Room‐Temperature Formate Ester Transfer Hydrogenation Enables an Electrochemical/Thermal Organometallic Cascade for Methanol Synthesis from CO2
Fernández S, Assaf E, Ahmad S, Travis B, Curley J, Hazari N, Ertem M, Miller A. Room‐Temperature Formate Ester Transfer Hydrogenation Enables an Electrochemical/Thermal Organometallic Cascade for Methanol Synthesis from CO2. Angewandte Chemie International Edition 2024, e202416061. PMID: 39571086, DOI: 10.1002/anie.202416061.Peer-Reviewed Original ResearchTransfer hydrogenationMethanol synthesisIsopropyl formateReduction of CO2 to methanolCO2 reduction to formateCO2 to methanolHydrogen bonding interactionsReduction to formateFormate to methanolEnergy-dense liquid fuelsRoom temperature reductionMulticatalyst systemsOrganometallic catalystsOrganometallic reactionsFormate ionTrifluoromethanesulfonic acidBonding interactionsFischer esterificationFormate estersIsopropanol solventHydrogenMethanolEster substratesElectrocatalystsEnergy storageRoom‐Temperature Formate Ester Transfer Hydrogenation Enables an Electrochemical/Thermal Organometallic Cascade for Methanol Synthesis from CO2
Fernández S, Assaf E, Ahmad S, Travis B, Curley J, Hazari N, Ertem M, Miller A. Room‐Temperature Formate Ester Transfer Hydrogenation Enables an Electrochemical/Thermal Organometallic Cascade for Methanol Synthesis from CO2. Angewandte Chemie 2024 DOI: 10.1002/ange.202416061.Peer-Reviewed Original ResearchTransfer hydrogenationMethanol synthesisIsopropyl formateReduction of CO2 to methanolCO2 reduction to formateCO2 to methanolHydrogen bonding interactionsReduction to formateFormate to methanolEnergy-dense liquid fuelsRoom temperature reductionMulticatalyst systemsOrganometallic catalystsOrganometallic reactionsFormate ionTrifluoromethanesulfonic acidBonding interactionsFischer esterificationFormate estersIsopropanol solventHydrogenMethanolEster substratesElectrocatalystsEnergy storage