Potassium Tetraiodatoiodate(III) Iodate(V): A Nonlinear Optical Crystal with Exceptional Second‐Harmonic Generation and Full‐Wavelength Phase Matching

The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full‐wavelength phase matching capabilities remains a significant challenge. In this study, we synthesized a novel potassium tetraiodatoiodate(III) iodate(V) via...

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Published inAngewandte Chemie International Edition Vol. 64; no. 23; pp. e202504673 - n/a
Main Authors Lin, Min‐Quan, Hu, Chun‐Li, Duan, Meng‐Fan, Li, Bing‐Xuan, Mao, Jiang‐Gao, Yang, Bing‐Ping
Format Journal Article
LanguageEnglish
Published Germany Wiley Subscription Services, Inc 02.06.2025
EditionInternational ed. in English
Subjects
Anisotropy
Birefringence
Coordination compound
Full‐wavelength phase matching
Functional materials
Harmonic generations
Hypervalent iodine
Iodine
NLO materials
Nonlinear optics
Optical materials
Optical properties
Partial reduction reaction
Phase matching
Polarizability
Potassium
Wavelength
Wavelengths
Coordination compound
Full‐wavelength phase matching
Hypervalent iodine
NLO materials
Partial reduction reaction
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Abstract The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full‐wavelength phase matching capabilities remains a significant challenge. In this study, we synthesized a novel potassium tetraiodatoiodate(III) iodate(V) via an in‐situ reduction and complexation reaction. The resulting compound, K2[IIII(IVO3)4]IVO3, exhibits exceptional second‐harmonic generation responses (21.6KH2PO4 at 1064 nm, 1.0KTiOPO4 at 2050 nm), a wide transparency range from the visible to the mid‐infrared wavelengths (0.37–6.05 and 7.03–13.40 µm), and a high birefringence (0.358 at 543 nm) to achieve full‐wavelength phase matching. These properties are primarily ascribed to the synergistic substantial hyperpolarizability and polarizability anisotropy exhibited by the [IIII(IVO3)4]− complex ions, which comprise square‐planar coordinated trivalent iodine and optimally arranged iodate ligands. This study demonstrates the pivotal role of nonmetallic cation centered coordination entities in influencing linear and nonlinear optical properties, a discovery that has significant implications for the development of innovative inorganic functional materials. A novel potassium tetraiodatoiodate(III) iodate(V), K2[IIII(IVO3)4]IVO3, has been successfully synthesized via an innovative in‐situ reduction and complexation reaction. This atypical inorganic nonmetallic coordination compound, featuring trivalent iodine as the central coordination atom, exhibits exceptional potential as a second‐order nonlinear optical material. It demonstrates remarkable second‐harmonic generation responses (21.6KH2PO4 at 1064 nm, 1.0KTiOPO4 at 2050 nm), a broad transparency range from the visible to the mid‐infrared wavelengths (0.37–6.05 and 7.03–13.40 µm), and a high birefringence (0.358 at 543 nm) enabling rare full‐wavelength phase matching.
AbstractList The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full-wavelength phase matching capabilities remains a significant challenge. In this study, we synthesized a novel potassium tetraiodatoiodate(III) iodate(V) via an in-situ reduction and complexation reaction. The resulting compound, K [I (I O ) ]I O , exhibits exceptional second-harmonic generation responses (21.6KH PO at 1064 nm, 1.0KTiOPO at 2050 nm), a wide transparency range from the visible to the mid-infrared wavelengths (0.37-6.05 and 7.03-13.40 µm), and a high birefringence (0.358 at 543 nm) to achieve full-wavelength phase matching. These properties are primarily ascribed to the synergistic substantial hyperpolarizability and polarizability anisotropy exhibited by the [I (I O ) ] complex ions, which comprise square-planar coordinated trivalent iodine and optimally arranged iodate ligands. This study demonstrates the pivotal role of nonmetallic cation centered coordination entities in influencing linear and nonlinear optical properties, a discovery that has significant implications for the development of innovative inorganic functional materials.
The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full-wavelength phase matching capabilities remains a significant challenge. In this study, we synthesized a novel potassium tetraiodatoiodate(III) iodate(V) via an in situ reduction and complexation reaction. The resulting compound, K2[IIII(IVO3)4]IVO3, exhibits exceptional second harmonic generation responses (21.6KH2PO4 at 1064 nm, 1.0KTiOPO4 at 2050 nm), a wide transparency range from the visible to the mid-infrared wavelengths (0.37-6.05 μm and 7.03-13.40 μm), and a high birefringence (0.358 at 543 nm) to achieve full-wavelength phase matching. These properties are primarily ascribed to the synergistic substantial hyperpolarizability and polarizability anisotropy exhibited by the [IIII(IVO3)4]- complex ions, which comprise square-planar coordinated trivalent iodine and optimally arranged iodate ligands. This study demonstrates the pivotal role of nonmetallic cation centered coordination entities in influencing linear and nonlinear optical properties, a discovery that has significant implications for the development of innovative inorganic functional materials.The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full-wavelength phase matching capabilities remains a significant challenge. In this study, we synthesized a novel potassium tetraiodatoiodate(III) iodate(V) via an in situ reduction and complexation reaction. The resulting compound, K2[IIII(IVO3)4]IVO3, exhibits exceptional second harmonic generation responses (21.6KH2PO4 at 1064 nm, 1.0KTiOPO4 at 2050 nm), a wide transparency range from the visible to the mid-infrared wavelengths (0.37-6.05 μm and 7.03-13.40 μm), and a high birefringence (0.358 at 543 nm) to achieve full-wavelength phase matching. These properties are primarily ascribed to the synergistic substantial hyperpolarizability and polarizability anisotropy exhibited by the [IIII(IVO3)4]- complex ions, which comprise square-planar coordinated trivalent iodine and optimally arranged iodate ligands. This study demonstrates the pivotal role of nonmetallic cation centered coordination entities in influencing linear and nonlinear optical properties, a discovery that has significant implications for the development of innovative inorganic functional materials.
The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full‐wavelength phase matching capabilities remains a significant challenge. In this study, we synthesized a novel potassium tetraiodatoiodate(III) iodate(V) via an in‐situ reduction and complexation reaction. The resulting compound, K 2 [I III (I V O 3 ) 4 ]I V O 3 , exhibits exceptional second‐harmonic generation responses (21.6KH 2 PO 4 at 1064 nm, 1.0KTiOPO 4 at 2050 nm), a wide transparency range from the visible to the mid‐infrared wavelengths (0.37–6.05 and 7.03–13.40 µm), and a high birefringence (0.358 at 543 nm) to achieve full‐wavelength phase matching. These properties are primarily ascribed to the synergistic substantial hyperpolarizability and polarizability anisotropy exhibited by the [I III (I V O 3 ) 4 ] − complex ions, which comprise square‐planar coordinated trivalent iodine and optimally arranged iodate ligands. This study demonstrates the pivotal role of nonmetallic cation centered coordination entities in influencing linear and nonlinear optical properties, a discovery that has significant implications for the development of innovative inorganic functional materials.
The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full‐wavelength phase matching capabilities remains a significant challenge. In this study, we synthesized a novel potassium tetraiodatoiodate(III) iodate(V) via an in‐situ reduction and complexation reaction. The resulting compound, K2[IIII(IVO3)4]IVO3, exhibits exceptional second‐harmonic generation responses (21.6KH2PO4 at 1064 nm, 1.0KTiOPO4 at 2050 nm), a wide transparency range from the visible to the mid‐infrared wavelengths (0.37–6.05 and 7.03–13.40 µm), and a high birefringence (0.358 at 543 nm) to achieve full‐wavelength phase matching. These properties are primarily ascribed to the synergistic substantial hyperpolarizability and polarizability anisotropy exhibited by the [IIII(IVO3)4]− complex ions, which comprise square‐planar coordinated trivalent iodine and optimally arranged iodate ligands. This study demonstrates the pivotal role of nonmetallic cation centered coordination entities in influencing linear and nonlinear optical properties, a discovery that has significant implications for the development of innovative inorganic functional materials.
The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full‐wavelength phase matching capabilities remains a significant challenge. In this study, we synthesized a novel potassium tetraiodatoiodate(III) iodate(V) via an in‐situ reduction and complexation reaction. The resulting compound, K2[IIII(IVO3)4]IVO3, exhibits exceptional second‐harmonic generation responses (21.6KH2PO4 at 1064 nm, 1.0KTiOPO4 at 2050 nm), a wide transparency range from the visible to the mid‐infrared wavelengths (0.37–6.05 and 7.03–13.40 µm), and a high birefringence (0.358 at 543 nm) to achieve full‐wavelength phase matching. These properties are primarily ascribed to the synergistic substantial hyperpolarizability and polarizability anisotropy exhibited by the [IIII(IVO3)4]− complex ions, which comprise square‐planar coordinated trivalent iodine and optimally arranged iodate ligands. This study demonstrates the pivotal role of nonmetallic cation centered coordination entities in influencing linear and nonlinear optical properties, a discovery that has significant implications for the development of innovative inorganic functional materials. A novel potassium tetraiodatoiodate(III) iodate(V), K2[IIII(IVO3)4]IVO3, has been successfully synthesized via an innovative in‐situ reduction and complexation reaction. This atypical inorganic nonmetallic coordination compound, featuring trivalent iodine as the central coordination atom, exhibits exceptional potential as a second‐order nonlinear optical material. It demonstrates remarkable second‐harmonic generation responses (21.6KH2PO4 at 1064 nm, 1.0KTiOPO4 at 2050 nm), a broad transparency range from the visible to the mid‐infrared wavelengths (0.37–6.05 and 7.03–13.40 µm), and a high birefringence (0.358 at 543 nm) enabling rare full‐wavelength phase matching.
Author Yang, Bing‐Ping
Li, Bing‐Xuan
Mao, Jiang‐Gao
Lin, Min‐Quan
Hu, Chun‐Li
Duan, Meng‐Fan
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  fullname: Hu, Chun‐Li
  organization: University of Chinese Academy of Sciences
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Keywords Coordination compound
Full‐wavelength phase matching
Hypervalent iodine
NLO materials
Partial reduction reaction
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Snippet The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full‐wavelength phase...
The development of nonlinear optical materials with large nonlinear optical susceptibilities, wide transmission ranges, and comprehensive full-wavelength phase...
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StartPage e202504673
SubjectTerms Anisotropy
Birefringence
Coordination compound
Full‐wavelength phase matching
Functional materials
Harmonic generations
Hypervalent iodine
Iodine
NLO materials
Nonlinear optics
Optical materials
Optical properties
Partial reduction reaction
Phase matching
Polarizability
Potassium
Wavelength
Wavelengths
Title Potassium Tetraiodatoiodate(III) Iodate(V): A Nonlinear Optical Crystal with Exceptional Second‐Harmonic Generation and Full‐Wavelength Phase Matching
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fanie.202504673
https://www.ncbi.nlm.nih.gov/pubmed/40163014
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https://www.proquest.com/docview/3184570823
Volume 64
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