Oxidant-Free Transformation of Ethylene Glycol toward Glycolic Acid in Water

Zhan, Yueping; Hou, Wenrong; Li, Gang; Shen, Yangbin; Zhang, Yahong; Tang, Yi

doi:10.1021/acssuschemeng.9b04617

Cited by 45 publications

(40 citation statements)

References 38 publications

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“…However, selective dehydrogenation of 1,2-diols suppressing over-oxidation, self-condensation, and polymerization is highly challenging . Additionally, the acceptorless liberation of hydrogen gas is a concern, and a sacrificial hydrogen acceptor is often required for successful catalysis. − The reformation reaction is only studied for the simplest ethylene glycol molecule using precious ruthenium, and platinum metal-derived catalysts by Grützmacher, Milstein, and others (Scheme B). − This too suffers from poor selectivity and reactivity. , While this work is in progress, Xu and Tu elegantly disclosed an iridium-catalyzed transformation of vicinal glycols to α-hydroxy acetates in the presence of oxygen as the terminal hydrogen acceptor . A general synthesis of α-hydroxy acids from readily available glycols utilizing non-noble metal catalysts without the need for an acceptor with high yield and selectivity is the need of the hour.…”

Section: Introductionmentioning

confidence: 99%

Manganese-Catalyzed Reformation of Vicinal Glycols to α-Hydroxy Carboxylic Acids with the Liberation of Hydrogen Gas

2022

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Conversion of readily available feedstocks to valuable platform chemicals via an eco-friendly catalytic pathway has always been one of the key focuses of synthetic chemists. In this context, herein, we report selective transformation of readily available feedstock, vicinal glycols, to value-added α-hydroxycarboxylic acid molecules that are prevalent in bioactive molecules and biodegradable polymers. A bench stable Earth-abundant metal complex, {[HN(C 2 H 4 PPh 2 ) 2 ]Mn(CO) 2 Br}, Mn-I catalyzed the reformation reaction at low temperature in high selectivity with a turnover number reaching 2400, surpassing previously used homogeneous catalysts for such a reaction. Hydrogen gas is evolved as a byproduct without needing an acceptor. The developed protocol is applicable for both aromatic and aliphatic vicinal glycols, delivering the α-substituted hydroxycarboxylic acids in high yields and selectivities. Detailed mechanistic studies elucidated the involvements of different manganese(I)-species during this acceptorless dehydrogenation catalysis.

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Section: Introductionmentioning

confidence: 99%

Manganese-Catalyzed Reformation of Vicinal Glycols to α-Hydroxy Carboxylic Acids with the Liberation of Hydrogen Gas

2022

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“…The development of sustainable and carbon-neutral catalytic processes that use biomass-derived feedstocks is critical to maintain the current size of production and consumption of chemicals without increasing carbon emission. − Sustainable processes include transition metal-catalyzed valorization of biomass resources to produce industrially useful α-hydroxy acids (AHAs). − Commonly used AHAs, glycolic acid (C 2 AHA), and lactic acid (C 3 AHA) have been produced by bacteria-mediated fermentation or the chemical process. − Sustainable carbohydrate feedstocks have also been employed to obtain glycolic acid and lactic acid via metal-catalyzed C–C bond cleavage. , In addition, an Ir-catalyzed synthesis of lactic acid from ethylene glycol and methanol was recently reported . Sn-catalyzed cleavage of glucose and Sn-catalyzed cross-coupling of 1,3-dihydroxyacetone and formaldehyde were used in the synthesis of methyl-4-methoxy-2-hydroxybutanoate and α-hydroxy-γ-butyrolactone (C 4 AHAs), respectively.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of α-Hydroxy Acids via Dehydrogenative Cross-Coupling of a Sustainable C₂ Chemical (Ethylene Glycol) with Alcohols

2022

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Ir(NHC) (NHC, N-heterocyclic carbene)-catalyzed dehydrogenative coupling of sustainable ethylene glycol and various bioalcohols can produce industrially valuable α-hydroxy acids (AHAs). This study is the first to report the sustainable synthesis of higher C n AHAs, in addition to glycolic acid (C2 AHA) and lactic acid (C3 AHA). This catalytic system can be recycled to the seventh cycle while maintaining good yields. A reaction mechanism, including facile dehydrogenation of each alcohol and fast cross-coupling of dehydrogenated aldehydes forming products, was proposed based on 18O- and 2H-labeling experiments and electron spray ionization-mass spectrometry (ESI-MS) and NMR spectral analyses.

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“…The group of Grützmacher reported the oxidative dehydrogenation of alcohols and polyalcohols, including ethylene glycol, to carboxylic acids using a homogeneous rhodium catalyst under mild conditions, albeit in the presence of sacrificial hydrogen acceptors such as ketones or methyl methacrylate [16] . Reforming of ethylene glycol to glycolic acid homogeneously catalyzed by an iridium complex (4 mol %) was reported recently, although the catalytic mechanism was not studied [17] . Very recently, homogeneous iridium‐catalyzed dehydrogenative cross‐coupling of ethylene glycol and methanol to lactic acid was also disclosed by Tu, Xu and co‐workers [18] .…”

Section: Introductionmentioning

confidence: 99%

Homogeneous Reforming of Aqueous Ethylene Glycol to Glycolic Acid and Pure Hydrogen Catalyzed by Pincer‐Ruthenium Complexes Capable of Metal–Ligand Cooperation

Zou

Wolff

Rauch

et al. 2021

Chemistry A European J

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Glycolic acid is a useful and important α‐hydroxy acid that has broad applications. Herein, the homogeneous ruthenium catalyzed reforming of aqueous ethylene glycol to generate glycolic acid as well as pure hydrogen gas, without concomitant CO2 emission, is reported. This approach provides a clean and sustainable direction to glycolic acid and hydrogen, based on inexpensive, readily available, and renewable ethylene glycol using 0.5 mol % of catalyst. In‐depth mechanistic experimental and computational studies highlight key aspects of the PNNH‐ligand framework involved in this transformation.

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Oxidant-Free Transformation of Ethylene Glycol toward Glycolic Acid in Water

Cited by 45 publications

References 38 publications

Manganese-Catalyzed Reformation of Vicinal Glycols to α-Hydroxy Carboxylic Acids with the Liberation of Hydrogen Gas

Manganese-Catalyzed Reformation of Vicinal Glycols to α-Hydroxy Carboxylic Acids with the Liberation of Hydrogen Gas

Synthesis of α-Hydroxy Acids via Dehydrogenative Cross-Coupling of a Sustainable C₂ Chemical (Ethylene Glycol) with Alcohols

Homogeneous Reforming of Aqueous Ethylene Glycol to Glycolic Acid and Pure Hydrogen Catalyzed by Pincer‐Ruthenium Complexes Capable of Metal–Ligand Cooperation

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Oxidant-Free Transformation of Ethylene Glycol toward Glycolic Acid in Water

Cited by 45 publications

References 38 publications

Manganese-Catalyzed Reformation of Vicinal Glycols to α-Hydroxy Carboxylic Acids with the Liberation of Hydrogen Gas

Manganese-Catalyzed Reformation of Vicinal Glycols to α-Hydroxy Carboxylic Acids with the Liberation of Hydrogen Gas

Synthesis of α-Hydroxy Acids via Dehydrogenative Cross-Coupling of a Sustainable C2 Chemical (Ethylene Glycol) with Alcohols

Homogeneous Reforming of Aqueous Ethylene Glycol to Glycolic Acid and Pure Hydrogen Catalyzed by Pincer‐Ruthenium Complexes Capable of Metal–Ligand Cooperation

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Synthesis of α-Hydroxy Acids via Dehydrogenative Cross-Coupling of a Sustainable C₂ Chemical (Ethylene Glycol) with Alcohols