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Main Authors: Errandonea, Daniel, Turnbull, Robin, Osman, Hussien H. H., Hebboul, Zoulikha, Botella, Pablo, Bura, Neha, Zhang, Peijie, Ramon, Jose Luis Rodrigo, Sanchez-Martin, Josu, Popescu, Catalin, Manjon, Francisco J.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.09140
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author Errandonea, Daniel
Turnbull, Robin
Osman, Hussien H. H.
Hebboul, Zoulikha
Botella, Pablo
Bura, Neha
Zhang, Peijie
Ramon, Jose Luis Rodrigo
Sanchez-Martin, Josu
Popescu, Catalin
Manjon, Francisco J.
author_facet Errandonea, Daniel
Turnbull, Robin
Osman, Hussien H. H.
Hebboul, Zoulikha
Botella, Pablo
Bura, Neha
Zhang, Peijie
Ramon, Jose Luis Rodrigo
Sanchez-Martin, Josu
Popescu, Catalin
Manjon, Francisco J.
contents Combining X-ray diffraction with density-functional theory and electron topology calculations we found that pressure substantially modifies the bonding in K2Zn(IO3)4.2H2O. We discovered that under compression there is a progressive change from primary covalent I-O bonds and secondary halogen I-O interactions towards O-I-O electron-deficient multicenter bonds. Because of this, iodine hypercoordination converts IO3 trigonal pyramids towards IO6 units. The formation of these IO6 units breaks the typical isolation of iodate molecules forming an infinite two-dimensional iodate network. Hypercoordination influences the hydrogen atoms too, such that multicenter O-H-O bonds are also promoted with increasing pressure. We have determined that K2Zn(IO3)4.2H2O is one of the most compressible iodates studied to date, with a bulk modulus of 22(3) GPa. The pressure-induced structural changes strongly modify the electronic structure as shown by optical-absorption measurements and band-structure calculations. The band-gap energy closes from 4.2(1) eV at ambient pressure to 3.4(1) eV at 20 GPa.
format Preprint
id arxiv_https___arxiv_org_abs_2604_09140
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Effects of Compression on the Local Iodine Environment in Dipotassium Zinc Tetraiodate(V) Dihydrate K2Zn(IO3)4.2H2O
Errandonea, Daniel
Turnbull, Robin
Osman, Hussien H. H.
Hebboul, Zoulikha
Botella, Pablo
Bura, Neha
Zhang, Peijie
Ramon, Jose Luis Rodrigo
Sanchez-Martin, Josu
Popescu, Catalin
Manjon, Francisco J.
Materials Science
Combining X-ray diffraction with density-functional theory and electron topology calculations we found that pressure substantially modifies the bonding in K2Zn(IO3)4.2H2O. We discovered that under compression there is a progressive change from primary covalent I-O bonds and secondary halogen I-O interactions towards O-I-O electron-deficient multicenter bonds. Because of this, iodine hypercoordination converts IO3 trigonal pyramids towards IO6 units. The formation of these IO6 units breaks the typical isolation of iodate molecules forming an infinite two-dimensional iodate network. Hypercoordination influences the hydrogen atoms too, such that multicenter O-H-O bonds are also promoted with increasing pressure. We have determined that K2Zn(IO3)4.2H2O is one of the most compressible iodates studied to date, with a bulk modulus of 22(3) GPa. The pressure-induced structural changes strongly modify the electronic structure as shown by optical-absorption measurements and band-structure calculations. The band-gap energy closes from 4.2(1) eV at ambient pressure to 3.4(1) eV at 20 GPa.
title Effects of Compression on the Local Iodine Environment in Dipotassium Zinc Tetraiodate(V) Dihydrate K2Zn(IO3)4.2H2O
topic Materials Science
url https://arxiv.org/abs/2604.09140