"Effect of γ-Valerolactone Blending on Engine Performance, Combustion Characteristics and Exhaust Emissions in a Diesel Engine"
written by Ákos Bereczky, Kristóf Lukács, Mária Farkas, Sándor Dóbé,
published by Natural Resources, Vol.5 No.5, 2014
has been cited by the following article(s):
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[2] CFD Design of Hydrogenation Reactor for Transformation of Levulinic Acid to γ-Valerolactone (GVL) by using High Boiling Point Organic Fluids
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[3] Green synthesis of gamma-valerolactone (GVL) through hydrogenation of biomass-derived levulinic acid using non-noble metal catalysts: A critical review
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[4] Thermal and Volumetric Properties of Five Lactones at Infinite Dilution in Water
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[5] On the HCCI Octane Boosting Effects of γ-Valerolactone
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[6] Continuous flow hydrogenation of methyl and ethyl levulinate: an alternative route to γ-valerolactone production
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[7] Engine exhaust system, emission and its control
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[8] Pressure-dependent branching in initial decomposition of gamma-valerolactone: a quantum chemical/RRKM study
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[9] Economic potential of 2-methyltetrahydrofuran (MTHF) and ethyl levulinate (EL) produced from hemicelluloses-derived furfural
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[10] Future Trends and Outlook in Biofuels Production
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[11] Influence of Gamma-Valerolactone-n-Butanol-Diesel Blends on Physicochemical Characteristics and Emissions of a Diesel Engine
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[12] Microwave‐Assisted Valorization of Biowastes to Levulinic Acid
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[13] Reactions of lactones with tropospheric oxidants: A kinetics and products study
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[14] Investigating the Combustion and Emissions Characteristics of Biomass-Derived Platform Fuels as Gasoline Extenders in a Single Cylinder Spark-Ignition Engine
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[15] Vapor–Liquid Equilibrium of γ-Valerolactone and Formic Acid at p = 51 kPa
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[16] Efficient hydrogenation of levulinic acid in water using a supported Ni–Sn alloy on aluminium hydroxide catalysts
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[17] Vapor–Liquid Equilibrium Study of the Gamma-Valerolactone–Water Binary System
Journal of Chemical & Engineering Data, 2016
[18] Effect of lignin-derived cyclohexanol on combustion, performance and emissions of a direct-injection agricultural diesel engine under naturally aspirated and exhaust gas recirculation (EGR) modes
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[19] The oxidation of the novel lignocellulosic biofuel γ-valerolactone in a low pressure flame
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[20] Direct and relative rate coefficients for the gas-phase reaction of OH radicals with 2-methyltetrahydrofuran at room temperature
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[21] Isobaric Vapor–Liquid Equilibria for Binary Mixtures of γ-Valerolactone+ Methanol, Ethanol, and 2-Propanol
Journal of Chemical & Engineering Data, 2016
[22] Effective conversion of biomass-derived ethyl levulinate into γ-valerolactone over commercial zeolite supported Pt catalysts
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[23] 新型生物质基平台分子 γ-戊内酯的应用
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[24] Experimental and Computational Study on Liquid–Liquid Equilibrium in Ternary Systems of γ-Valerolactone, Toluene, and Hydrocarbons
Journal of Chemical & Engineering Data, 2015
[25] An experimental and kinetic modeling study of γ-valerolactone pyrolysis
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[26] Upgrading furfurals to drop-in biofuels: An overview
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[27] Kinetics of the reaction of OH radicals with the biofuel molecule 2-methyltetrahydrofuran
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[28] Binary Liquid–Liquid Equilibria of γ-Valerolactone with Some Hydrocarbons
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[29] Microwave-Assisted Conversion of Levulinic Acid to γ-Valerolactone Using Low-Loaded Supported Iron Oxide Nanoparticles on Porous Silicates
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[30] Chemical kinetics and transport of tropospheric trace compounds-implications for environment and air quality
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[31] Direct Production of 5‐Hydroxymethylfurfural via Catalytic Conversion of Simple and Complex Sugars over Phosphated TiO2
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[32] Production of γ-valerolactone from lignocellulosic biomass for sustainable fuels and chemicals supply
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