Manganese Catalyzed Hydrogenation of Organic Carbonates to Methanol and Alcohols

The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported. Based on the mechanistic investigation, which indicates metal‐ligand cooperation between the manganese center and the N−H group of the pincer...

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Published inAngewandte Chemie International Edition Vol. 57; no. 37; pp. 12076 - 12080
Main Authors Kumar, Amit, Janes, Trevor, Espinosa‐Jalapa, Noel Angel, Milstein, David
Format Journal Article
LanguageEnglish
Published WEINHEIM Wiley 10.09.2018
Wiley Subscription Services, Inc
EditionInternational ed. in English
Subjects
Alcohol
Alcohols
Carbon dioxide
Carbonates
Catalysis
Catalysts
Chemistry
Chemistry, Multidisciplinary
Hydrogenation
Intermediates
Ligands
Manganese
Metals
Methanol
Physical Sciences
Science & Technology
carbon dioxide
LOW-PRESSURE HYDROGENATION
BICARBONATES
DEFINED IRON CATALYST
CO2
carbonates
hydrogenation
DIOXIDE HYDROGENATION
AMINES
methanol
HOMOGENEOUS CATALYSIS
CYCLIC CARBONATES
PINCER COMPLEX
DERIVATIVES
Manganese
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Abstract The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported. Based on the mechanistic investigation, which indicates metal‐ligand cooperation between the manganese center and the N−H group of the pincer ligand, we propose that the hydrogenation of organic carbonates to methanol occurs via formate and aldehyde intermediates. The reaction offers an indirect route for the conversion of CO2 to methanol, which coupled with the use of an earth abundant catalyst, makes the overall process environmentally benign and sustainable. The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol is reported. The reaction is catalyzed by a manganese pincer complex and offers an indirect route to convert CO2 to methanol, making the overall process environmentally benign and sustainable.
AbstractList The first example of a homogeneous catalyst based on an earth-abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported. Based on the mechanistic investigation, which indicates metal-ligand cooperation between the manganese center and the N II group of the pincer ligand, we propose that the hydrogenation of organic carbonates to methanol occurs via formate and aldehyde intermediates. The reaction offers an indirect route for the conversion of CO2 to methanol, which coupled with the use of an earth abundant catalyst, makes the overall process environmentally benign and sustainable.
The first example of a homogeneous catalyst based on an earth-abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported. Based on the mechanistic investigation, which indicates metal-ligand cooperation between the manganese center and the N-H group of the pincer ligand, we propose that the hydrogenation of organic carbonates to methanol occurs via formate and aldehyde intermediates. The reaction offers an indirect route for the conversion of CO2 to methanol, which coupled with the use of an earth abundant catalyst, makes the overall process environmentally benign and sustainable.
The first example of a homogeneous catalyst based on an earth-abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported. Based on the mechanistic investigation, which indicates metal-ligand cooperation between the manganese center and the N-H group of the pincer ligand, we propose that the hydrogenation of organic carbonates to methanol occurs via formate and aldehyde intermediates. The reaction offers an indirect route for the conversion of CO to methanol, which coupled with the use of an earth abundant catalyst, makes the overall process environmentally benign and sustainable.
The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported. Based on the mechanistic investigation, which indicates metal‐ligand cooperation between the manganese center and the N−H group of the pincer ligand, we propose that the hydrogenation of organic carbonates to methanol occurs via formate and aldehyde intermediates. The reaction offers an indirect route for the conversion of CO2 to methanol, which coupled with the use of an earth abundant catalyst, makes the overall process environmentally benign and sustainable. The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol is reported. The reaction is catalyzed by a manganese pincer complex and offers an indirect route to convert CO2 to methanol, making the overall process environmentally benign and sustainable.
The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported. Based on the mechanistic investigation, which indicates metal‐ligand cooperation between the manganese center and the N−H group of the pincer ligand, we propose that the hydrogenation of organic carbonates to methanol occurs via formate and aldehyde intermediates. The reaction offers an indirect route for the conversion of CO2 to methanol, which coupled with the use of an earth abundant catalyst, makes the overall process environmentally benign and sustainable.
Abstract The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported. Based on the mechanistic investigation, which indicates metal‐ligand cooperation between the manganese center and the N−H group of the pincer ligand, we propose that the hydrogenation of organic carbonates to methanol occurs via formate and aldehyde intermediates. The reaction offers an indirect route for the conversion of CO 2 to methanol, which coupled with the use of an earth abundant catalyst, makes the overall process environmentally benign and sustainable.
Author Kumar, Amit
Milstein, David
Espinosa‐Jalapa, Noel Angel
Janes, Trevor
Author_xml – sequence: 1
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  givenname: Noel Angel
  surname: Espinosa‐Jalapa
  fullname: Espinosa‐Jalapa, Noel Angel
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  orcidid: 0000-0002-2320-0262
  surname: Milstein
  fullname: Milstein, David
  email: david.milstein@weizmann.ac.il
  organization: Weizmann Institute of Science
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Issue 37
Keywords carbon dioxide
LOW-PRESSURE HYDROGENATION
BICARBONATES
DEFINED IRON CATALYST
CO2
carbonates
hydrogenation
DIOXIDE HYDROGENATION
AMINES
methanol
HOMOGENEOUS CATALYSIS
CYCLIC CARBONATES
PINCER COMPLEX
DERIVATIVES
Manganese
Language English
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Snippet The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported....
The first example of a homogeneous catalyst based on an earth-abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is reported....
Abstract The first example of a homogeneous catalyst based on an earth‐abundant metal for the hydrogenation of organic carbonates to methanol and alcohols is...
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SubjectTerms Alcohol
Alcohols
Carbon dioxide
Carbonates
Catalysis
Catalysts
Chemistry
Chemistry, Multidisciplinary
Hydrogenation
Intermediates
Ligands
Manganese
Metals
Methanol
Physical Sciences
Science & Technology
Title Manganese Catalyzed Hydrogenation of Organic Carbonates to Methanol and Alcohols
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