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Engineering Nanoelectrocatalytic Systems for CO2 and Nitrate Conversion into Value-Added Chemicals

The thesis addresses two major related environmental crises: nitrate pollution of water systems and the ever-increasing levels of atmospheric carbon dioxide. Both challenges are closely linked to anthropogenic disturbance of nitrogen and carbon cycles and require sustainable, energy efficient mitiga...

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Main Author: Abdelmohsen, Abdelrahman Mohamed
Format: Thesis
Published: AUC Knowledge Fountain 2026
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access_status_str Open Access
author Abdelmohsen, Abdelrahman Mohamed
author_browse Abdelmohsen, Abdelrahman Mohamed
author_facet Abdelmohsen, Abdelrahman Mohamed
author_sort Abdelmohsen, Abdelrahman Mohamed
collection Thesis
description The thesis addresses two major related environmental crises: nitrate pollution of water systems and the ever-increasing levels of atmospheric carbon dioxide. Both challenges are closely linked to anthropogenic disturbance of nitrogen and carbon cycles and require sustainable, energy efficient mitigation techniques. In this study, we investigate electrochemical conversion routes as a unified approach to convert these pollutants into value-added compounds: ammonia (NH3) via nitrate reduction (NO3-RR) and ethylene (C2H4) via carbon dioxide reduction (CO2RR). The first half of this work deals with the design and engineering of Cu-Zn alloy electrocatalysts for efficient NO3-RR. Tuning the alloy composition and surface nanostructure improved the catalytic activity, selectivity, and stability for ammonia generation. The improved activity is ascribed to the synergistic effect of Cu and Zn, which modulate the adsorption energies of crucial reaction intermediates, promote hydrogenation pathways, and inhibit the competing hydrogen evolution reaction. Atomistic insights into the reaction mechanism were obtained from density functional theory (DFT) calculations, which revealed modulation of the electronic structure and the adsorption energetics of nitrogen-containing intermediates, explaining the experimentally observed enhancement in catalytic performance. The second half focuses on nanostructured copper-based catalysts, namely copper nanofiber architectures, for selective CO2 electroreduction to multi-carbon (C2+) products. The nanofiber shape provides a large surface area and numerous active sites, facilitating improved CO adsorption and promoting C-C coupling, a crucial step toward ethylene production. Furthermore, the DFT analysis reveals the chemical pathways and identifies the critical intermediates that drive the C–C bond formation, thereby providing a mechanistic insight into the enhanced selectivity for ethylene. This work further integrates basic electrochemical concepts, catalyst design techniques, and system-level considerations (e.g., electrolyzer topologies and reaction conditions) to provide a comprehensive understanding of NO3-RR and CO2RR processes. Combining experimental electrochemical analysis and theoretical modeling, the structure-activity-selectivity correlations in both systems are established. In summary, this thesis demonstrates the rational design of catalysts, guided by theoretical insights from DFT simulations, to efficiently convert nitrogen and carbon pollution into useful chemical products. These findings, in combination, call for the development of sustainable circular techniques in both environmental remediation and energy conversion, furthering the practical deployment of electrochemical technology.
format Thesis
id oai:fount.aucegypt.edu:etds-3892
institution American University in Cairo (Egypt)
last_indexed 2026-07-01T04:02:58.628Z
license_str Not specified — see source repository
provenance_str_mv Harvested via OAI-PMH from AUC Knowledge Fountain — bepress
publishDate 2026
publishDateRange 2026
publishDateSort 2026
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source_str AUC Knowledge Fountain — bepress
spelling oai:fount.aucegypt.edu:etds-3892 Engineering Nanoelectrocatalytic Systems for CO2 and Nitrate Conversion into Value-Added Chemicals Abdelmohsen, Abdelrahman Mohamed The thesis addresses two major related environmental crises: nitrate pollution of water systems and the ever-increasing levels of atmospheric carbon dioxide. Both challenges are closely linked to anthropogenic disturbance of nitrogen and carbon cycles and require sustainable, energy efficient mitigation techniques. In this study, we investigate electrochemical conversion routes as a unified approach to convert these pollutants into value-added compounds: ammonia (NH3) via nitrate reduction (NO3-RR) and ethylene (C2H4) via carbon dioxide reduction (CO2RR). The first half of this work deals with the design and engineering of Cu-Zn alloy electrocatalysts for efficient NO3-RR. Tuning the alloy composition and surface nanostructure improved the catalytic activity, selectivity, and stability for ammonia generation. The improved activity is ascribed to the synergistic effect of Cu and Zn, which modulate the adsorption energies of crucial reaction intermediates, promote hydrogenation pathways, and inhibit the competing hydrogen evolution reaction. Atomistic insights into the reaction mechanism were obtained from density functional theory (DFT) calculations, which revealed modulation of the electronic structure and the adsorption energetics of nitrogen-containing intermediates, explaining the experimentally observed enhancement in catalytic performance. The second half focuses on nanostructured copper-based catalysts, namely copper nanofiber architectures, for selective CO2 electroreduction to multi-carbon (C2+) products. The nanofiber shape provides a large surface area and numerous active sites, facilitating improved CO adsorption and promoting C-C coupling, a crucial step toward ethylene production. Furthermore, the DFT analysis reveals the chemical pathways and identifies the critical intermediates that drive the C–C bond formation, thereby providing a mechanistic insight into the enhanced selectivity for ethylene. This work further integrates basic electrochemical concepts, catalyst design techniques, and system-level considerations (e.g., electrolyzer topologies and reaction conditions) to provide a comprehensive understanding of NO3-RR and CO2RR processes. Combining experimental electrochemical analysis and theoretical modeling, the structure-activity-selectivity correlations in both systems are established. In summary, this thesis demonstrates the rational design of catalysts, guided by theoretical insights from DFT simulations, to efficiently convert nitrogen and carbon pollution into useful chemical products. These findings, in combination, call for the development of sustainable circular techniques in both environmental remediation and energy conversion, furthering the practical deployment of electrochemical technology. 2026-06-15T07:00:00Z thesis application/pdf https://fount.aucegypt.edu/etds/2826 https://fount.aucegypt.edu/context/etds/article/3892/viewcontent/Abdelrahman_Abdelmohsen_s_Thesis.pdf Theses and Dissertations AUC Knowledge Fountain CO2RR NO3-RR Electrocatalysis Copper-Based Catalysts Cu-Zn Alloy Copper Nanofibers Ammonia Synthesis Ethylene Production Density Functional Theory (DFT) ECSA and DRT Chemical Engineering Chemistry Engineering Science and Materials Materials Science and Engineering Physics
spellingShingle CO2RR
NO3-RR
Electrocatalysis
Copper-Based Catalysts
Cu-Zn Alloy
Copper Nanofibers
Ammonia Synthesis
Ethylene Production
Density Functional Theory (DFT)
ECSA
and DRT
Chemical Engineering
Chemistry
Engineering Science and Materials
Materials Science and Engineering
Physics
Abdelmohsen, Abdelrahman Mohamed
Engineering Nanoelectrocatalytic Systems for CO2 and Nitrate Conversion into Value-Added Chemicals
title Engineering Nanoelectrocatalytic Systems for CO2 and Nitrate Conversion into Value-Added Chemicals
title_full Engineering Nanoelectrocatalytic Systems for CO2 and Nitrate Conversion into Value-Added Chemicals
title_fullStr Engineering Nanoelectrocatalytic Systems for CO2 and Nitrate Conversion into Value-Added Chemicals
title_full_unstemmed Engineering Nanoelectrocatalytic Systems for CO2 and Nitrate Conversion into Value-Added Chemicals
title_short Engineering Nanoelectrocatalytic Systems for CO2 and Nitrate Conversion into Value-Added Chemicals
title_sort engineering nanoelectrocatalytic systems for co2 and nitrate conversion into value added chemicals
topic CO2RR
NO3-RR
Electrocatalysis
Copper-Based Catalysts
Cu-Zn Alloy
Copper Nanofibers
Ammonia Synthesis
Ethylene Production
Density Functional Theory (DFT)
ECSA
and DRT
Chemical Engineering
Chemistry
Engineering Science and Materials
Materials Science and Engineering
Physics
url https://fount.aucegypt.edu/etds/2826
https://fount.aucegypt.edu/context/etds/article/3892/viewcontent/Abdelrahman_Abdelmohsen_s_Thesis.pdf
work_keys_str_mv AT abdelmohsenabdelrahmanmohamed engineeringnanoelectrocatalyticsystemsforco2andnitrateconversionintovalueaddedchemicals