Anomalous electronic properties in layered, disordered ZnVSb
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2021 |
| Outros Autores: | , , , , , , , , , , , , , , , , |
| Tipo de documento: | Artigo |
| Idioma: | eng |
| Título da fonte: | Repositório Institucional da UNESP |
| Texto Completo: | http://dx.doi.org/10.1103/PhysRevMaterials.5.015002 http://hdl.handle.net/11449/207230 |
Resumo: | New materials discovery is the driving force for progress in solid state physics and chemistry. Here we solve the crystal structure and comprehensively study physical properties of ZnVSb in the polycrystalline form. Synchrotron x-ray diffraction reveals that the compound attains a layered ZrSiS-type structure (P4/nmm, a = 4.09021(2) Å, c = 6.42027(4) Å). The unit cell is composed of a 2D vanadium network separated by Zn-Sb blocks that are slightly distorted from the ideal cubic arrangement. A considerable amount of vacancies were observed on the vanadium and antimony positions; the experimental composition is ZnV0.91Sb0.96. Low-temperature x-ray diffraction shows very subtle discontinuity in the lattice parameters around 175 K. Bonding V-V distance is below the critical separation of 2.97 Å known from the literature, which allows for V-V orbital overlap and subsequent metallic conductivity. From ab initio calculations, we found that ZnVSb is a pseudogap material with an expected dominant vanadium contribution to the density of states at the Fermi level. The energy difference between the antiferromagnetic and nonordered magnetic configurations is rather small (0.34 eV/f.u.). X-ray photoelectron spectroscopy fully corroborates the results of the band structure calculations. Magnetic susceptibility uncovered that, in ZnVSb, itinerant charge carriers coexist with a small, localized magnetic moment of ca. 0.25 μB. The itinerant electrons arise from the ordered part of the vanadium lattice. Fractional localization, in turn, was attributed to V atoms neighboring vacancies, which hinder full V-V orbital overlap. Furthermore, the susceptibility and electrical resistivity showed a large hysteresis between 120 K and 160 K. The effect is not sensitive to magnetic fields up to 9 T. Curie-Weiss fitting revealed that the amount of itinerant charge carriers in ZnVSb drops with decreasing temperature below 160 K, which is accompanied by a concurrent rise in the localized magnetic moment. This observation together with the overall shape of the hysteresis in the resistivity allows for suggesting a plausible origin of the effect as a charge-transfer metal-insulator transition. Ab initio phonon calculations show the formation of a collective phonon mode at 2.8 THz (134 K). The experimental heat capacity reflected this feature by a boson peak with Einstein temperature of 116 K. Analysis of the heat capacity with both an ab initio perspective and Debye-Einstein model revealed a sizable anharmonic contribution to heat capacity, in line with disordered nature of the material. Further investigation of the electron and phonon properties for ZnVSb is likely to provide valuable insight into the relation between structural disorder and the physical properties of transition-metal-bearing compounds. |
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Anomalous electronic properties in layered, disordered ZnVSbNew materials discovery is the driving force for progress in solid state physics and chemistry. Here we solve the crystal structure and comprehensively study physical properties of ZnVSb in the polycrystalline form. Synchrotron x-ray diffraction reveals that the compound attains a layered ZrSiS-type structure (P4/nmm, a = 4.09021(2) Å, c = 6.42027(4) Å). The unit cell is composed of a 2D vanadium network separated by Zn-Sb blocks that are slightly distorted from the ideal cubic arrangement. A considerable amount of vacancies were observed on the vanadium and antimony positions; the experimental composition is ZnV0.91Sb0.96. Low-temperature x-ray diffraction shows very subtle discontinuity in the lattice parameters around 175 K. Bonding V-V distance is below the critical separation of 2.97 Å known from the literature, which allows for V-V orbital overlap and subsequent metallic conductivity. From ab initio calculations, we found that ZnVSb is a pseudogap material with an expected dominant vanadium contribution to the density of states at the Fermi level. The energy difference between the antiferromagnetic and nonordered magnetic configurations is rather small (0.34 eV/f.u.). X-ray photoelectron spectroscopy fully corroborates the results of the band structure calculations. Magnetic susceptibility uncovered that, in ZnVSb, itinerant charge carriers coexist with a small, localized magnetic moment of ca. 0.25 μB. The itinerant electrons arise from the ordered part of the vanadium lattice. Fractional localization, in turn, was attributed to V atoms neighboring vacancies, which hinder full V-V orbital overlap. Furthermore, the susceptibility and electrical resistivity showed a large hysteresis between 120 K and 160 K. The effect is not sensitive to magnetic fields up to 9 T. Curie-Weiss fitting revealed that the amount of itinerant charge carriers in ZnVSb drops with decreasing temperature below 160 K, which is accompanied by a concurrent rise in the localized magnetic moment. This observation together with the overall shape of the hysteresis in the resistivity allows for suggesting a plausible origin of the effect as a charge-transfer metal-insulator transition. Ab initio phonon calculations show the formation of a collective phonon mode at 2.8 THz (134 K). The experimental heat capacity reflected this feature by a boson peak with Einstein temperature of 116 K. Analysis of the heat capacity with both an ab initio perspective and Debye-Einstein model revealed a sizable anharmonic contribution to heat capacity, in line with disordered nature of the material. Further investigation of the electron and phonon properties for ZnVSb is likely to provide valuable insight into the relation between structural disorder and the physical properties of transition-metal-bearing compounds.Physics Department Colorado School of MinesInstitute of Low Temperature and Structure Research Polish Academy of SciencesUniversity of Illinois at Urbana-ChampaignInstituto de Física Teórica São Paulo State University (UNESP)University of California Santa BarbaraMax Planck Institute for Chemical Physics of SolidsDepartment of Chemistry and Biochemistry The Ohio State UniversityNational Synchrotron Radiation Research Center (NSRRC)Instituto de Física Teórica São Paulo State University (UNESP)Colorado School of MinesPolish Academy of SciencesUniversity of Illinois at Urbana-ChampaignUniversidade Estadual Paulista (Unesp)University of California Santa BarbaraMax Planck Institute for Chemical Physics of SolidsThe Ohio State UniversityNational Synchrotron Radiation Research Center (NSRRC)Bensen, Erik A.Ciesielski, KamilGomes, Lídia C. [UNESP]Ortiz, Brenden R.Falke, JohannesPavlosiuk, OrestWeber, DanielBraden, Tara L.Steirer, Kenneth X.Szymański, DamianGoldberger, Joshua E.Kuo, Chang-YangChen, Chien-TeChang, Chun-FuTjeng, Liu HaoKaczorowski, DariuszErtekin, ElifToberer, Eric S.2021-06-25T10:51:07Z2021-06-25T10:51:07Z2021-01-01info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/articlehttp://dx.doi.org/10.1103/PhysRevMaterials.5.015002Physical Review Materials, v. 5, n. 1, 2021.2475-9953http://hdl.handle.net/11449/20723010.1103/PhysRevMaterials.5.0150022-s2.0-85100383565Scopusreponame:Repositório Institucional da UNESPinstname:Universidade Estadual Paulista (UNESP)instacron:UNESPengPhysical Review Materialsinfo:eu-repo/semantics/openAccess2021-10-23T16:37:02Zoai:repositorio.unesp.br:11449/207230Repositório InstitucionalPUBhttp://repositorio.unesp.br/oai/requestopendoar:29462024-08-05T20:20:11.826640Repositório Institucional da UNESP - Universidade Estadual Paulista (UNESP)false |
| dc.title.none.fl_str_mv |
Anomalous electronic properties in layered, disordered ZnVSb |
| title |
Anomalous electronic properties in layered, disordered ZnVSb |
| spellingShingle |
Anomalous electronic properties in layered, disordered ZnVSb Bensen, Erik A. |
| title_short |
Anomalous electronic properties in layered, disordered ZnVSb |
| title_full |
Anomalous electronic properties in layered, disordered ZnVSb |
| title_fullStr |
Anomalous electronic properties in layered, disordered ZnVSb |
| title_full_unstemmed |
Anomalous electronic properties in layered, disordered ZnVSb |
| title_sort |
Anomalous electronic properties in layered, disordered ZnVSb |
| author |
Bensen, Erik A. |
| author_facet |
Bensen, Erik A. Ciesielski, Kamil Gomes, Lídia C. [UNESP] Ortiz, Brenden R. Falke, Johannes Pavlosiuk, Orest Weber, Daniel Braden, Tara L. Steirer, Kenneth X. Szymański, Damian Goldberger, Joshua E. Kuo, Chang-Yang Chen, Chien-Te Chang, Chun-Fu Tjeng, Liu Hao Kaczorowski, Dariusz Ertekin, Elif Toberer, Eric S. |
| author_role |
author |
| author2 |
Ciesielski, Kamil Gomes, Lídia C. [UNESP] Ortiz, Brenden R. Falke, Johannes Pavlosiuk, Orest Weber, Daniel Braden, Tara L. Steirer, Kenneth X. Szymański, Damian Goldberger, Joshua E. Kuo, Chang-Yang Chen, Chien-Te Chang, Chun-Fu Tjeng, Liu Hao Kaczorowski, Dariusz Ertekin, Elif Toberer, Eric S. |
| author2_role |
author author author author author author author author author author author author author author author author author |
| dc.contributor.none.fl_str_mv |
Colorado School of Mines Polish Academy of Sciences University of Illinois at Urbana-Champaign Universidade Estadual Paulista (Unesp) University of California Santa Barbara Max Planck Institute for Chemical Physics of Solids The Ohio State University National Synchrotron Radiation Research Center (NSRRC) |
| dc.contributor.author.fl_str_mv |
Bensen, Erik A. Ciesielski, Kamil Gomes, Lídia C. [UNESP] Ortiz, Brenden R. Falke, Johannes Pavlosiuk, Orest Weber, Daniel Braden, Tara L. Steirer, Kenneth X. Szymański, Damian Goldberger, Joshua E. Kuo, Chang-Yang Chen, Chien-Te Chang, Chun-Fu Tjeng, Liu Hao Kaczorowski, Dariusz Ertekin, Elif Toberer, Eric S. |
| description |
New materials discovery is the driving force for progress in solid state physics and chemistry. Here we solve the crystal structure and comprehensively study physical properties of ZnVSb in the polycrystalline form. Synchrotron x-ray diffraction reveals that the compound attains a layered ZrSiS-type structure (P4/nmm, a = 4.09021(2) Å, c = 6.42027(4) Å). The unit cell is composed of a 2D vanadium network separated by Zn-Sb blocks that are slightly distorted from the ideal cubic arrangement. A considerable amount of vacancies were observed on the vanadium and antimony positions; the experimental composition is ZnV0.91Sb0.96. Low-temperature x-ray diffraction shows very subtle discontinuity in the lattice parameters around 175 K. Bonding V-V distance is below the critical separation of 2.97 Å known from the literature, which allows for V-V orbital overlap and subsequent metallic conductivity. From ab initio calculations, we found that ZnVSb is a pseudogap material with an expected dominant vanadium contribution to the density of states at the Fermi level. The energy difference between the antiferromagnetic and nonordered magnetic configurations is rather small (0.34 eV/f.u.). X-ray photoelectron spectroscopy fully corroborates the results of the band structure calculations. Magnetic susceptibility uncovered that, in ZnVSb, itinerant charge carriers coexist with a small, localized magnetic moment of ca. 0.25 μB. The itinerant electrons arise from the ordered part of the vanadium lattice. Fractional localization, in turn, was attributed to V atoms neighboring vacancies, which hinder full V-V orbital overlap. Furthermore, the susceptibility and electrical resistivity showed a large hysteresis between 120 K and 160 K. The effect is not sensitive to magnetic fields up to 9 T. Curie-Weiss fitting revealed that the amount of itinerant charge carriers in ZnVSb drops with decreasing temperature below 160 K, which is accompanied by a concurrent rise in the localized magnetic moment. This observation together with the overall shape of the hysteresis in the resistivity allows for suggesting a plausible origin of the effect as a charge-transfer metal-insulator transition. Ab initio phonon calculations show the formation of a collective phonon mode at 2.8 THz (134 K). The experimental heat capacity reflected this feature by a boson peak with Einstein temperature of 116 K. Analysis of the heat capacity with both an ab initio perspective and Debye-Einstein model revealed a sizable anharmonic contribution to heat capacity, in line with disordered nature of the material. Further investigation of the electron and phonon properties for ZnVSb is likely to provide valuable insight into the relation between structural disorder and the physical properties of transition-metal-bearing compounds. |
| publishDate |
2021 |
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2021-06-25T10:51:07Z 2021-06-25T10:51:07Z 2021-01-01 |
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info:eu-repo/semantics/publishedVersion |
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info:eu-repo/semantics/article |
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article |
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publishedVersion |
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http://dx.doi.org/10.1103/PhysRevMaterials.5.015002 Physical Review Materials, v. 5, n. 1, 2021. 2475-9953 http://hdl.handle.net/11449/207230 10.1103/PhysRevMaterials.5.015002 2-s2.0-85100383565 |
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http://dx.doi.org/10.1103/PhysRevMaterials.5.015002 http://hdl.handle.net/11449/207230 |
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Physical Review Materials, v. 5, n. 1, 2021. 2475-9953 10.1103/PhysRevMaterials.5.015002 2-s2.0-85100383565 |
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eng |
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Physical Review Materials |
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Repositório Institucional da UNESP - Universidade Estadual Paulista (UNESP) |
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