Cargando…
Yttrium- and zirconium-decorated Mg(12)O(12)–X (X = Y, Zr) nanoclusters as sensors for diazomethane (CH(2)N(2)) gas
Diazomethane (CH(2)N(2)) presents a notable hazard as a respiratory irritant, resulting in various adverse effects upon exposure. Consequently, there has been increasing concern in the field of environmental research to develop a sensor material that exhibits heightened sensitivity and conductivity...
Autores principales: | , , , , , , , |
---|---|
Formato: | Online Artículo Texto |
Lenguaje: | English |
Publicado: |
The Royal Society of Chemistry
2023
|
Materias: | |
Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10448449/ https://www.ncbi.nlm.nih.gov/pubmed/37636506 http://dx.doi.org/10.1039/d3ra02939e |
_version_ | 1785094735956803584 |
---|---|
author | Gber, Terkumbur E. Louis, Hitler Ngana, Obinna C. Amodu, Ismail O. Ekereke, Ernest E. Benjamin, Innocent Adalikwu, Stephen A. Adeyinka, Adedapo |
author_facet | Gber, Terkumbur E. Louis, Hitler Ngana, Obinna C. Amodu, Ismail O. Ekereke, Ernest E. Benjamin, Innocent Adalikwu, Stephen A. Adeyinka, Adedapo |
author_sort | Gber, Terkumbur E. |
collection | PubMed |
description | Diazomethane (CH(2)N(2)) presents a notable hazard as a respiratory irritant, resulting in various adverse effects upon exposure. Consequently, there has been increasing concern in the field of environmental research to develop a sensor material that exhibits heightened sensitivity and conductivity for the detection and adsorption of this gas. Therefore, this study aims to provide a comprehensive analysis of the geometric structure of three systems: CH(2)N(2)@MgO (C1), CH(2)N(2)@YMgO (CY1), and CH(2)N(2)@ZrMgO (CZ1), in addition to pristine MgO nanocages. The investigation involves a theoretical analysis employing the DFT/ωB97XD method at the GenECP/6-311++G(d,p)/SDD level of theory. Notably, the examination of bond lengths within the MgO cage yielded specific values, including Mg15–O4 (1.896 Å), Mg19–O4 (1.952 Å), and Mg23–O4 (1.952 Å), thereby offering valuable insights into the structural properties and interactions with CH(2)N(2) gas. Intriguingly, after the interaction, bond length variations were observed, with CH(2)N(2)@MgO exhibiting shorter bonds and CH(2)N(2)@YMgO showcasing longer bonds. Meanwhile, CH(2)N(2)@ZrMgO displayed shorter bonds, except for a longer bond in Mg19–O4, suggesting increased stability due to shorter bond distances. The study further investigated the electronic properties, revealing changes in the energy gap that influenced electrical conductivity and sensitivity. The energy gap increased for Zr@MgO, CH(2)N(2)@MgO, CH(2)N(2)@YMgO, and CH(2)N(2)@ZrMgO, indicating weak interactions on the MgO surface. Conversely, Y@MgO showed a decrease in energy, suggesting a strong interaction. The pure MgO surface exhibited the ability to donate and accept electrons, resulting in an energy gap of 4.799 eV. Surfaces decorated with yttrium and zirconium exhibited decreased energies of the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO), as well as decreased energy gap, indicating increased conductivity and sensitivity. Notably, Zr@MgO had the highest energy gap before CH(2)N(2) adsorption, but C1 exhibited a significantly higher energy gap after adsorption, implying increased conductivity and sensitivity. The study also examined the density of states, demonstrating significant variations in the electronic properties of MgO and its decorated surfaces due to CH(2)N(2) adsorption. Moreover, various analysis techniques were employed, including natural bond orbital (NBO), quantum theory of atoms in molecules (QTAIM), and noncovalent interaction (NCI) analysis, which provided insights into bonding, charge density, and intermolecular interactions. The findings contribute to a deeper understanding of the sensing mechanisms of CH(2)N(2) gas on nanocage surfaces, shedding light on adsorption energy, conductivity, and recovery time. These results hold significance for gas-sensing applications and provide a basis for further exploration and development in this field. |
format | Online Article Text |
id | pubmed-10448449 |
institution | National Center for Biotechnology Information |
language | English |
publishDate | 2023 |
publisher | The Royal Society of Chemistry |
record_format | MEDLINE/PubMed |
spelling | pubmed-104484492023-08-25 Yttrium- and zirconium-decorated Mg(12)O(12)–X (X = Y, Zr) nanoclusters as sensors for diazomethane (CH(2)N(2)) gas Gber, Terkumbur E. Louis, Hitler Ngana, Obinna C. Amodu, Ismail O. Ekereke, Ernest E. Benjamin, Innocent Adalikwu, Stephen A. Adeyinka, Adedapo RSC Adv Chemistry Diazomethane (CH(2)N(2)) presents a notable hazard as a respiratory irritant, resulting in various adverse effects upon exposure. Consequently, there has been increasing concern in the field of environmental research to develop a sensor material that exhibits heightened sensitivity and conductivity for the detection and adsorption of this gas. Therefore, this study aims to provide a comprehensive analysis of the geometric structure of three systems: CH(2)N(2)@MgO (C1), CH(2)N(2)@YMgO (CY1), and CH(2)N(2)@ZrMgO (CZ1), in addition to pristine MgO nanocages. The investigation involves a theoretical analysis employing the DFT/ωB97XD method at the GenECP/6-311++G(d,p)/SDD level of theory. Notably, the examination of bond lengths within the MgO cage yielded specific values, including Mg15–O4 (1.896 Å), Mg19–O4 (1.952 Å), and Mg23–O4 (1.952 Å), thereby offering valuable insights into the structural properties and interactions with CH(2)N(2) gas. Intriguingly, after the interaction, bond length variations were observed, with CH(2)N(2)@MgO exhibiting shorter bonds and CH(2)N(2)@YMgO showcasing longer bonds. Meanwhile, CH(2)N(2)@ZrMgO displayed shorter bonds, except for a longer bond in Mg19–O4, suggesting increased stability due to shorter bond distances. The study further investigated the electronic properties, revealing changes in the energy gap that influenced electrical conductivity and sensitivity. The energy gap increased for Zr@MgO, CH(2)N(2)@MgO, CH(2)N(2)@YMgO, and CH(2)N(2)@ZrMgO, indicating weak interactions on the MgO surface. Conversely, Y@MgO showed a decrease in energy, suggesting a strong interaction. The pure MgO surface exhibited the ability to donate and accept electrons, resulting in an energy gap of 4.799 eV. Surfaces decorated with yttrium and zirconium exhibited decreased energies of the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO), as well as decreased energy gap, indicating increased conductivity and sensitivity. Notably, Zr@MgO had the highest energy gap before CH(2)N(2) adsorption, but C1 exhibited a significantly higher energy gap after adsorption, implying increased conductivity and sensitivity. The study also examined the density of states, demonstrating significant variations in the electronic properties of MgO and its decorated surfaces due to CH(2)N(2) adsorption. Moreover, various analysis techniques were employed, including natural bond orbital (NBO), quantum theory of atoms in molecules (QTAIM), and noncovalent interaction (NCI) analysis, which provided insights into bonding, charge density, and intermolecular interactions. The findings contribute to a deeper understanding of the sensing mechanisms of CH(2)N(2) gas on nanocage surfaces, shedding light on adsorption energy, conductivity, and recovery time. These results hold significance for gas-sensing applications and provide a basis for further exploration and development in this field. The Royal Society of Chemistry 2023-08-24 /pmc/articles/PMC10448449/ /pubmed/37636506 http://dx.doi.org/10.1039/d3ra02939e Text en This journal is © The Royal Society of Chemistry https://creativecommons.org/licenses/by-nc/3.0/ |
spellingShingle | Chemistry Gber, Terkumbur E. Louis, Hitler Ngana, Obinna C. Amodu, Ismail O. Ekereke, Ernest E. Benjamin, Innocent Adalikwu, Stephen A. Adeyinka, Adedapo Yttrium- and zirconium-decorated Mg(12)O(12)–X (X = Y, Zr) nanoclusters as sensors for diazomethane (CH(2)N(2)) gas |
title | Yttrium- and zirconium-decorated Mg(12)O(12)–X (X = Y, Zr) nanoclusters as sensors for diazomethane (CH(2)N(2)) gas |
title_full | Yttrium- and zirconium-decorated Mg(12)O(12)–X (X = Y, Zr) nanoclusters as sensors for diazomethane (CH(2)N(2)) gas |
title_fullStr | Yttrium- and zirconium-decorated Mg(12)O(12)–X (X = Y, Zr) nanoclusters as sensors for diazomethane (CH(2)N(2)) gas |
title_full_unstemmed | Yttrium- and zirconium-decorated Mg(12)O(12)–X (X = Y, Zr) nanoclusters as sensors for diazomethane (CH(2)N(2)) gas |
title_short | Yttrium- and zirconium-decorated Mg(12)O(12)–X (X = Y, Zr) nanoclusters as sensors for diazomethane (CH(2)N(2)) gas |
title_sort | yttrium- and zirconium-decorated mg(12)o(12)–x (x = y, zr) nanoclusters as sensors for diazomethane (ch(2)n(2)) gas |
topic | Chemistry |
url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10448449/ https://www.ncbi.nlm.nih.gov/pubmed/37636506 http://dx.doi.org/10.1039/d3ra02939e |
work_keys_str_mv | AT gberterkumbure yttriumandzirconiumdecoratedmg12o12xxyzrnanoclustersassensorsfordiazomethanech2n2gas AT louishitler yttriumandzirconiumdecoratedmg12o12xxyzrnanoclustersassensorsfordiazomethanech2n2gas AT nganaobinnac yttriumandzirconiumdecoratedmg12o12xxyzrnanoclustersassensorsfordiazomethanech2n2gas AT amoduismailo yttriumandzirconiumdecoratedmg12o12xxyzrnanoclustersassensorsfordiazomethanech2n2gas AT ekerekeerneste yttriumandzirconiumdecoratedmg12o12xxyzrnanoclustersassensorsfordiazomethanech2n2gas AT benjamininnocent yttriumandzirconiumdecoratedmg12o12xxyzrnanoclustersassensorsfordiazomethanech2n2gas AT adalikwustephena yttriumandzirconiumdecoratedmg12o12xxyzrnanoclustersassensorsfordiazomethanech2n2gas AT adeyinkaadedapo yttriumandzirconiumdecoratedmg12o12xxyzrnanoclustersassensorsfordiazomethanech2n2gas |