ACS applied materials & interfaces

ACS omega

[1] Ultrasmall Silver Clusters Stabilized on MgO for Robust Oxygen-Promoted Hydrogen Production from Formaldehyde Reforming.

[2] Super Toughened Poly(lactic acid)-Based Ternary Blends via Enhancing Interfacial Compatibility.

[3] Solar chemical looping reforming of methane combined with isothermal H<inf>2</inf>O/CO<inf>2</inf> splitting using ceria oxygen carrier for syngas production

[4] Redefining the Acting Internship in the Era of Entrustment: One Institution’s Approach to Reforming the Acting Internship

[5] Experimental Study for Partial Oxidation Reforming of CH<inf>4</inf>/CO<inf>2</inf>With Rich Combustion in a Porous Media Burner

[6] Engineering oxygen vacancies and nickel dispersion on CeO<inf>2</inf> by Pr doping for highly stable ethanol steam reforming

[7] Photocatalytic reforming of biomass for hydrogen production over ZnS nanoparticles modified carbon nitride nanosheets.

[8] A thermo-photo hybrid process for steam reforming of methane: highly efficient visible light photocatalysis.

[9] Interplay of Support Chemistry and Reaction Conditions on Copper Catalyzed Methanol Steam Reforming.

[10] Microwave Heating-Assisted Catalytic Dry Reforming of Methane to Syngas.

[11] Combined Ceria Reduction and Methane Reforming in a Solar-Driven Particle-Transport Reactor.

[12] Self-Supported 3D PdCu Alloy Nanosheets as a Bifunctional Catalyst for Electrochemical Reforming of Ethanol.

[13] Conversion of Carbon Dioxide by Methane Reforming under Visible-Light Irradiation: Surface-Plasmon-Mediated Nonpolar Molecule Activation.

[14] Carbon Dioxide Reforming of Methane using an Isothermal Redox Membrane Reactor.

[15] Analysis and optimization for energy, cost and carbon emission of a solar driven steam-autothermal hybrid methane reforming for hydrogen, ammonia and power production

[16] Multi-objective optimization and analysis of a solar energy driven steam and autothermal combined reforming system with natural gas

[17] Novel concept for indirect solar-heated methane reforming

[18] Annual performance of a solar reforming plant for high-temperature thermal processing of minerals

[19] Steam methane reforming over structured reactors under concentrated solar irradiation

[20] Solar hydrogen production via perovskite-based chemical-looping steam methane reforming

[21] Corrigendum to “Optimization of a hybrid solar-fossil fuel plant: Solar steam reforming of methane in a combined cycle” (Energy (2013) 51 (193–202), (S0360544213000479) (10.1016/j.energy.2013.01.027))

[22] A comprehensive study on parabolic trough solar receiver-reactors of methanol-steam reforming reaction for hydrogen production

[23] Thermodynamic analysis on mid/low temperature solar methane steam reforming with hydrogen permeation membrane reactors

[24] Hybrid Solar Power Generation System Integrating Concentrating Photovoltaics and Methane Reforming With Spectral Splitting

[25] Analysis of Two-Step Solar Thermochemical Looping Reforming of Fe <inf>3</inf> O <inf>4</inf> Redox Cycles for Synthesis Gas Production

[26] High efficiency solar chemical-looping methane reforming with ceria in a fixed-bed reactor

[27] Syngas production via solar-driven chemical looping methane reforming from redox cycling of ceria porous foam in a volumetric solar reactor

[28] Solar-driven novel methane reforming with carbon looping for hydrogen production

[29] Stepwise Solar Methane Reforming and Water-Splitting via Lattice Oxygen Transfer in Iron and Cerium Oxides

[30] Thermodynamic efficiency analysis of ZnO/Zn based solar thermochemical CH<inf>4</inf> reforming and H<inf>2</inf>O splitting cycle

[31] Heat transfer and storage performance of steam methane reforming in tubular reactor with focused solar simulator

[32] Analysis of CO<inf>2</inf> utilization into synthesis gas based on solar thermochemical CH<inf>4</inf>-reforming

[33] Thermodynamic and kinetic analysis of an integrated solar thermochemical energy storage system for dry-reforming of methane

[34] Photocatalytic Solar Light H<inf>2</inf> Production by Aqueous Glucose Reforming

[35] (Solar) mixed reforming of methane: Potential and limits in utilizing CO<inf>2</inf> as feedstock for syngas production - A thermodynamic analysis

[36] Full-spectrum solar energy utilization integrating spectral splitting, photovoltaics and methane reforming

[37] A solar methane reforming reactor design with enhanced efficiency

[38] Solar driven two-step CH<inf>4</inf> reforming and H<inf>2</inf>O splitting using Al<inf>2</inf>O<inf>3</inf> for Co-production of Al, syngas, and H<inf>2</inf>

[39] Effect of internal hydrocarbon reforming during coupled operation of a biomass gasifier with hot gas cleaning and SOFC stacks

[40] Reforming perpendicular shocks in the presence of pickup protons: initial ion acceleration

[41] Reforming Islamic finance for achieving sustainable development goals

[42] Optimization of a novel multifunctional reactor containing m-xylene hydrodealkylation and naphtha reforming

[43] Ultrasmall Silver Clusters Stabilized on MgO for Robust Oxygen-Promoted Hydrogen Production from Formaldehyde Reforming.

[44] Towards Reforming Nigeria's Secured Transactions Law: The Central Bank of Nigeria's Attempt through the Back Door

[45] Corrigendum to ‘Autothermal dry reforming of methane with a nickel spinellized catalyst prepared from a negative value metallurgical residue’ (Renewable Energy (2019) 138 (1239–1249), (S0960148119301363), (10.1016/j.renene.2019.01.125))

[46] Catalytic Properties of Heusler Alloys for Steam Reforming of Methanol.

[47] Low-temperature hydrogen production from methanol steam reforming on Zn-modified Pt/MoC catalysts

[48] Dual catalyst-sorbent role of dolomite in the steam reforming of raw bio-oil for producing H<inf>2</inf>-rich syngas

[49] Multi-scale two-dimensional packed bed reactor model for industrial steam methane reforming

[50] Effect of secondary metal catalysts on butane internal steam reforming operation of thin-film solid oxide fuel cells at 500–600 °C

[51] Steam reforming of acetic acid over Ni–Ba/Al<inf>2</inf>O<inf>3</inf> catalysts: Impacts of barium addition on coking behaviors and formation of reaction intermediates

[52] Enhancement of the catalytic performances and lifetime of Ni/γ-Al<inf>2</inf>O<inf>3</inf> catalysts for the steam toluene reforming via the combination of dopants: inspection of Cu, Co, Fe, Mn, and Mo species addition

[53] Hydrogen storage for off-grid power supply based on solar PV and electrochemical reforming of ethanol-water solutions

[54] Transient analysis of a solid oxide fuel cell unit with reforming and water-shift reaction and the building of neural network model for rapid prediction in electrical and thermal performance

[55] Reforming urban sanitation under decentralization: Cross-country learning for Kenya and beyond

[56] CO<inf>2</inf> reforming in CH<inf>4</inf> over Ni/γ-Al<inf>2</inf>O<inf>3</inf> nano catalyst: Effect of cold plasma surface discharge

[57] Integrating pyrolysis and ex-situ catalytic reforming by microwave heating to produce hydrocarbon-rich bio-oil from soybean soapstock.

[58] Effects of ordered hierarchically porous structure on methane reforming performance in solar foam reactor

[59] Efficiency assessment of solar redox reforming in comparison to conventional reforming

[60] Effects of non-uniform porosity on thermochemical performance of solar driven methane reforming

[61] Testing of a 3D-Printed Solar Micro-Reactor for Hydrogen Production via Natural Gas Reforming

[62] Solar photocatalytic hydrogen production from glycerol reforming using ternary Cu/THS/Graphene

[63] Numerical Investigation of Carbon Deposition Behavior in Ni/Al<inf>2</inf>O<inf>3</inf>-Based Catalyst Porous-Filled Solar Thermochemical Reactor for the Dry Reforming of Methane Process

[64] Ni/CeO<inf>2</inf> structured catalysts for solar reforming of spent solvents

[65] Analysis of planar-cavity receiver reactor for solar thermochemical dry-reforming

[66] Methane and Ethane Steam Reforming over MgAl₂O₄-Supported Rh and Ir Catalysts: Catalytic Implications for Natural Gas Reforming Application

[67] Tuning combined steam and dry reforming of methane for “metgas” production: A thermodynamic approach and state-of-the-art catalysts

[68] Comparative assessment of performances of different oxygen carriers in a chemical looping combustion coupled intensified reforming process through simulation study

[69] Biogas Reforming to Syngas: A Review.

[70] Model biogas reforming over Ni-Rh/MgAl<inf>2</inf>O<inf>4</inf> catalyst. Effect of gas impurities

[71] Hydrogen and/or syngas production through combined dry and steam reforming of biogas in a membrane reactor: A thermodynamic study

[72] Catalytic steam reforming of model biogas

[73] synthesis and application of cerium-incorporated sba-16 supported ni-based oxygen carrier in cyclic chemical looping steam methane reforming

[74] penal law of the future: directions of reforming

[75] reforming the australian mental health system: can network theory and methods help?

[76] ce - promoted catalyst from hydrotalcites for co2 reforming of methane: calcination temperature effect

[77] management of corporate rights of the state: evaluation of efficiency and directions of reforming

[78] managing the process of catalytic reforming by the optimal distribution of temperature at the reactor block inlets

[79] parametric study of hydrogen production from ethanol steam reforming in a membrane microreactor

[80] reforming community medicine in line with the country's health priorities - let's make it relevant and rational

[81] highly stable and active ni-doped ordered mesoporous carbon catalyst on the steam reforming of ethanol application

[82] Prediction and evaluation of plasma arc reforming of naphthalene using a hybrid machine learning model

[83] active ageing and reforming pension system. main challenges

[84] prospects for reforming the organizational and legal mechanism for ensuring human and civil rights and freedoms

[85] catalyst deactivation simulation through carbon deposition in carbon dioxide reforming over ni/cao-al2o3 catalyst

[86] a white paper on reforming canada’s transportation policies for the 21st century

[87] the effect of wo3 modification of zro2 support on the ni-catalyzed dry reforming of biogas reaction for syngas production

[88] carbon dioxide dry reforming of glycerol for hydrogen production using ni/zro2 and ni/cao as catalysts

[89] hydrogen production by sorption enhanced steam reforming (sesr) of biomass in a fluidised-bed reactor using combined multifunctional particles

[90] alguns aspectos da reforma da inteligência na américa latina some aspects of reforming intelligence in latin america

[91] local government reforming in lithuania: experience for ukraine

[92] analysis of combined cycle power plants with chemical looping reforming of natural gas and pre-combustion co2 capture

[93] institutional evolution of european union toward the enlargement. reforming aspects of the institutional system

[94] reforming social-humanitarian sphere in the decentralization of power in ukraine

[95] Catalytic Performance of Metal Oxides Promoted Nickel Catalysts Supported on Mesoporous γ-Alumina in Dry Reforming of Methane

[96] Hydrogen Production by Partial Oxidation Reforming of Methane over Ni Catalysts Supported on High and Low Surface Area Alumina and Zirconia

[97] Hydrogen Production by Partial Oxidation Reforming of Methane over Ni Catalysts Supported on High and Low Surface Area Alumina and Zirconia

[98] Catalytic Performance of Metal Oxides Promoted Nickel Catalysts Supported on Mesoporous γ-Alumina in Dry Reforming of Methane

[99] Growth and Hormonal Status of Children in the Context of Reforming the Preschool Education System

[100] Priority Directions for Reforming the Banking System in the Republic of Uzbekistan