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• W4313236613 endingPage "582" @default.
• W4313236613 startingPage "574" @default.
• W4313236613 abstract "Two acentric chalcogenide compounds, K2CdGe3S8 and K2CdGe3Se8, were synthesized via conventional high-temperature solid-state reactions. The crystal structures of K2CdGe3S8 and K2CdGe3Se8 were accurately determined by single-crystal X-ray diffraction and crystallize in the K2FeGe3S8 structure type. K2CdGe3S8 is isostructural to K2FeGe3S8 with superior nonlinear optical properties. For the second harmonic generation (SHG) response, K2CdGe3S8 is 18× K2FeGe3S8 for samples of particle size of 38-55 μm. The superior nonlinear optical properties of K2CdGe3S8 over K2FeGe3S8 are mainly contributed by the chemical characteristics of Cd compared with Fe, which are elucidated by nonlinear optical property measurements, electronic structure calculations, and density functional theory calculations. The [CdS4] tetrahedra within K2CdGe3S8 exhibit a higher degree of distortion and larger volume compared to the [FeS4] tetrahedra in K2FeGe3S8. This study possesses a good platform to investigate how d-block elements contribute to the SHG response. The fully occupied d10-elements are better for SHG susceptibility than d6-elements in this study. K2CdGe3S8 is a good candidate as an infrared nonlinear optical material of high SHG response (2.1× AgGaS2, samples of particle size of 200-250 μm), type-I phase-matching capability, high laser damage threshold (6.2× AgGaS2), and good stability." @default.
• W4313236613 created "2023-01-06" @default.
• W4313236613 creator A5022903980 @default.
• W4313236613 creator A5029257600 @default.
• W4313236613 creator A5045460496 @default.
• W4313236613 creator A5065063614 @default.
• W4313236613 creator A5076891744 @default.
• W4313236613 date "2022-12-27" @default.
• W4313236613 modified "2023-09-27" @default.
• W4313236613 title "d⁶<i>versus</i> d¹⁰, Which Is Better for Second Harmonic Generation Susceptibility? A Case Study of K₂TGe₃Ch₈ (T = Fe, Cd; Ch = S, Se)" @default.
• W4313236613 cites W1965154772 @default.
• W4313236613 cites W1979368839 @default.
• W4313236613 cites W1982583450 @default.
• W4313236613 cites W1993579001 @default.
• W4313236613 cites W1994880295 @default.
• W4313236613 cites W2009076882 @default.
• W4313236613 cites W2016325227 @default.
• W4313236613 cites W2028039815 @default.
• W4313236613 cites W2039922514 @default.
• W4313236613 cites W2041893040 @default.
• W4313236613 cites W2045191079 @default.
• W4313236613 cites W2047263344 @default.
• W4313236613 cites W2052380206 @default.
• W4313236613 cites W2059274993 @default.
• W4313236613 cites W2061410433 @default.
• W4313236613 cites W2064658748 @default.
• W4313236613 cites W2085093563 @default.
• W4313236613 cites W2100894227 @default.
• W4313236613 cites W2107141326 @default.
• W4313236613 cites W2108338446 @default.
• W4313236613 cites W2149035808 @default.
• W4313236613 cites W2167650550 @default.
• W4313236613 cites W2256830989 @default.
• W4313236613 cites W2313968758 @default.
• W4313236613 cites W2328800059 @default.
• W4313236613 cites W2328954908 @default.
• W4313236613 cites W2333036772 @default.
• W4313236613 cites W2336781730 @default.
• W4313236613 cites W2418462194 @default.
• W4313236613 cites W2438289398 @default.
• W4313236613 cites W2471047469 @default.
• W4313236613 cites W2556254339 @default.
• W4313236613 cites W2558935017 @default.
• W4313236613 cites W2580266548 @default.
• W4313236613 cites W2594172079 @default.
• W4313236613 cites W2602804263 @default.
• W4313236613 cites W2609865870 @default.
• W4313236613 cites W2613175206 @default.
• W4313236613 cites W2625539153 @default.
• W4313236613 cites W2756427999 @default.
• W4313236613 cites W2796767663 @default.
• W4313236613 cites W2803484276 @default.
• W4313236613 cites W2884864685 @default.
• W4313236613 cites W2889144404 @default.
• W4313236613 cites W2900525384 @default.
• W4313236613 cites W2912432336 @default.
• W4313236613 cites W2949314515 @default.
• W4313236613 cites W2950198643 @default.
• W4313236613 cites W2952686123 @default.
• W4313236613 cites W2953129065 @default.
• W4313236613 cites W2955125204 @default.
• W4313236613 cites W2982636042 @default.
• W4313236613 cites W2995116823 @default.
• W4313236613 cites W2995300520 @default.
• W4313236613 cites W2999025538 @default.
• W4313236613 cites W3000205468 @default.
• W4313236613 cites W3009780705 @default.
• W4313236613 cites W3048851191 @default.
• W4313236613 cites W3090198507 @default.
• W4313236613 cites W3116436612 @default.
• W4313236613 cites W3126795569 @default.
• W4313236613 cites W3133657241 @default.
• W4313236613 cites W3152545139 @default.
• W4313236613 cites W3176595553 @default.
• W4313236613 cites W3183988065 @default.
• W4313236613 cites W3196637215 @default.
• W4313236613 cites W3199901323 @default.
• W4313236613 cites W4206284274 @default.
• W4313236613 cites W4206632430 @default.
• W4313236613 cites W4210249328 @default.
• W4313236613 cites W4210406790 @default.
• W4313236613 cites W4211038198 @default.
• W4313236613 cites W4236818499 @default.
• W4313236613 cites W4280651768 @default.
• W4313236613 cites W4281677368 @default.
• W4313236613 cites W4283511199 @default.
• W4313236613 cites W4294865212 @default.
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• W4313236613 doi "https://doi.org/10.1021/acs.inorgchem.2c03852" @default.
• W4313236613 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/36574629" @default.
• W4313236613 hasPublicationYear "2022" @default.
• W4313236613 type Work @default.
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