Cd<sub>4</sub>SiQ<sub>6</sub> (Q = S, Se): Ternary Infrared Nonlinear Optical Materials with Mixed Functional Building Motifs

Chen, Jindong; Lin, Chensheng; Yang, Shunda; Jiang, Xiaotian; Shi, Shuangshuang; Sun, Yimeng; Li, Bingxuan; Fang, Shenghao; Ye, Ning

doi:10.1021/acs.cgd.9b01649

Cited by 17 publications

(7 citation statements)

References 52 publications

(65 reference statements)

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“…Besides, α-Ca 2 CdP 2 and β-Ca 2 CdP 2 exhibited stronger SHG intensities than AgGaS 2 (∼1.41 and 3.28× that of AgGaS 2 , respectively, among particle sizes of 150–200 μm at 2050 nm laser) and could be potential IR NLO materials. As a contrast, the title compounds had comparable or even larger SHG intensities than some Cd-based IR NLO materials, such as Cd 4 GeS 6 (1.1× that of AgGaS 2 ), Cd 4 SiS 6 (1.3× that of AgGaS 2 ), LiCd 3 PS 6 (0.8× that of AgGaS 2 ), Li 2 CdGeS 4 (0.4× that of AgGaS 2 ), Li 2 CdSnS 4 (0.6× that of AgGaS 2 ), and Na 2 CdGe 2 S 6 (0.8× that of AgGaS 2 ) . As illustrated in Table , α-Ca 2 CdP 2 and β-Ca 2 CdP 2 performed well in regard to both their SHG effects and band gaps compared to some known IR NLO materials, thus achieving a relative balance between the SHG effects and band gaps.…”

Section: Resultsmentioning

confidence: 92%

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α-Ca₂CdP₂ and β-Ca₂CdP₂: Two Polymorphic Phosphide-Based Infrared Nonlinear Crystals with Distorted NLO-Active Tetrahedral Motifs Realizing Large Second Harmonic Generation Effects and Suitable Band Gaps

et al. 2021

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Two polymorphic phosphide-based infrared (IR) nonlinear optical (NLO) crystals, α-Ca2CdP2 and β-Ca2CdP2, were obtained by combining alkaline-earth metals and d10 transition metals using metal flux and metal salt flux methods, respectively. The crystal structure of α-Ca2CdP2 is orthorhombic in the space group Cmc21 (no. 36), while the structure of β-Ca2CdP2 is monoclinic in the space group Cm (no. 8). Both are two-dimensional layered structures that are composed of CdP4 tetrahedra layers via sharing vertices, which stack along the b-axis and the c-axis, respectively. The second harmonic generation (SHG) measurements manifest that α-Ca2CdP2 and β-Ca2CdP2 exhibit strong SHG intensities (1.41 and 3.28× that of AgGaS2 at a 2050 nm laser, respectively). Other optical measurements indicate that α-Ca2CdP2 and β-Ca2CdP2 have suitable band gaps (1.98 and 1.55 eV, respectively), high laser-induced damage thresholds (4.5 and 3.1× that of AgGaS2 at 1064 nm laser, respectively) and appropriate birefringence (0.12 and 0.20 at 2050 nm, respectively) in addition to covering wide infrared transparent regions. The research on α-Ca2CdP2 and β-Ca2CdP2 demonstrates that they are potential IR NLO candidates. Theoretical calculations uncover that their SHG effects are from distorted CdP4 tetrahedra, highlighting that tetrahedral motifs, including d10 transition metals, would be ideal NLO-active building blocks.

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Section: Resultsmentioning

confidence: 92%

“…), and d 10 transition metals (Zn 2+ , Ag + , Cd 2+ , etc. ) − have been considered to be introduced to IR NLO phosphides. Because these cations benefit from the second-order Jahn–Teller (SOJT) effect or a large polar displacement, they easily form asymmetrical polyhedra and are thus favorable for generating larger SHG responses.…”

Section: Introductionmentioning

confidence: 99%

α-Ca₂CdP₂ and β-Ca₂CdP₂: Two Polymorphic Phosphide-Based Infrared Nonlinear Crystals with Distorted NLO-Active Tetrahedral Motifs Realizing Large Second Harmonic Generation Effects and Suitable Band Gaps

et al. 2021

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“…[2] Na 2 Hg 3 Si 2 S 8 and Na 2 Hg 3 Ge 2 S 8 feature tetrahedral (TS 4 ) 4À anions and present strong phasematching (PM) SHG responses of 2.3 and 2.2 × AGS and elevated LIDTs of 4.5 and 3 × AGS, respectively. [3] Distorted (TS 4 ) 4À units are found in Cd 4 SiS 6 [4] and Cd 4 GeS 6 , [5] which give rise to PM SHG signals of 1.5 and 1.1 × AGS and impressive LIDTs of 8.6 and 3.6 × AGS, respectively. Ba 2 Ga 8 GeS 16 , which contains mixed (Ga/ Ge)S 4 and GaS 4 tetrahedra exhibits a decent PM SHG response, with a χ (2) of 6.6 pm/V and a remarkable LIDT of 22 × AGS.…”

Section: Introductionmentioning

confidence: 99%

“…Metal thiosilicates and thiogermanates are attractive classes of solid-state materials with a rich structural diversity. In these compounds, various tetrel-sulfur anionic building units can be stabilized, including (TS 4 ) 4À , [1][2][3][4][5][6][7][8][9] (T 2 S 6 ) 4À , [10,11] (T 2 S 6 ) 6À , [12][13][14] (T 2 S 7 ) 6À , [15,16] and (T 4 S 10 ) 4À , [17,18] where T = Si or Ge. The tetrahedral (TS 4 ) 4À unit is the most prevalent of these anions in condensed inorganic phases.…”

Section: Introductionmentioning

confidence: 99%

Li₂Mg₂Si₂S₆ and Li₂Mg₂Ge₂S₆: Two nonlinear optical sulfides featuring a unique, polar trigonal structure incorporating ethane‐like anions

Barton

Liang

Craig

et al. 2022

Zeitschrift anorg allge chemie

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The new compounds Li 2 Mg 2 Si 2 S 6 and Li 2 Mg 2 Ge 2 S 6 have been prepared via traditional high-temperature, solid-state synthesis. The title compounds crystallize in the polar, noncentrosymmetric, trigonal space group P31m (No. 157) and adopt a new structure type featuring staggered, ethane-like (T 2 S 6 ) 6À units, where T = Si or Ge. These (T 2 S 6 ) 6À units are nestled within the holes of magnesium-sulfide "layers" that are created through the edge-sharing of MgS 6 octahedra. The holes found in the lithium-sulfide "layers", created by LiS 6 edge-sharing octahedra, remain vacant, containing no (T 2 S 6 ) 6À anionic group. Through the face sharing of the respective MgS 6 and LiS 6 octahedra, the magnesium-sulfide and lithium-sulfide "layers" are stitched together resulting in an overall three-dimensional structure. The optical bandgaps of Li 2 Mg 2 Si 2 S 6 and Li 2 Mg 2 Ge 2 S 6 are 3.24 and 3.18 eV, respectively, as estimated from optical diffuse reflectance UV-Vis-NIR spectroscopy. The compounds exhibit second harmonic generation responses of ~0.24 × KDP and ~2.92 × αquartz for Li 2 Mg 2 Si 2 S 6 and ~0.17 × KDP and ~2.08 × α-quartz for Li 2 Mg 2 Ge 2 S 6 , using a Nd:YAG laser at 1.064 μm. Electronic structure calculations were performed using density functional theory and the linearized augmented plane-wave approach within the WIEN2k software package. Examination of the electronic band structures shows that these compounds are indirect bandgap semiconductors.

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“…The thermogravimetric analysis (TGA) and the differential scanning calorimetry (DSC) curve (Figure S4, ESI †) show that LBS is stable up to at least 700 1C. Its melting point is about 713 1C, which is higher than those of ASb 5 S 8 (A = K, Rb; 400 1C), Cd 4 SiQ 6 (Q = S, Se; 710 1C, 362 1C), and Zn 3 P 2 S 8 (594 1C), [33][34][35] but much lower compared to that of AGS (998 1C). 36 According to the IR spectrum (Fig.…”

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confidence: 99%

LaBS₃ revisited: a promising mid-infrared nonlinear optical material

Han

Fang

et al. 2022

J. Mater. Chem. C

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Cd₄SiQ₆ (Q = S, Se): Ternary Infrared Nonlinear Optical Materials with Mixed Functional Building Motifs

Cited by 17 publications

References 52 publications

α-Ca₂CdP₂ and β-Ca₂CdP₂: Two Polymorphic Phosphide-Based Infrared Nonlinear Crystals with Distorted NLO-Active Tetrahedral Motifs Realizing Large Second Harmonic Generation Effects and Suitable Band Gaps

α-Ca₂CdP₂ and β-Ca₂CdP₂: Two Polymorphic Phosphide-Based Infrared Nonlinear Crystals with Distorted NLO-Active Tetrahedral Motifs Realizing Large Second Harmonic Generation Effects and Suitable Band Gaps

Li₂Mg₂Si₂S₆ and Li₂Mg₂Ge₂S₆: Two nonlinear optical sulfides featuring a unique, polar trigonal structure incorporating ethane‐like anions

LaBS₃ revisited: a promising mid-infrared nonlinear optical material

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Cd4SiQ6 (Q = S, Se): Ternary Infrared Nonlinear Optical Materials with Mixed Functional Building Motifs

Cited by 17 publications

References 52 publications

α-Ca2CdP2 and β-Ca2CdP2: Two Polymorphic Phosphide-Based Infrared Nonlinear Crystals with Distorted NLO-Active Tetrahedral Motifs Realizing Large Second Harmonic Generation Effects and Suitable Band Gaps

α-Ca2CdP2 and β-Ca2CdP2: Two Polymorphic Phosphide-Based Infrared Nonlinear Crystals with Distorted NLO-Active Tetrahedral Motifs Realizing Large Second Harmonic Generation Effects and Suitable Band Gaps

Li2Mg2Si2S6 and Li2Mg2Ge2S6: Two nonlinear optical sulfides featuring a unique, polar trigonal structure incorporating ethane‐like anions

LaBS3 revisited: a promising mid-infrared nonlinear optical material

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Cd₄SiQ₆ (Q = S, Se): Ternary Infrared Nonlinear Optical Materials with Mixed Functional Building Motifs

α-Ca₂CdP₂ and β-Ca₂CdP₂: Two Polymorphic Phosphide-Based Infrared Nonlinear Crystals with Distorted NLO-Active Tetrahedral Motifs Realizing Large Second Harmonic Generation Effects and Suitable Band Gaps

α-Ca₂CdP₂ and β-Ca₂CdP₂: Two Polymorphic Phosphide-Based Infrared Nonlinear Crystals with Distorted NLO-Active Tetrahedral Motifs Realizing Large Second Harmonic Generation Effects and Suitable Band Gaps

Li₂Mg₂Si₂S₆ and Li₂Mg₂Ge₂S₆: Two nonlinear optical sulfides featuring a unique, polar trigonal structure incorporating ethane‐like anions

LaBS₃ revisited: a promising mid-infrared nonlinear optical material