PREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES

PREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES

States (DOS) and Partial density of states (PDOS) analyses reveal that the d orbitals of Ti, Co, Cu, and Ni significantly contribute to peaks near the Fermi level, dominated by the p orbital of the carbon atoms. The d orbitals of Pt symmetrically contribute to peaks in the conduction band, wherea...

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Main Author: Majeed Himat, Abdul
Format: Theses
Language:Indonesia
Online Access:https://digilib.itb.ac.id/gdl/view/81442
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Institution: Institut Teknologi Bandung
Language: Indonesia
id id-itb.:81442
spelling id-itb.:814422024-06-26T13:29:24ZPREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES Majeed Himat, Abdul Indonesia Theses DFT, pristine graphene, single vacancy (SV) graphene, CO2 adsorption, transition metals. INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/81442 States (DOS) and Partial density of states (PDOS) analyses reveal that the d orbitals of Ti, Co, Cu, and Ni significantly contribute to peaks near the Fermi level, dominated by the p orbital of the carbon atoms. The d orbitals of Pt symmetrically contribute to peaks in the conduction band, whereas Zn and Sn’s d orbitals do not. Charge density difference analysis shows negative charge accumulation around all TMs, indicating charge transfer from carbon atoms. This finding confirms that Ti, Ni, Cu, Zn, and Sn have insufficient charge redistribution to induce significant CO2 bending, resulting in weak interactions with CO2. Conversely, Co and Pt on SV graphene demonstrate effective CO2 activation, positioning these configurations as promising candidates for next-generation catalysts in the electrochemical CO2RR. Furthermore, the reduction of CO2 to CO and HCOOH through a two-electron/proton transfer pathway was considered. On Co and Pt catalytic surfaces, we were able to obtain CO and a molecule of water by reducing CO2. The final products (CO + H2O) on the Co catalytic surface are obtained with a reaction energy of -0.443 eV. When reducing CO2 to HCOOH, the reaction requires energies of 0.8525 eV and 0.0828 eV through pathway mechanisms A and B, respectively. On the other hand, for the Pt catalytic surface, the reaction energy for (CO + H2O) was -0.422 eV, and for HCOOH, the reaction energies are 0.1065 eV and 0.7533 eV through pathway mechanism A and B respectively. Pathway A reduces CO2 to HCOOH through a carboxylate intermediate, while Pathway B does so through a formate intermediate. Looking into the high energy activation barrier through formate pathway, makes the reaction kinetically unfavorable. In a conclusion, both CO and formic acid reactions will proceed favorably via the carboxylate intermediate, but not the formate pathway. text
institution Institut Teknologi Bandung
building Institut Teknologi Bandung Library
continent Asia
country Indonesia
Indonesia
content_provider Institut Teknologi Bandung
collection Digital ITB
language Indonesia
description States (DOS) and Partial density of states (PDOS) analyses reveal that the d orbitals of Ti, Co, Cu, and Ni significantly contribute to peaks near the Fermi level, dominated by the p orbital of the carbon atoms. The d orbitals of Pt symmetrically contribute to peaks in the conduction band, whereas Zn and Sn’s d orbitals do not. Charge density difference analysis shows negative charge accumulation around all TMs, indicating charge transfer from carbon atoms. This finding confirms that Ti, Ni, Cu, Zn, and Sn have insufficient charge redistribution to induce significant CO2 bending, resulting in weak interactions with CO2. Conversely, Co and Pt on SV graphene demonstrate effective CO2 activation, positioning these configurations as promising candidates for next-generation catalysts in the electrochemical CO2RR. Furthermore, the reduction of CO2 to CO and HCOOH through a two-electron/proton transfer pathway was considered. On Co and Pt catalytic surfaces, we were able to obtain CO and a molecule of water by reducing CO2. The final products (CO + H2O) on the Co catalytic surface are obtained with a reaction energy of -0.443 eV. When reducing CO2 to HCOOH, the reaction requires energies of 0.8525 eV and 0.0828 eV through pathway mechanisms A and B, respectively. On the other hand, for the Pt catalytic surface, the reaction energy for (CO + H2O) was -0.422 eV, and for HCOOH, the reaction energies are 0.1065 eV and 0.7533 eV through pathway mechanism A and B respectively. Pathway A reduces CO2 to HCOOH through a carboxylate intermediate, while Pathway B does so through a formate intermediate. Looking into the high energy activation barrier through formate pathway, makes the reaction kinetically unfavorable. In a conclusion, both CO and formic acid reactions will proceed favorably via the carboxylate intermediate, but not the formate pathway.
format Theses
author Majeed Himat, Abdul
spellingShingle Majeed Himat, Abdul
PREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES
author_facet Majeed Himat, Abdul
author_sort Majeed Himat, Abdul
title PREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES
title_short PREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES
title_full PREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES
title_fullStr PREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES
title_full_unstemmed PREDICTION OF CO2 REDUCTION REACTION (CO2RR) BY TRANSITION METALS ON SINGLE VACANCY GRAPHENE STRUCTURES
title_sort prediction of co2 reduction reaction (co2rr) by transition metals on single vacancy graphene structures
url https://digilib.itb.ac.id/gdl/view/81442
_version_ 1822997322226728960

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