Page last updated: 2024-08-18

gamma-valerolactone and levulinic acid

gamma-valerolactone has been researched along with levulinic acid in 26 studies

Research

Studies (26)

Timeframe	Studies, this research(%)	All Research%
pre-1990	0 (0.00)	18.7374
1990's	1 (3.85)	18.2507
2000's	2 (7.69)	29.6817
2010's	18 (69.23)	24.3611
2020's	5 (19.23)	2.80

Authors

Authors	Studies
Gottschalk, G; Hein, S; Söhling, B; Steinbüchel, A	1
Bourne, RA; Ke, J; Poliakoff, M; Stevens, JG	1
Deng, L; Fu, Y; Guo, QX; Lai, DM; Li, J	1
Bozell, JJ	1
Deng, L; Fu, Y; Guo, QX; Li, J; Liao, B; Zhao, Y	1
Engendahl, B; Geilen, FM; Hölscher, M; Klankermayer, J; Leitner, W	1
Chia, M; Dumesic, JA	1
Palkovits, R; Wright, WR	1
Chadderdon, DJ; Li, W; Qi, J; Qiu, Y; Warsko, KM; Xin, L; Zhang, Z	1
Dafoe, JT; Daugulis, AJ	1
Grams, J; Jędrzejczyk, M; Matras-Michalska, J; Michel, C; Ruppert, AM; Sautet, P; Zaffran, J	1
De, S; Luque, R; Saha, B	1
Grams, J; Jędrzejczyk, M; Keller, N; Matras-Michalska, J; Ostojska, K; Ruppert, AM; Sautet, P	1
Chan-Thaw, CE; Dai, S; Fulvio, PF; Mayes, RT; More, KL; Prati, L; Schiavoni, M; Veith, GM; Villa, A	1
Burtoloso, AC; Metzker, G	1
Calcio Gaudino, E; Carnaroglio, D; Cravotto, G; Grillo, G; Tabasso, S	1
Han, B; Jiang, T; Song, J; Wu, L; Wu, T; Zhou, B	1
Hallett, J; Miller, PW; Omoruyi, U; Page, S	1
Al-Shaal, MG; Arias, PL; Gandarias, I; Mevissen, C; Obregón, I; Palkovits, R	1
Deng, S; Guo, D; Liu, Y; Lou, J; Su, C; Wei, Z	1
Lin, KA; Yang, MT; Yun, WC	1
Barla, MK; Madduluri, VR; Minpoor, S; Srinivasu, P; Velagala, RR	1
Chi, Y; Hu, C; Li, J; Li, Z; Liu, D; Zhao, S	1
Bykov, AV; Ezernitskaya, MG; Golovin, AL; Kuchkina, NV; Mikhailov, SP; Nikoshvili, LZ; Shifrina, ZB; Sorokina, SA; Sulman, MG; Vasiliev, AL	1
Dong, Z; Fang, J; Gao, W; Li, B; Li, J; Liu, C; Ma, K; Ren, X; Yang, H; Zhao, H	1
Guo, H; Liang, Y; Qi, X; Xu, Y	1

Reviews

3 review(s) available for gamma-valerolactone and levulinic acid

Article	Year
Development of heterogeneous catalysts for the conversion of levulinic acid to γ-valerolactone. ChemSusChem, 2012, Volume: 5, Issue:9 Topics: Catalysis; Formates; Hydrogenation; Lactones; Levulinic Acids; Temperature	2012
Hydrodeoxygenation processes: advances on catalytic transformations of biomass-derived platform chemicals into hydrocarbon fuels. Bioresource technology, 2015, Volume: 178 Topics: Biofuels; Biomass; Biotechnology; Catalysis; Conservation of Energy Resources; Furaldehyde; Furans; Hydrocarbons; Hydrogen; Hydrogenation; Lactones; Levulinic Acids; Lignin; Oxygen	2015
Homogeneous Catalyzed Reactions of Levulinic Acid: To γ-Valerolactone and Beyond. ChemSusChem, 2016, 08-23, Volume: 9, Issue:16 Topics: Catalysis; Furans; Glycols; Hydrogenation; Lactones; Levulinic Acids	2016

Other Studies

23 other study(ies) available for gamma-valerolactone and levulinic acid

Article	Year
Biosynthesis of poly(4-hydroxybutyric acid) by recombinant strains of Escherichia coli. FEMS microbiology letters, 1997, Aug-15, Volume: 153, Issue:2 Topics: 4-Butyrolactone; Acetyl-CoA C-Acyltransferase; Acyltransferases; Coenzyme A-Transferases; Escherichia coli; Genes, Bacterial; Glucose; Hydroxybutyrates; Lactones; Levulinic Acids; Polyesters; Recombinant Fusion Proteins; Sodium Oxybate; Succinates; Valerates	1997
Maximising opportunities in supercritical chemistry: the continuous conversion of levulinic acid to gamma-valerolactone in CO(2). Chemical communications (Cambridge, England), 2007, Nov-28, Issue:44 Topics: Carbon Dioxide; Hydrogenation; Lactones; Levulinic Acids; Molecular Structure; Water	2007
Catalytic conversion of biomass-derived carbohydrates into gamma-valerolactone without using an external H2 supply. Angewandte Chemie (International ed. in English), 2009, Volume: 48, Issue:35 Topics: Biomass; Carbohydrate Metabolism; Catalysis; Formates; Lactones; Levulinic Acids	2009
Chemistry. Connecting biomass and petroleum processing with a chemical bridge. Science (New York, N.Y.), 2010, Jul-30, Volume: 329, Issue:5991 Topics: Biofuels; Biomass; Catalysis; Lactones; Levulinic Acids; Pentanoic Acids; Petroleum	2010
Conversion of levulinic acid and formic acid into γ-valerolactone over heterogeneous catalysts. ChemSusChem, 2010, Oct-25, Volume: 3, Issue:10 Topics: Biomass; Catalysis; Formates; Gas Chromatography-Mass Spectrometry; Hydrogenation; Lactones; Levulinic Acids; Phosphates; Ruthenium; Silicon Dioxide; Time Factors	2010
Selective homogeneous hydrogenation of biogenic carboxylic acids with [Ru(TriPhos)H]+: a mechanistic study. Journal of the American Chemical Society, 2011, Sep-14, Volume: 133, Issue:36 Topics: Catalysis; Ethers, Cyclic; Hydrogenation; Lactones; Levulinic Acids; Ruthenium Compounds; Succinates	2011
Liquid-phase catalytic transfer hydrogenation and cyclization of levulinic acid and its esters to γ-valerolactone over metal oxide catalysts. Chemical communications (Cambridge, England), 2011, Nov-28, Volume: 47, Issue:44 Topics: Alcohols; Catalysis; Cyclization; Esters; Hydrogenation; Lactones; Levulinic Acids; Zirconium	2011
Electricity storage in biofuels: selective electrocatalytic reduction of levulinic acid to valeric acid or γ-valerolactone. ChemSusChem, 2013, Volume: 6, Issue:4 Topics: Biofuels; Catalysis; Electricity; Electrodes; Lactones; Lead; Levulinic Acids; Oxidation-Reduction; Pentanoic Acids	2013
Production of 4-valerolactone by an equilibrium-limited transformation in a partitioning bioreactor: impact of absorptive polymer properties. Bioprocess and biosystems engineering, 2014, Volume: 37, Issue:3 Topics: Bioreactors; Biotransformation; Hydrophobic and Hydrophilic Interactions; Lactones; Levulinic Acids; Polymers	2014
Role of water in metal catalyst performance for ketone hydrogenation: a joint experimental and theoretical study on levulinic acid conversion into gamma-valerolactone. Chemical communications (Cambridge, England), 2014, Oct-25, Volume: 50, Issue:83 Topics: Catalysis; Hydrogenation; Ketones; Lactones; Levulinic Acids; Models, Molecular; Water	2014
Titania-Supported Catalysts for Levulinic Acid Hydrogenation: Influence of Support and its Impact on γ-Valerolactone Yield. ChemSusChem, 2015, May-11, Volume: 8, Issue:9 Topics: Catalysis; Hydrogenation; Lactones; Levulinic Acids; Temperature; Titanium; Water	2015
Acid-functionalized mesoporous carbon: an efficient support for ruthenium-catalyzed γ-valerolactone production. ChemSusChem, 2015, Aug-10, Volume: 8, Issue:15 Topics: Carbon; Catalysis; Hydrogenation; Lactones; Levulinic Acids; Porosity; Ruthenium	2015
Conversion of levulinic acid into γ-valerolactone using Fe3(CO)12: mimicking a biorefinery setting by exploiting crude liquors from biomass acid hydrolysis. Chemical communications (Cambridge, England), 2015, Sep-28, Volume: 51, Issue:75 Topics: Biomass; Catalysis; Formates; Hydrolysis; Iron Compounds; Lactones; Levulinic Acids; Molecular Structure	2015
Microwave-Assisted γ-Valerolactone Production for Biomass Lignin Extraction: A Cascade Protocol. Molecules (Basel, Switzerland), 2016, Mar-26, Volume: 21, Issue:4 Topics: Biofuels; Biomass; Hydrogenation; Hydrolysis; Lactones; Levulinic Acids; Lignin; Microwaves; Solvents	2016
Preparation of Ru/Graphene using Glucose as Carbon Source and Hydrogenation of Levulinic Acid to γ-Valerolactone. Chemistry, an Asian journal, 2016, Oct-06, Volume: 11, Issue:19 Topics: Carbon; Catalysis; Glucose; Graphite; Hydrogenation; Lactones; Levulinic Acids; Particle Size; Photoelectron Spectroscopy; Ruthenium; Spectrum Analysis, Raman; Temperature; X-Ray Diffraction	2016
The Role of the Hydrogen Source on the Selective Production of γ-Valerolactone and 2-Methyltetrahydrofuran from Levulinic Acid. ChemSusChem, 2016, 09-08, Volume: 9, Issue:17 Topics: Atmosphere; Furans; Hydrogen; Hydrogenation; Lactones; Levulinic Acids; Nitrogen; Pressure	2016
An Efficient and Reusable Embedded Ru Catalyst for the Hydrogenolysis of Levulinic Acid to γ-Valerolactone. ChemSusChem, 2017, 04-22, Volume: 10, Issue:8 Topics: Catalysis; Hydrogen; Lactones; Levulinic Acids; Microscopy, Electron, Transmission; Photoelectron Spectroscopy; Porosity; Ruthenium; Surface Properties; Thermodynamics; X-Ray Diffraction	2017
Water-born zirconium-based metal organic frameworks as green and effective catalysts for catalytic transfer hydrogenation of levulinic acid to γ-valerolactone: Critical roles of modulators. Journal of colloid and interface science, 2019, May-01, Volume: 543 Topics: Catalysis; Hydrogenation; Lactones; Levulinic Acids; Metal-Organic Frameworks; Particle Size; Surface Properties; Water; Zirconium	2019
Biomass derived efficient conversion of levulinic acid for sustainable production of γ-valerolactone over cobalt based catalyst. Journal of hazardous materials, 2021, 03-05, Volume: 405 Topics: Biomass; Catalysis; Cobalt; Lactones; Levulinic Acids	2021
Efficient Conversion of Biomass-Derived Levulinic Acid to γ-Valerolactone over Polyoxometalate@Zr-Based Metal-Organic Frameworks: The Synergistic Effect of Bro̷nsted and Lewis Acidic Sites. Inorganic chemistry, 2021, Jun-07, Volume: 60, Issue:11 Topics: 2-Propanol; Biomass; Lactones; Levulinic Acids; Lewis Acids; Metal-Organic Frameworks; Models, Molecular; Molecular Structure; Tungsten Compounds; Zirconium	2021
Ru@hyperbranched Polymer for Hydrogenation of Levulinic Acid to Gamma-Valerolactone: The Role of the Catalyst Support. International journal of molecular sciences, 2022, Jan-12, Volume: 23, Issue:2 Topics: Catalysis; Cellulose; Hydrogenation; Lactones; Levulinic Acids; Molecular Structure; Polymers; Ruthenium; Spectrum Analysis; Temperature	2022
Ru nanoparticles anchored on porous N-doped carbon nanospheres for efficient catalytic hydrogenation of Levulinic acid to γ-valerolactone under solvent-free conditions. Journal of colloid and interface science, 2022, Volume: 623 Topics: Hydrogenation; Lactones; Levulinic Acids; Nanospheres; Nanotubes, Carbon; Porosity; Solvents	2022
Catalytic hydrogenation of levulinic acid to γ-valerolactone over lignin-metal coordinated carbon nanospheres in water. International journal of biological macromolecules, 2023, Jun-15, Volume: 240 Topics: Cetrimonium; Hydrogenation; Levulinic Acids; Lignin; Metals; Nanospheres; Water	2023