Crystal and Electronic Structures of a Chain Vanadium Selenoiodide [V3Se12I2]I3·1/4I2

IF 1.4 4区化学 Q4 CHEMISTRY, INORGANIC & NUCLEAR

Journal of Structural Chemistry Pub Date : 2025-07-01 DOI:10.1134/S0022476625060010

R. R. Galiev, V. Y. Komarov, S. G. Kozlova, S. B. Artemkina, V. E. Fedorov

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Abstract

A crystal of the [V₃Se₁₂I₂]I₃·1/4I₂ vanadium selenoiodide is prepared by a reaction of vanadium, selenium, and iodine at 240 °C. According to the single-crystal XRD data (P2₁/c space group, a = 19.1162(7) Å, b = 13.6844(5) Å, c = 18.1423(6) Å, β = 90.663(2)°, V = 4745.6(3) Å³, T = 150 K, Z = 8), the [V₃Se₁₂I₂]I₃·1/4I₂ structure contains positively charged \([{{\text{V}}_{3}}\text{S}{{\text{e}}_{12}}{{\text{I}}_{2}}]_{\infty }^{+}\) chains composed of {V₃I(Se₂)₃(Se₂I)} linear groups with V⋯V distances of 2.98 Å. The groups are interconnected by μ-(Se₂) and μ-(Se₂I) bridging ligands (one at a time) with a larger V⋯V distance of 3.74 Å. The [V₃Se₁₂I₂]I₃·1/4I₂ structure is characterized by the presence of a Se–Se–I ligand connecting vanadium atoms by the μ-Se₂-κ²,κ¹ type. The calculated bandgap of 0.78 eV indicates that the vanadium selenoiodide possesses semiconducting properties. The crystal structure of [V₃Se₁₂I₂]I₃·1/4I₂ is discussed; the electronic structure and stability of this compound are calculated.

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链型硒化钒[V3Se12I2]I3·1/4I2的晶体和电子结构

通过钒、硒和碘在240℃下的反应，制备了[V3Se12I2]I3·1/4I2硒化钒晶体。根据单晶XRD数据(P21/c空间群，a = 19.1162(7) Å， b = 13.6844(5) Å， c = 18.1423(6) Å， β = 90.663(2)°，V = 4745.6(3) Å3, T = 150 K, Z = 8)， [V3Se12I2]I3·1/4I2结构包含由线性基团组成的带正电的\([{{\text{V}}_{3}}\text{S}{{\text{e}}_{12}}{{\text{I}}_{2}}]_{\infty }^{+}\)链，其V⋯V距离为2.98 Å。基团由μ-(Se2)和μ-(Se2I)桥接配体连接（一次一个），其V⋯V距离较大，为3.74 Å。[V3Se12I2]I3·1/4I2结构的特点是存在Se-Se-I配体，以μ-Se2-κ2，κ1型连接钒原子。计算得到的带隙为0.78 eV，表明硒化钒具有半导体性质。讨论了[V3Se12I2]I3·1/4I2的晶体结构；计算了该化合物的电子结构和稳定性。{}

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来源期刊

Journal of Structural Chemistry 化学-无机化学与核化学

CiteScore

1.60

自引率

12.50%

发文量

142

审稿时长

8.3 months

期刊介绍： Journal is an interdisciplinary publication covering all aspects of structural chemistry, including the theory of molecular structure and chemical bond; the use of physical methods to study the electronic and spatial structure of chemical species; structural features of liquids, solutions, surfaces, supramolecular systems, nano- and solid materials; and the crystal structure of solids.