Si5-pentagonal rings and Y-shaped Si4 building blocks in Li32Si18 system: similarities with the crystalline Zintl phase Li12Si7

Osvaldo Yañez; Diego Inostroza; Luis Leyva-Parra; José Solar-Encinas; J. César Cruz; Jorge Garza; Alejandro Vásquez-Espinal; Ricardo Pino-Rios; Walter Orellana; William Tiznado

doi:10.1039/d2me00152g

Si₅-pentagonal rings and Y-shaped Si₄ building blocks in Li₃₂Si₁₈ system: similarities with the crystalline Zintl phase Li₁₂Si₇

Osvaldo Yañez, Diego Inostroza, Luis Leyva-Parra, José Solar-Encinas, J. César Cruz, Jorge Garza, Alejandro Vásquez-Espinal, Ricardo Pino-Rios, Walter Orellana, William Tiznado

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Resumen

Potential energy surface screening combined with density functional computations reveal that the Li₃₂Si₁₈ lowest energy structure consists of Si₄ Y-shaped and Si₅-pentagonal moieties, as observed in the crystalline Zintl-phase Li₁₂Si₇. The Li₃₂Si₁₈ system can be interpreted as an assembly of Li₁₀Si₄ (Si₄-Y) and Li₆Si₅ (Si₅-pentagonal) clusters, showing a clear growth pattern towards a material assembled from clusters. Chemical bonding analysis shows that the silicon atoms are strongly connected by covalent bonds, with a significant electron transfer from the lithium resulting in primarily electrostatic Li-Si interactions. This study establishes a structural relationship between Li-Si compounds at sub-nano, nano, and macro scales, which, together with the abundant literature on Zintl-phases of lithium silicides, may open new routes for materials design.

Idioma original	Inglés
Páginas (desde-hasta)	207-216
Número de páginas	10
Publicación	Molecular Systems Design and Engineering
Volumen	8
N.º	2
DOI	https://doi.org/10.1039/d2me00152g
Estado	Publicada - 7 oct. 2022

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10.1039/d2me00152g

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Yañez, O., Inostroza, D., Leyva-Parra, L., Solar-Encinas, J., Cruz, J. C., Garza, J., Vásquez-Espinal, A., Pino-Rios, R., Orellana, W., & Tiznado, W. (2022). Si₅-pentagonal rings and Y-shaped Si₄ building blocks in Li₃₂Si₁₈ system: similarities with the crystalline Zintl phase Li₁₂Si₇. Molecular Systems Design and Engineering, 8(2), 207-216. https://doi.org/10.1039/d2me00152g

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title = "Si5-pentagonal rings and Y-shaped Si4 building blocks in Li32Si18 system: similarities with the crystalline Zintl phase Li12Si7",

abstract = "Potential energy surface screening combined with density functional computations reveal that the Li32Si18 lowest energy structure consists of Si4 Y-shaped and Si5-pentagonal moieties, as observed in the crystalline Zintl-phase Li12Si7. The Li32Si18 system can be interpreted as an assembly of Li10Si4 (Si4-Y) and Li6Si5 (Si5-pentagonal) clusters, showing a clear growth pattern towards a material assembled from clusters. Chemical bonding analysis shows that the silicon atoms are strongly connected by covalent bonds, with a significant electron transfer from the lithium resulting in primarily electrostatic Li-Si interactions. This study establishes a structural relationship between Li-Si compounds at sub-nano, nano, and macro scales, which, together with the abundant literature on Zintl-phases of lithium silicides, may open new routes for materials design.",

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Yañez, O , Inostroza, D, Leyva-Parra, L, Solar-Encinas, J, Cruz, JC, Garza, J, Vásquez-Espinal, A, Pino-Rios, R, Orellana, W & Tiznado, W 2022, 'Si₅-pentagonal rings and Y-shaped Si₄ building blocks in Li₃₂Si₁₈ system: similarities with the crystalline Zintl phase Li₁₂Si₇', Molecular Systems Design and Engineering, vol. 8, n.º 2, pp. 207-216. https://doi.org/10.1039/d2me00152g

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T1 - Si5-pentagonal rings and Y-shaped Si4 building blocks in Li32Si18 system

T2 - similarities with the crystalline Zintl phase Li12Si7

AU - Yañez, Osvaldo

AU - Inostroza, Diego

AU - Leyva-Parra, Luis

AU - Solar-Encinas, José

AU - Cruz, J. César

AU - Garza, Jorge

AU - Vásquez-Espinal, Alejandro

AU - Pino-Rios, Ricardo

AU - Orellana, Walter

AU - Tiznado, William

PY - 2022/10/7

Y1 - 2022/10/7

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AB - Potential energy surface screening combined with density functional computations reveal that the Li32Si18 lowest energy structure consists of Si4 Y-shaped and Si5-pentagonal moieties, as observed in the crystalline Zintl-phase Li12Si7. The Li32Si18 system can be interpreted as an assembly of Li10Si4 (Si4-Y) and Li6Si5 (Si5-pentagonal) clusters, showing a clear growth pattern towards a material assembled from clusters. Chemical bonding analysis shows that the silicon atoms are strongly connected by covalent bonds, with a significant electron transfer from the lithium resulting in primarily electrostatic Li-Si interactions. This study establishes a structural relationship between Li-Si compounds at sub-nano, nano, and macro scales, which, together with the abundant literature on Zintl-phases of lithium silicides, may open new routes for materials design.

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