Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition
- Autores
- Frechero, Marisa Alejandra; Tulandy, Eider Iván Vivas; García Muriel, Alvaro
- Año de publicación
- 2019
- Idioma
- español castellano
- Tipo de recurso
- documento de conferencia
- Estado
- versión publicada
- Descripción
- Silver iodide (AgI) is one of the most extensively studied superionic conductors. In this work, we have applied the standard Buckingham pair potential and standard charge. For the first time, the microscopic dynamic events that allow the achievement of the superionic transition are revealed. A collaborative effect among cations and anions that makes possible the hopping mechanism within the appropriate timescale is revealed. One of the most accepted explanations states that the Ag+ moves easily through the lattice, described as a molten sub-lattice of Ag+ ions, and that the high conductivity of α-AgI is achieved owing to: a) the low charge cation and the large number of vacant sites available for the cations to move; b) the open framework; c) the low ion coordination which involves a low activation energy; and d) the polarizable anions that facilitate the displacement of cations. Though this explanation appears to be accurate the question of what removes those constrains on the dynamic of the silver cation allowing its ionic conductivity value to be incremented by several magnitude orders is still open. The present work is focused on applying the molecular dynamics formalism to reveal the structural features that cause this property change. The study of the movement of the silver iodide ions applying the Molecular Dynamics formalism, in terms of atom interactions through the most common pair potential Buckingham, allows us to reproduce the experimental behavior expected in its electrical conductivity. Empirical models such as the Universal Dielectric Response and the Jump Relaxation Model describe the charge carrier behavior in a solid matrix without a microscopic description of the transport phenomenon. However, even the dynamic heterogeneity model interpretation could be useful to analyze the AgI dynamic, the evidence given in this work of different kind of mobile cations and its collaborative mechanism with the anions (iodide) allows us to confirm the importance of those distinguishable cations jumps that in the context of the Anderson-Stuart’s activation energy calculation, a very traditional model applied to a solid ionic conductors, evidences the need for the iodide-silver mutual dynamic interaction. The purpose of this work is to shed light on the current knowledge related to the transport phenomena and the relaxation phenomena in the paradigmatic solid ionic conductor, the AgI, from a very detailed microscopic point of view. We were able to evidence the collaborative movement between the cations and the anions which is responsible of the superionic transition when the phase transition occurs. We also showed not only the hopping mechanism involved but also its mechanism at the appropriate timescale.
Fil: Frechero, Marisa Alejandra. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Instituto de Química del Sur. Universidad Nacional del Sur. Departamento de Química. Instituto de Química del Sur; Argentina
Fil: Tulandy, Eider Iván Vivas. Universidad de Cartagena.; Colombia
Fil: García Muriel, Alvaro. Universidad de Cartagena.; Colombia
XVII Taller Regional de Física Estadística y Aplicaciones a la Materia Condensada. TREFEMAC
San Luis
Argentina
Universidad Nacional de San Luis. Facultad de Ciencias Físico Matemáticas y Naturales. Instituto de Física Aplicada "Dr. Jorge Andrés Zgrablich" - Materia
-
IONIC CONDUCTIVITY
MOLECULAR DYNAMIC SIMULATION
SILVER IODIDE - Nivel de accesibilidad
- acceso abierto
- Condiciones de uso
- https://creativecommons.org/licenses/by-nc-sa/2.5/ar/
- Repositorio
.jpg)
- Institución
- Consejo Nacional de Investigaciones Científicas y Técnicas
- OAI Identificador
- oai:ri.conicet.gov.ar:11336/231550
Ver los metadatos del registro completo
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Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transitionFrechero, Marisa AlejandraTulandy, Eider Iván VivasGarcía Muriel, AlvaroIONIC CONDUCTIVITYMOLECULAR DYNAMIC SIMULATIONSILVER IODIDEhttps://purl.org/becyt/ford/1.3https://purl.org/becyt/ford/1Silver iodide (AgI) is one of the most extensively studied superionic conductors. In this work, we have applied the standard Buckingham pair potential and standard charge. For the first time, the microscopic dynamic events that allow the achievement of the superionic transition are revealed. A collaborative effect among cations and anions that makes possible the hopping mechanism within the appropriate timescale is revealed. One of the most accepted explanations states that the Ag+ moves easily through the lattice, described as a molten sub-lattice of Ag+ ions, and that the high conductivity of α-AgI is achieved owing to: a) the low charge cation and the large number of vacant sites available for the cations to move; b) the open framework; c) the low ion coordination which involves a low activation energy; and d) the polarizable anions that facilitate the displacement of cations. Though this explanation appears to be accurate the question of what removes those constrains on the dynamic of the silver cation allowing its ionic conductivity value to be incremented by several magnitude orders is still open. The present work is focused on applying the molecular dynamics formalism to reveal the structural features that cause this property change. The study of the movement of the silver iodide ions applying the Molecular Dynamics formalism, in terms of atom interactions through the most common pair potential Buckingham, allows us to reproduce the experimental behavior expected in its electrical conductivity. Empirical models such as the Universal Dielectric Response and the Jump Relaxation Model describe the charge carrier behavior in a solid matrix without a microscopic description of the transport phenomenon. However, even the dynamic heterogeneity model interpretation could be useful to analyze the AgI dynamic, the evidence given in this work of different kind of mobile cations and its collaborative mechanism with the anions (iodide) allows us to confirm the importance of those distinguishable cations jumps that in the context of the Anderson-Stuart’s activation energy calculation, a very traditional model applied to a solid ionic conductors, evidences the need for the iodide-silver mutual dynamic interaction. The purpose of this work is to shed light on the current knowledge related to the transport phenomena and the relaxation phenomena in the paradigmatic solid ionic conductor, the AgI, from a very detailed microscopic point of view. We were able to evidence the collaborative movement between the cations and the anions which is responsible of the superionic transition when the phase transition occurs. We also showed not only the hopping mechanism involved but also its mechanism at the appropriate timescale.Fil: Frechero, Marisa Alejandra. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Instituto de Química del Sur. Universidad Nacional del Sur. Departamento de Química. Instituto de Química del Sur; ArgentinaFil: Tulandy, Eider Iván Vivas. Universidad de Cartagena.; ColombiaFil: García Muriel, Alvaro. Universidad de Cartagena.; ColombiaXVII Taller Regional de Física Estadística y Aplicaciones a la Materia Condensada. TREFEMACSan LuisArgentinaUniversidad Nacional de San Luis. Facultad de Ciencias Físico Matemáticas y Naturales. Instituto de Física Aplicada "Dr. Jorge Andrés Zgrablich"Universidad de San Luis2019info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/conferenceObjectTallerBookhttp://purl.org/coar/resource_type/c_5794info:ar-repo/semantics/documentoDeConferenciaapplication/pdfapplication/vnd.openxmlformats-officedocument.wordprocessingml.documentapplication/pdfhttp://hdl.handle.net/11336/231550Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition; XVII Taller Regional de Física Estadística y Aplicaciones a la Materia Condensada. 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| dc.title.none.fl_str_mv |
Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition |
| title |
Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition |
| spellingShingle |
Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition Frechero, Marisa Alejandra IONIC CONDUCTIVITY MOLECULAR DYNAMIC SIMULATION SILVER IODIDE |
| title_short |
Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition |
| title_full |
Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition |
| title_fullStr |
Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition |
| title_full_unstemmed |
Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition |
| title_sort |
Anion-cation dynamic cooperation in a paradigmatic ionic conductor around its superionic transition |
| dc.creator.none.fl_str_mv |
Frechero, Marisa Alejandra Tulandy, Eider Iván Vivas García Muriel, Alvaro |
| author |
Frechero, Marisa Alejandra |
| author_facet |
Frechero, Marisa Alejandra Tulandy, Eider Iván Vivas García Muriel, Alvaro |
| author_role |
author |
| author2 |
Tulandy, Eider Iván Vivas García Muriel, Alvaro |
| author2_role |
author author |
| dc.subject.none.fl_str_mv |
IONIC CONDUCTIVITY MOLECULAR DYNAMIC SIMULATION SILVER IODIDE |
| topic |
IONIC CONDUCTIVITY MOLECULAR DYNAMIC SIMULATION SILVER IODIDE |
| purl_subject.fl_str_mv |
https://purl.org/becyt/ford/1.3 https://purl.org/becyt/ford/1 |
| dc.description.none.fl_txt_mv |
Silver iodide (AgI) is one of the most extensively studied superionic conductors. In this work, we have applied the standard Buckingham pair potential and standard charge. For the first time, the microscopic dynamic events that allow the achievement of the superionic transition are revealed. A collaborative effect among cations and anions that makes possible the hopping mechanism within the appropriate timescale is revealed. One of the most accepted explanations states that the Ag+ moves easily through the lattice, described as a molten sub-lattice of Ag+ ions, and that the high conductivity of α-AgI is achieved owing to: a) the low charge cation and the large number of vacant sites available for the cations to move; b) the open framework; c) the low ion coordination which involves a low activation energy; and d) the polarizable anions that facilitate the displacement of cations. Though this explanation appears to be accurate the question of what removes those constrains on the dynamic of the silver cation allowing its ionic conductivity value to be incremented by several magnitude orders is still open. The present work is focused on applying the molecular dynamics formalism to reveal the structural features that cause this property change. The study of the movement of the silver iodide ions applying the Molecular Dynamics formalism, in terms of atom interactions through the most common pair potential Buckingham, allows us to reproduce the experimental behavior expected in its electrical conductivity. Empirical models such as the Universal Dielectric Response and the Jump Relaxation Model describe the charge carrier behavior in a solid matrix without a microscopic description of the transport phenomenon. However, even the dynamic heterogeneity model interpretation could be useful to analyze the AgI dynamic, the evidence given in this work of different kind of mobile cations and its collaborative mechanism with the anions (iodide) allows us to confirm the importance of those distinguishable cations jumps that in the context of the Anderson-Stuart’s activation energy calculation, a very traditional model applied to a solid ionic conductors, evidences the need for the iodide-silver mutual dynamic interaction. The purpose of this work is to shed light on the current knowledge related to the transport phenomena and the relaxation phenomena in the paradigmatic solid ionic conductor, the AgI, from a very detailed microscopic point of view. We were able to evidence the collaborative movement between the cations and the anions which is responsible of the superionic transition when the phase transition occurs. We also showed not only the hopping mechanism involved but also its mechanism at the appropriate timescale. Fil: Frechero, Marisa Alejandra. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Instituto de Química del Sur. Universidad Nacional del Sur. Departamento de Química. Instituto de Química del Sur; Argentina Fil: Tulandy, Eider Iván Vivas. Universidad de Cartagena.; Colombia Fil: García Muriel, Alvaro. Universidad de Cartagena.; Colombia XVII Taller Regional de Física Estadística y Aplicaciones a la Materia Condensada. TREFEMAC San Luis Argentina Universidad Nacional de San Luis. Facultad de Ciencias Físico Matemáticas y Naturales. Instituto de Física Aplicada "Dr. Jorge Andrés Zgrablich" |
| description |
Silver iodide (AgI) is one of the most extensively studied superionic conductors. In this work, we have applied the standard Buckingham pair potential and standard charge. For the first time, the microscopic dynamic events that allow the achievement of the superionic transition are revealed. A collaborative effect among cations and anions that makes possible the hopping mechanism within the appropriate timescale is revealed. One of the most accepted explanations states that the Ag+ moves easily through the lattice, described as a molten sub-lattice of Ag+ ions, and that the high conductivity of α-AgI is achieved owing to: a) the low charge cation and the large number of vacant sites available for the cations to move; b) the open framework; c) the low ion coordination which involves a low activation energy; and d) the polarizable anions that facilitate the displacement of cations. Though this explanation appears to be accurate the question of what removes those constrains on the dynamic of the silver cation allowing its ionic conductivity value to be incremented by several magnitude orders is still open. The present work is focused on applying the molecular dynamics formalism to reveal the structural features that cause this property change. The study of the movement of the silver iodide ions applying the Molecular Dynamics formalism, in terms of atom interactions through the most common pair potential Buckingham, allows us to reproduce the experimental behavior expected in its electrical conductivity. Empirical models such as the Universal Dielectric Response and the Jump Relaxation Model describe the charge carrier behavior in a solid matrix without a microscopic description of the transport phenomenon. However, even the dynamic heterogeneity model interpretation could be useful to analyze the AgI dynamic, the evidence given in this work of different kind of mobile cations and its collaborative mechanism with the anions (iodide) allows us to confirm the importance of those distinguishable cations jumps that in the context of the Anderson-Stuart’s activation energy calculation, a very traditional model applied to a solid ionic conductors, evidences the need for the iodide-silver mutual dynamic interaction. The purpose of this work is to shed light on the current knowledge related to the transport phenomena and the relaxation phenomena in the paradigmatic solid ionic conductor, the AgI, from a very detailed microscopic point of view. We were able to evidence the collaborative movement between the cations and the anions which is responsible of the superionic transition when the phase transition occurs. We also showed not only the hopping mechanism involved but also its mechanism at the appropriate timescale. |
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