Research output: Contribution to journal › Article › peer-review
Anhydrous alkali copper sulfates – A promising playground for new Cu2+ oxide complexes: New Rb-analogues of fumarolic minerals. / Siidra, Oleg I.; Nekrasova, Diana O.; Charkin, Dmitry O.; Zaitsev, Anatoly N.; Borisov, Artem S.; Colmont, Marie; Mentré, Olivier; Spiridonova, Darya V.
In: Mineralogical Magazine, Vol. 85, No. 6, 12.2021, p. 831-845.Research output: Contribution to journal › Article › peer-review
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TY - JOUR
T1 - Anhydrous alkali copper sulfates – A promising playground for new Cu2+ oxide complexes: New Rb-analogues of fumarolic minerals
AU - Siidra, Oleg I.
AU - Nekrasova, Diana O.
AU - Charkin, Dmitry O.
AU - Zaitsev, Anatoly N.
AU - Borisov, Artem S.
AU - Colmont, Marie
AU - Mentré, Olivier
AU - Spiridonova, Darya V.
N1 - Publisher Copyright: © 2021 Cambridge University Press. All rights reserved.
PY - 2021/12
Y1 - 2021/12
N2 - We report the crystal structures of eight new synthetic multinary Rb-Cu sulfates representing four new structure types: δ-Rb2Cu(SO4)2, γ-RbNaCu(SO4)2, γ-RbKCu(SO4)2, Rb2Cu2(SO4)3, Rb2Cu2(SO4)3(H2O), β-Rb2Cu(SO4)Cl2, β-Rb4Cu4O2(SO4)4∙(Cu0.83Rb0.17Cl) and Rb2Cu5O(SO4)5. The determination of their crystal structures significantly expands the family of anhydrous copper sulfates. Some of the obtained anhydrous rubidium copper sulfates turned out to be isostructural to known compounds and minerals. Rb2Cu5O(SO4)5 is isostructural to cesiodymite, CsKCu5O(SO4)5, and cryptochalcite, K2Cu5O(SO4)5. Rb2Cu2(SO4)3 also shows an example of crystallization in the already known structure type first observed for synthetic K2Cu2(SO4)3. “Hydrolangbeinite”, Rb2Cu2(SO4)3(H2O), was formed as a result of a minor hydration of the initial mixture of reagents. The minerals and synthetic framework compounds of the A2Cu(SO4)2 series demonstrate a vivid example of morphotropism with the formation of structural types depending on the size of the cations residing in the cavities of the [Cu(SO4)2]2- open framework. To date, five types (α, β, γ, δ and ε) can be distinguished. We propose to call this series of compounds “saranchinaite-type”, since the stoichiometry A2Cu(SO4)2 was first encountered during the discovery and description of saranchinaite, Na2Cu(SO4)2. The discovery of β-Rb2Cu(SO4)Cl2, a new monoclinic polymorph of chlorothionite, seems to be of particular interest considering the recently discovered interesting magnetic properties of synthetic K2Cu(SO4)X2 (X = Cl, Br) and Na2Cu(SO4)Cl2. In the determined new structural architectures, a number of features were revealed which were seldom observed before. The first is the bidentate coordination of the sulfate tetrahedron via edge-sharing with the Cu2+-centered coordination polyhedron. Until recently, such coordination was known only for the chlorothionite structure. The second is formation of “high-coordinated” CuO7 polyhedra. The structures of the new compounds suggest that such coordination is not in fact so uncommon, at least among anhydrous alkali copper sulfates. All of the described features clearly indicate the importance of further systematic studies of anhydrous copper-sulfate systems. Their exploration, particularly of the new copper-oxide substructures with new coordination environments, is highly likely to lead to new potentially interesting magnetic properties due to unusual arrangements of magnetically active Cu2+ cations. In addition to experimental details on the synthesis of rubidium analogs of anhydrous potassium and sodium sulfates, this work also provides an analysis and a brief review of the geochemistry of rubidium in volcanic environments.
AB - We report the crystal structures of eight new synthetic multinary Rb-Cu sulfates representing four new structure types: δ-Rb2Cu(SO4)2, γ-RbNaCu(SO4)2, γ-RbKCu(SO4)2, Rb2Cu2(SO4)3, Rb2Cu2(SO4)3(H2O), β-Rb2Cu(SO4)Cl2, β-Rb4Cu4O2(SO4)4∙(Cu0.83Rb0.17Cl) and Rb2Cu5O(SO4)5. The determination of their crystal structures significantly expands the family of anhydrous copper sulfates. Some of the obtained anhydrous rubidium copper sulfates turned out to be isostructural to known compounds and minerals. Rb2Cu5O(SO4)5 is isostructural to cesiodymite, CsKCu5O(SO4)5, and cryptochalcite, K2Cu5O(SO4)5. Rb2Cu2(SO4)3 also shows an example of crystallization in the already known structure type first observed for synthetic K2Cu2(SO4)3. “Hydrolangbeinite”, Rb2Cu2(SO4)3(H2O), was formed as a result of a minor hydration of the initial mixture of reagents. The minerals and synthetic framework compounds of the A2Cu(SO4)2 series demonstrate a vivid example of morphotropism with the formation of structural types depending on the size of the cations residing in the cavities of the [Cu(SO4)2]2- open framework. To date, five types (α, β, γ, δ and ε) can be distinguished. We propose to call this series of compounds “saranchinaite-type”, since the stoichiometry A2Cu(SO4)2 was first encountered during the discovery and description of saranchinaite, Na2Cu(SO4)2. The discovery of β-Rb2Cu(SO4)Cl2, a new monoclinic polymorph of chlorothionite, seems to be of particular interest considering the recently discovered interesting magnetic properties of synthetic K2Cu(SO4)X2 (X = Cl, Br) and Na2Cu(SO4)Cl2. In the determined new structural architectures, a number of features were revealed which were seldom observed before. The first is the bidentate coordination of the sulfate tetrahedron via edge-sharing with the Cu2+-centered coordination polyhedron. Until recently, such coordination was known only for the chlorothionite structure. The second is formation of “high-coordinated” CuO7 polyhedra. The structures of the new compounds suggest that such coordination is not in fact so uncommon, at least among anhydrous alkali copper sulfates. All of the described features clearly indicate the importance of further systematic studies of anhydrous copper-sulfate systems. Their exploration, particularly of the new copper-oxide substructures with new coordination environments, is highly likely to lead to new potentially interesting magnetic properties due to unusual arrangements of magnetically active Cu2+ cations. In addition to experimental details on the synthesis of rubidium analogs of anhydrous potassium and sodium sulfates, this work also provides an analysis and a brief review of the geochemistry of rubidium in volcanic environments.
KW - Copper
KW - Crystal structures
KW - Fumarolic minerals
KW - Gas transport reactions
KW - Rubidium
KW - Solid state reactions
KW - Sulfates
UR - http://www.scopus.com/inward/record.url?scp=85117279339&partnerID=8YFLogxK
U2 - 10.1180/mgm.2021.73
DO - 10.1180/mgm.2021.73
M3 - Article
AN - SCOPUS:85117279339
VL - 85
SP - 831
EP - 845
JO - Mineralogical Magazine
JF - Mineralogical Magazine
SN - 0026-461X
IS - 6
ER -
ID: 87839946