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Thermal expansion of anhydrous copper sulfate minerals determined by single crystal X‑ray diffraction: chalcocyanite CuSO4, dolerophanite Cu2OSO4 and kamchatkite KCu3O(SO4)2Cl. / Назарчук, Евгений Васильевич; Сийдра, Олег Иоханнесович; Филатов, Станислав Константинович; Чаркин, Дмитрий; Жданова, Лада Руслановна.

в: Physics and Chemistry of Minerals, Том 50, № 2, 11, 01.06.2023.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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@article{0a344db9a6084653a2d3b347e760a28c,
title = "Thermal expansion of anhydrous copper sulfate minerals determined by single crystal X‑ray diffraction: chalcocyanite CuSO4, dolerophanite Cu2OSO4 and kamchatkite KCu3O(SO4)2Cl",
abstract = "Polythermic single-crystal X-ray studies of chalcocyanite CuSO4, dolerophanite Cu2OSO4, and kamchatkite KCu3O(SO4)2Cl have established their melting points as well as peculiarities of their thermal expansion. Association of oxocentered and sulfate tetrahedra in dolerophanite and kamchatkite leads to the formation of rigid tetrahedral “backbones” only slightly sensitive to thermal variations. Rigid complexes can also be distinguished in the structure of chalcocyanite, if we consider only the system of the shortest and strongest Cu–O and S–O bonds. The anisotropy of the thermal expansion can be explained by either rigid complexes drifting parallel to each other (as in dolerophanite and chalcocyanite), or radial and angular distortions in the polyhedra of alkali cations. The presence of a tetrahedrally coordinated additional oxygen atom in the structure of dolerophanite and kamchatkite leads to an increase in the principal eigenvalues. The demonstrated rigidity of the sulfate tetrahedra in studied anhydrous copper sulfate minerals explains the absence of phase transitions up to the melting temperatures. The variation of chemical composition leads to changes in their thermal decomposition points. Chlorine-containing kamchatkite decomposes at the lowest temperature of 590(5) K, next are chalcocyanite 675(10) K, and dolerophanite 925(10) K.",
keywords = "Anhydrous copper sulfate minerals, Chalcocyanite, Dolerophanite, High-temperature X-ray diffraction, Kamchatkite, Single-crystal X-ray analysis, Thermal expansion",
author = "Назарчук, {Евгений Васильевич} and Сийдра, {Олег Иоханнесович} and Филатов, {Станислав Константинович} and Дмитрий Чаркин and Жданова, {Лада Руслановна}",
year = "2023",
month = jun,
day = "1",
doi = "10.1007/s00269-023-01236-7",
language = "English",
volume = "50",
journal = "Physics and Chemistry of Minerals",
issn = "0342-1791",
publisher = "Springer Nature",
number = "2",

}

RIS

TY - JOUR

T1 - Thermal expansion of anhydrous copper sulfate minerals determined by single crystal X‑ray diffraction: chalcocyanite CuSO4, dolerophanite Cu2OSO4 and kamchatkite KCu3O(SO4)2Cl

AU - Назарчук, Евгений Васильевич

AU - Сийдра, Олег Иоханнесович

AU - Филатов, Станислав Константинович

AU - Чаркин, Дмитрий

AU - Жданова, Лада Руслановна

PY - 2023/6/1

Y1 - 2023/6/1

N2 - Polythermic single-crystal X-ray studies of chalcocyanite CuSO4, dolerophanite Cu2OSO4, and kamchatkite KCu3O(SO4)2Cl have established their melting points as well as peculiarities of their thermal expansion. Association of oxocentered and sulfate tetrahedra in dolerophanite and kamchatkite leads to the formation of rigid tetrahedral “backbones” only slightly sensitive to thermal variations. Rigid complexes can also be distinguished in the structure of chalcocyanite, if we consider only the system of the shortest and strongest Cu–O and S–O bonds. The anisotropy of the thermal expansion can be explained by either rigid complexes drifting parallel to each other (as in dolerophanite and chalcocyanite), or radial and angular distortions in the polyhedra of alkali cations. The presence of a tetrahedrally coordinated additional oxygen atom in the structure of dolerophanite and kamchatkite leads to an increase in the principal eigenvalues. The demonstrated rigidity of the sulfate tetrahedra in studied anhydrous copper sulfate minerals explains the absence of phase transitions up to the melting temperatures. The variation of chemical composition leads to changes in their thermal decomposition points. Chlorine-containing kamchatkite decomposes at the lowest temperature of 590(5) K, next are chalcocyanite 675(10) K, and dolerophanite 925(10) K.

AB - Polythermic single-crystal X-ray studies of chalcocyanite CuSO4, dolerophanite Cu2OSO4, and kamchatkite KCu3O(SO4)2Cl have established their melting points as well as peculiarities of their thermal expansion. Association of oxocentered and sulfate tetrahedra in dolerophanite and kamchatkite leads to the formation of rigid tetrahedral “backbones” only slightly sensitive to thermal variations. Rigid complexes can also be distinguished in the structure of chalcocyanite, if we consider only the system of the shortest and strongest Cu–O and S–O bonds. The anisotropy of the thermal expansion can be explained by either rigid complexes drifting parallel to each other (as in dolerophanite and chalcocyanite), or radial and angular distortions in the polyhedra of alkali cations. The presence of a tetrahedrally coordinated additional oxygen atom in the structure of dolerophanite and kamchatkite leads to an increase in the principal eigenvalues. The demonstrated rigidity of the sulfate tetrahedra in studied anhydrous copper sulfate minerals explains the absence of phase transitions up to the melting temperatures. The variation of chemical composition leads to changes in their thermal decomposition points. Chlorine-containing kamchatkite decomposes at the lowest temperature of 590(5) K, next are chalcocyanite 675(10) K, and dolerophanite 925(10) K.

KW - Anhydrous copper sulfate minerals

KW - Chalcocyanite

KW - Dolerophanite

KW - High-temperature X-ray diffraction

KW - Kamchatkite

KW - Single-crystal X-ray analysis

KW - Thermal expansion

UR - https://www.mendeley.com/catalogue/6900e96c-5a15-3c4a-9825-5924544d2a9a/

U2 - 10.1007/s00269-023-01236-7

DO - 10.1007/s00269-023-01236-7

M3 - Article

VL - 50

JO - Physics and Chemistry of Minerals

JF - Physics and Chemistry of Minerals

SN - 0342-1791

IS - 2

M1 - 11

ER -

ID: 104088144