Hydrothermal Organic Reduction and Deoxygenation

Hydrothermal Organic Reduction and Deoxygenation

abstract: Organic reactions in natural hydrothermal settings have relevance toward the deep carbon cycle, petroleum formation, the ecology of deep microbial communities, and potentially the origin of life. Many reaction pathways involving organic compounds under geochemically relevant hydrothermal...

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Other Authors: Bockisch, Christiana (Author)
Format: Doctoral Thesis
Language:English
Published: 2018
Subjects:
Organic chemistry
Environmental science
Alternative energy
Biofuels
Catalysis
Geochemistry
Hydrothermal
Online Access:http://hdl.handle.net/2286/R.I.49165
id ndltd-asu.edu-item-49165
record_format oai_dc
spelling ndltd-asu.edu-item-491652018-06-22T03:09:25Z Hydrothermal Organic Reduction and Deoxygenation abstract: Organic reactions in natural hydrothermal settings have relevance toward the deep carbon cycle, petroleum formation, the ecology of deep microbial communities, and potentially the origin of life. Many reaction pathways involving organic compounds under geochemically relevant hydrothermal conditions have now been characterized, but their mechanisms, in particular those involving mineral surface catalysis, are largely unknown. The overall goal of this work is to describe these mechanisms so that predictive models of reactivity can be developed and so that applications of these reactions beyond geochemistry can be explored. The focus of this dissertation is the mechanisms of hydrothermal dehydration and catalytic hydrogenation reactions. Kinetic and structure/activity relationships show that elimination occurs mainly by the E1 mechanism for simple alcohols via homogeneous catalysis. Stereochemical probes show that hydrogenation on nickel occurs on the metal surface. By combining dehydration with and catalytic reduction, effective deoxygenation of organic structures with various functional groups such as alkenes, polyols, ketones, and carboxylic acids can be accomplished under hydrothermal conditions, using either nickel or copper-zinc alloy. These geomimetic reactions can potentially be used in biomass reduction to generate useful fuels and other high value chemicals. Through the use of earth-abundant metal catalysts, and water as the solvent, the reactions presented in this dissertation are a green alternative to current biomass deoxygenation/reduction methods, which often use exotic, rare-metal catalysts, and organic solvents. Dissertation/Thesis Bockisch, Christiana (Author) Gould, Ian R (Advisor) Hartnett, Hilairy E (Committee member) Shock, Everett L (Committee member) Arizona State University (Publisher) Organic chemistry Environmental science Alternative energy Biofuels Catalysis Geochemistry Hydrothermal eng 220 pages Doctoral Dissertation Chemistry 2018 Doctoral Dissertation http://hdl.handle.net/2286/R.I.49165 http://rightsstatements.org/vocab/InC/1.0/ All Rights Reserved 2018
collection NDLTD
language English
format Doctoral Thesis
sources NDLTD
topic Organic chemistry
Environmental science
Alternative energy
Biofuels
Catalysis
Geochemistry
Hydrothermal
spellingShingle Organic chemistry
Environmental science
Alternative energy
Biofuels
Catalysis
Geochemistry
Hydrothermal
Hydrothermal Organic Reduction and Deoxygenation
description abstract: Organic reactions in natural hydrothermal settings have relevance toward the deep carbon cycle, petroleum formation, the ecology of deep microbial communities, and potentially the origin of life. Many reaction pathways involving organic compounds under geochemically relevant hydrothermal conditions have now been characterized, but their mechanisms, in particular those involving mineral surface catalysis, are largely unknown. The overall goal of this work is to describe these mechanisms so that predictive models of reactivity can be developed and so that applications of these reactions beyond geochemistry can be explored. The focus of this dissertation is the mechanisms of hydrothermal dehydration and catalytic hydrogenation reactions. Kinetic and structure/activity relationships show that elimination occurs mainly by the E1 mechanism for simple alcohols via homogeneous catalysis. Stereochemical probes show that hydrogenation on nickel occurs on the metal surface. By combining dehydration with and catalytic reduction, effective deoxygenation of organic structures with various functional groups such as alkenes, polyols, ketones, and carboxylic acids can be accomplished under hydrothermal conditions, using either nickel or copper-zinc alloy. These geomimetic reactions can potentially be used in biomass reduction to generate useful fuels and other high value chemicals. Through the use of earth-abundant metal catalysts, and water as the solvent, the reactions presented in this dissertation are a green alternative to current biomass deoxygenation/reduction methods, which often use exotic, rare-metal catalysts, and organic solvents. === Dissertation/Thesis === Doctoral Dissertation Chemistry 2018
author2 Bockisch, Christiana (Author)
author_facet Bockisch, Christiana (Author)
title Hydrothermal Organic Reduction and Deoxygenation
title_short Hydrothermal Organic Reduction and Deoxygenation
title_full Hydrothermal Organic Reduction and Deoxygenation
title_fullStr Hydrothermal Organic Reduction and Deoxygenation
title_full_unstemmed Hydrothermal Organic Reduction and Deoxygenation
title_sort hydrothermal organic reduction and deoxygenation
publishDate 2018
url http://hdl.handle.net/2286/R.I.49165
_version_ 1718701753211289600

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