Andrew C. Strzelecki, Stella Chariton, Cody B. Cockreham, Michael T. Pettes, Vitali Prakapenka, Bethany A. Chidester, Di Wu, Chris R. Bradley, Garrett G. Euler, Xiaofeng Guo, Hakim Boukhalfa, Hongwu Xu
{"title":"用高压粉末同步x射线衍射测定天然斜发沸石的P-V状态方程","authors":"Andrew C. Strzelecki, Stella Chariton, Cody B. Cockreham, Michael T. Pettes, Vitali Prakapenka, Bethany A. Chidester, Di Wu, Chris R. Bradley, Garrett G. Euler, Xiaofeng Guo, Hakim Boukhalfa, Hongwu Xu","doi":"10.1007/s00269-022-01224-3","DOIUrl":null,"url":null,"abstract":"<div><p>Characterization of the behavior of zeolites at high pressures is of interest both in fundamental science and for practical applications. For example, zeolites occur as a major mineral group in tuffaceous rocks (such as those at the Nevada Nuclear Security Site), and they play a key role in defining the high-pressure behavior of tuff in a nuclear explosion event. The crystal structure, Si/Al ratio, and type of pressure-transmitting media (PTM) used in high-pressure experiments influence the compressional behavior of a given zeolitic phase. The heulandite-type (HEU) zeolites, including heulandite and clinoptilolite, are isostructural but differ in their Si/Al ratios. Thus, HEU-type zeolites comprise an ideal system in unraveling the effects of Si/Al ratio and type of PTM on their pressure-induced structural behavior. In this study, we performed in situ high-pressure angle-dispersive powder synchrotron X-ray diffraction (XRD) experiments on a natural HEU zeolite, clinoptilolite, with a Si/Al ratio of 4.4, by compressing it in a diamond anvil cell (DAC) up to 14.65 GPa using a non-penetrating pressure-transmitting medium (KCl). Unit cell parameters as a function of pressure up to 9.04 GPa were obtained by Rietveld analysis. Unit cell volumes were fit to both a second and a third-order Birch–Murnaghan equation of state. The mean bulk modulus (<i>K</i><sub>0</sub>) determined from all the fittings is 32.7 ± 0.9 GPa. The zero-pressure compressibility of the <i>a-</i>, <i>b-</i>, and <i>c</i>-axes for clinoptilolite are 10.6 (± 0.8) × 10<sup>–3</sup> GPa<sup>–1</sup>, 5.3 (± 0.7) × 10<sup>–3</sup> GPa<sup>–1</sup>, and 17.1 (± 1.8) × 10<sup>–3</sup> GPa<sup>–1</sup>, respectively. The pressure–volume equations of states of this type of zeolite are important for characterizing high-pressure behavior of the broader family of microporous materials and for developing reliable geophysical signatures for underground nuclear monitoring.</p></div>","PeriodicalId":20132,"journal":{"name":"Physics and Chemistry of Minerals","volume":"49 12","pages":""},"PeriodicalIF":1.2000,"publicationDate":"2022-11-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"Determination of P–V equation of state of a natural clinoptilolite using high-pressure powder synchrotron X-ray diffraction\",\"authors\":\"Andrew C. Strzelecki, Stella Chariton, Cody B. Cockreham, Michael T. Pettes, Vitali Prakapenka, Bethany A. Chidester, Di Wu, Chris R. Bradley, Garrett G. Euler, Xiaofeng Guo, Hakim Boukhalfa, Hongwu Xu\",\"doi\":\"10.1007/s00269-022-01224-3\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>Characterization of the behavior of zeolites at high pressures is of interest both in fundamental science and for practical applications. For example, zeolites occur as a major mineral group in tuffaceous rocks (such as those at the Nevada Nuclear Security Site), and they play a key role in defining the high-pressure behavior of tuff in a nuclear explosion event. The crystal structure, Si/Al ratio, and type of pressure-transmitting media (PTM) used in high-pressure experiments influence the compressional behavior of a given zeolitic phase. The heulandite-type (HEU) zeolites, including heulandite and clinoptilolite, are isostructural but differ in their Si/Al ratios. Thus, HEU-type zeolites comprise an ideal system in unraveling the effects of Si/Al ratio and type of PTM on their pressure-induced structural behavior. In this study, we performed in situ high-pressure angle-dispersive powder synchrotron X-ray diffraction (XRD) experiments on a natural HEU zeolite, clinoptilolite, with a Si/Al ratio of 4.4, by compressing it in a diamond anvil cell (DAC) up to 14.65 GPa using a non-penetrating pressure-transmitting medium (KCl). Unit cell parameters as a function of pressure up to 9.04 GPa were obtained by Rietveld analysis. Unit cell volumes were fit to both a second and a third-order Birch–Murnaghan equation of state. The mean bulk modulus (<i>K</i><sub>0</sub>) determined from all the fittings is 32.7 ± 0.9 GPa. The zero-pressure compressibility of the <i>a-</i>, <i>b-</i>, and <i>c</i>-axes for clinoptilolite are 10.6 (± 0.8) × 10<sup>–3</sup> GPa<sup>–1</sup>, 5.3 (± 0.7) × 10<sup>–3</sup> GPa<sup>–1</sup>, and 17.1 (± 1.8) × 10<sup>–3</sup> GPa<sup>–1</sup>, respectively. 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Determination of P–V equation of state of a natural clinoptilolite using high-pressure powder synchrotron X-ray diffraction
Characterization of the behavior of zeolites at high pressures is of interest both in fundamental science and for practical applications. For example, zeolites occur as a major mineral group in tuffaceous rocks (such as those at the Nevada Nuclear Security Site), and they play a key role in defining the high-pressure behavior of tuff in a nuclear explosion event. The crystal structure, Si/Al ratio, and type of pressure-transmitting media (PTM) used in high-pressure experiments influence the compressional behavior of a given zeolitic phase. The heulandite-type (HEU) zeolites, including heulandite and clinoptilolite, are isostructural but differ in their Si/Al ratios. Thus, HEU-type zeolites comprise an ideal system in unraveling the effects of Si/Al ratio and type of PTM on their pressure-induced structural behavior. In this study, we performed in situ high-pressure angle-dispersive powder synchrotron X-ray diffraction (XRD) experiments on a natural HEU zeolite, clinoptilolite, with a Si/Al ratio of 4.4, by compressing it in a diamond anvil cell (DAC) up to 14.65 GPa using a non-penetrating pressure-transmitting medium (KCl). Unit cell parameters as a function of pressure up to 9.04 GPa were obtained by Rietveld analysis. Unit cell volumes were fit to both a second and a third-order Birch–Murnaghan equation of state. The mean bulk modulus (K0) determined from all the fittings is 32.7 ± 0.9 GPa. The zero-pressure compressibility of the a-, b-, and c-axes for clinoptilolite are 10.6 (± 0.8) × 10–3 GPa–1, 5.3 (± 0.7) × 10–3 GPa–1, and 17.1 (± 1.8) × 10–3 GPa–1, respectively. The pressure–volume equations of states of this type of zeolite are important for characterizing high-pressure behavior of the broader family of microporous materials and for developing reliable geophysical signatures for underground nuclear monitoring.
期刊介绍:
Physics and Chemistry of Minerals is an international journal devoted to publishing articles and short communications of physical or chemical studies on minerals or solids related to minerals. The aim of the journal is to support competent interdisciplinary work in mineralogy and physics or chemistry. Particular emphasis is placed on applications of modern techniques or new theories and models to interpret atomic structures and physical or chemical properties of minerals. Some subjects of interest are:
-Relationships between atomic structure and crystalline state (structures of various states, crystal energies, crystal growth, thermodynamic studies, phase transformations, solid solution, exsolution phenomena, etc.)
-General solid state spectroscopy (ultraviolet, visible, infrared, Raman, ESCA, luminescence, X-ray, electron paramagnetic resonance, nuclear magnetic resonance, gamma ray resonance, etc.)
-Experimental and theoretical analysis of chemical bonding in minerals (application of crystal field, molecular orbital, band theories, etc.)
-Physical properties (magnetic, mechanical, electric, optical, thermodynamic, etc.)
-Relations between thermal expansion, compressibility, elastic constants, and fundamental properties of atomic structure, particularly as applied to geophysical problems
-Electron microscopy in support of physical and chemical studies
-Computational methods in the study of the structure and properties of minerals
-Mineral surfaces (experimental methods, structure and properties)