recovery and utilization technology using reactor-separation membranes for off-gases emission during crude oil shuttle tanker …
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2018 |
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2018 |
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The non-catalytic partial oxidation of methane in a flow tube reactor using indirect induction heating–An experimental and kinetic modelling study
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Chemical Engineering Science,
2018 |
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[76]
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The Role of Neodymium in the Optimization of a Ni/CeO2 and Ni/CeZrO2 Methane Dry Reforming Catalyst
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Inorganics,
2018 |
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[77]
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Oxygen Transfer at Metal-Reducible Oxide Nanocatalyst Interfaces: Contrasting Carbon Growth from Ethane and Ethylene
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ACS Applied Nano Materials,
2018 |
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[78]
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Industrial Ni-Based Catalyst Development for Carbon Dioxide Reforming of Methane
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2018 |
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[79]
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Comparative assessment of response surface methodology quadratic models and artificial neural network method for dry reforming of natural gas
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Energy Sources Part A Recovery Utilization and Environmental Effects,
2018 |
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[80]
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Impregnation vs. sol-gel and sol-gel-plasma dispersion of nickel nanoparticles over Al2O3 employed in combined dry reforming and partial oxidation of greenhouse …
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International Journal of Hydrogen Energy,
2018 |
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[81]
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Innovative hydrocarbons recovery and utilization technology using reactor-separation membranes for off-gases emission during crude oil shuttle tanker transportation …
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2018 |
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[82]
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Tri-Reforming of Natural Gas for Hydrogen Production
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2018 |
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[83]
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Zirconium‐assistierte Aktivierung von Palladium zur Steigerung der Produktion von Synthesegas in der Trockenreformierung von Methan
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Angewandte Chemie,
2018 |
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[84]
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Zirconium‐Assisted Activation of Palladium To Boost Syngas Production by Methane Dry Reforming
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Angewandte Chemie International Edition,
2018 |
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Perspective of catalysts for (Tri) reforming of natural gas and flue gas rich in CO2
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Applied Catalysis A: General,
2018 |
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[86]
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Development of Technologies for More Efficient Deep Processing of Natural Gas
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2018 |
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Safety measures implementation for MRT construction sites in Malaysia
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2018 |
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[88]
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Process Integration of a Gas to Liquid Plant and a Power Plant
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2018 |
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[89]
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A que distância estamos da cinética máxima no processo tradicional de reforma de metano?
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2018 |
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[90]
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Nickel aluminide coating as catalyst in steam methane reforming microreactor
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2017 |
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CO 2 utilization through integration of post-combustion carbon capture process with Fischer-Tropsch gas-to-liquid (GTL) processes
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Journal of CO2 Utilization,
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The Role of Synthetic Fuels for a Carbon Neutral Economy
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Integration of Reforming and CO2 Removal processes in a GTL Plant
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Energy & Fuels,
2017 |
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What is the most energy efficient route for biogas utilization: Heat, electricity or transport?
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Applied Energy,
2017 |
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Catalysts for conversion of synthesis gas
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Bioenergy Systems for the Future,
2017 |
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The CO2 economy: Review of CO2 capture and reuse technologies
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The Journal of Supercritical Fluids,
2017 |
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Process Intensification of Gasification and Reforming Technology for Enhanced Power Generation with Carbon Capture and Storage
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2017 |
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2017?? ?????? ?? ???? ???,
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Углекислотная конверсия метана с использованием мембранных катализаторов на основе двойных карбидов
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2017 |
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CO2 utilization through integration of post-combustion carbon capture process with Fischer-Tropsch gas-to-liquid (GTL) processes
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Journal of CO2 Utilization,
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V. Palma, C. Ruocco, M. Martino, E. Meloni, A. Ricca University of Salerno, Salerno, Italy
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2017 |
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[102]
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Integration of Reforming and CO2 Removal Processes in a Gas-to-Liquid Plant
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Energy & Fuels,
2017 |
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Dry reforming of methane over nickel catalysts modified with noble metals
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2016 |
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Applications in Energy and Combustion Science
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