Synthesis, structure, magnetic and photoelectric properties of Ln3M0.5M′Se7 (Ln = La, Ce, Sm; M = Fe, Mn; M′ = Si, Ge) and La3MnGaSe7

He, Jianqiao; Wang, Zhe; Zhang, Xian; Ye, Cheng; Gong, Yu Ting; Lai, Xiaofang; Zheng, Chong; Lin, Jianhua; Huang, Fuqiang

doi:10.1039/c5ra05629b

Cited by 21 publications

(12 citation statements)

References 41 publications

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“…A few more chalcogenides and related materials have also been successfully synthesized by the MSS strategy, such as Fe(Se 0.5 Te 0.5 ) solid pellet, 1D zinc selenophosphates, sulfur-doped silicon, La 3 Fe 0.5 GeSe 7 , La 3 MnGaSe 7 , Ce 3 Fe 0.5 SiSe 7 , Ce 3 Mn 0.5 SiSe 7 , Sm 3 Fe 0.5 SiSe 7 , Sm 3 Mn 0.5 GeSe 7 , Cu 10 Cd 2 Sb 4 S 13 , etc. − The MSS has also been employed to prepare chalocogenide-related heterojunctions. For example, Zhong et al synthesized TiO 2 NP@MoS 2 nanosheet heterojunction using the MSS strategy (Figure d–f) .…”

Section: Other Nanomaterials Synthesized By the Mss Methodsmentioning

confidence: 99%

Recent Developments on Molten Salt Synthesis of Inorganic Nanomaterials: A Review

2021

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A wide range of inorganic nanomaterials with many fascinating properties and application potentials in widespread fields may be synthesized by wet chemical synthetic routes. To achieve scientific and commercial viability of nanomaterials with uniformity and scalability, it is necessary to develop efficient and cost-effective, preferably sustainable, methods. The molten salt synthesis (MSS) method is one such bottom-up technique to fabricate a wide variety of inorganic nanomaterials with tunable size, morphology, and surface characteristics. It is also environmentally friendly, cost-effective, simple to operate, easy to scale, and generalizable, etc. This review gives a critical overview on this emerging and rapidly developing method for making defect free nanomaterials in well-defined texture, surface, and morphology at a relatively low formation temperature. We have discussed its different aspects, including the role of molten salts, the choice of molten salts, the electrochemical aspects, some advanced modifications of the conventional MSS technique, and their implications. To show the most recent development on MSS synthesized inorganic nanomaterials, this review only encompasses the studies reported over the last six years (2015−2020). We have summarized technologically important and emerging families of inorganic nanomaterials such as metal oxides, fluorides, nitrides, silicides, chalcogenides, oxohalides, borides, and carbides. Finally, a few perspectives for the MSS method are highlighted. It is expected that this review will further attract scientists to explore the MSS method in making size-and shape-tunable nanomaterials.

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Section: Other Nanomaterials Synthesized By the Mss Methodsmentioning

confidence: 99%

Recent Developments on Molten Salt Synthesis of Inorganic Nanomaterials: A Review

2021

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“…For the chemical formula RE 6 B x C y Ch 14 , elements that can be found occupying the RE atomic position are presented in yellow, elements that can be found occupying the B atomic position are presented in orange, elements that can be found occupying the C atomic position are presented in blue, and elements that can be found occupying the Ch atomic position are presented in green. The broad structural flexibility of the RE 6 B x C y Ch 14 family results in properties such as variable bandgaps spanning 1.13 eV (Sm 3 Fe 0.5 SiSe 7 [3] ) to 3.01 eV (La 3 LiGeS 7 [1] ), and intriguing nonlinear optical properties, such as in La 3 GaGe 0.5 S 7 (4.8 × AgGaS 2 [2] ). As the first few reported compounds in the RE 6 B x C y Ch 14 family, Y 6 Si 2.5 S 14 and Y 6 Ge 2.5 S 14 were discovered in 1969.…”

Section: Introductionmentioning

confidence: 99%

Synthesis, Crystal Growth, Electronic Properties and Optical Properties of Y₆IV_2.5S₁₄ (IV=Si, Ge)

Bardelli

et al. 2021

Zeitschrift anorg allge chemie

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Two isostructural ternary acentric sulfides, Y 6 Si 2.5 S 14 (1) and Y 6 Ge 2.5 S 14 (2) were re-investigated to understand the origin of the chemical flexibility of RE 6 B x C y Ch 14 (RE=Y, LaÀ Lu; B=Si, Ge, Sn, Al, Ga; C = monovalent M + (Ag, Na, Li, etc.), divalent M 2 + (Mg, Cr, Ni, Zn, etc.), trivalent M 3 + (Al, In, Ga, etc.), tetravalent M 4 + (Si, Ge, Sn) and pentavalent M 5 + (Sb), Ch=S, Se), which consists of ~444 isostructural compounds. Y 6 IV 2.5 S 14 (IV=Si, Ge) were synthesized by a high-temperature salt flux method. The crystal structures of Y 6 IV 2.5 S 14 (IV=Si, Ge) are constructed by [YS 8 ] polyhedra, [Si1S 6 ] octahedra, and [Si2S 4 ] tetrahedra. The Si1 atom displaces from the center of [Si1S 6 ] octahedra with partial occupancy, which can be replaced by various metals, and mainly accounts for the chemical flexibility of the RE 6 B x C y Ch 14 family. The bonding pictures of Y 6 Si 2.5 S 14 were studied by electron localization function (ELF) and crystal orbital Hamilton population (COHP) calculations. Y 6 Si 2.5 S 14 is evaluated as an indirect semiconductor with a bandgap of 2.4(1) eV measured by UV-Vis. The indirect bandgap of Y 6 Ge 2.5 S 14 is 1.7(1) eV. Y 6 IV 2.5 S 14 (IV=Si, Ge) are not type-I phase-matchable materials. For samples of 47 μm particle size, Y 6 Si 2.5 S 14 and Y 6 Ge 2.5 S 14 own good second harmonic generation (SHG) responses of ~3.0 × AGS and ~2.8 × AGS respectively. Y 6 Si 2.5 S 14 and Y 6 Ge 2.5 S 14 possess high laser damage threshold (LDT) of ~5.5 × AGS and ~5.2 × AGS respectively.

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“…Desirable properties for an IR NLO material include (1) a large NLO coefficient to increase the energy conversion efficiency, (2) a sufficiently large birefringence (Dn) to satisfy the phase-matching requirement, (3) a wide IR transparency region, (4) a high laser-induced damage threshold and (5) good chemical and thermal stability. 15 During the last few decades, research was widely carried out on metal chalcogenides, [16][17][18][19][20][21][22][23] a rich source of IR nonlinear optical materials. [24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40] Compared with oxides, metal chalcogenides have a much broader IR transmission range and hence are more suitable for IR NLO applications.…”

Section: Introductionmentioning

confidence: 99%

BaGa₂SnSe₆: a new phase-matchable IR nonlinear optical material with strong second harmonic generation response

Gong

et al. 2015

J. Mater. Chem. C

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Synthesis, structure, magnetic and photoelectric properties of Ln₃M_0.5M′Se₇ (Ln = La, Ce, Sm; M = Fe, Mn; M′ = Si, Ge) and La₃MnGaSe₇

Cited by 21 publications

References 41 publications

Recent Developments on Molten Salt Synthesis of Inorganic Nanomaterials: A Review

Recent Developments on Molten Salt Synthesis of Inorganic Nanomaterials: A Review

Synthesis, Crystal Growth, Electronic Properties and Optical Properties of Y₆IV_2.5S₁₄ (IV=Si, Ge)

BaGa₂SnSe₆: a new phase-matchable IR nonlinear optical material with strong second harmonic generation response

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Synthesis, structure, magnetic and photoelectric properties of Ln3M0.5M′Se7 (Ln = La, Ce, Sm; M = Fe, Mn; M′ = Si, Ge) and La3MnGaSe7

Cited by 21 publications

References 41 publications

Recent Developments on Molten Salt Synthesis of Inorganic Nanomaterials: A Review

Recent Developments on Molten Salt Synthesis of Inorganic Nanomaterials: A Review

Synthesis, Crystal Growth, Electronic Properties and Optical Properties of Y6IV2.5S14 (IV=Si, Ge)

BaGa2SnSe6: a new phase-matchable IR nonlinear optical material with strong second harmonic generation response

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Synthesis, structure, magnetic and photoelectric properties of Ln₃M_0.5M′Se₇ (Ln = La, Ce, Sm; M = Fe, Mn; M′ = Si, Ge) and La₃MnGaSe₇

Synthesis, Crystal Growth, Electronic Properties and Optical Properties of Y₆IV_2.5S₁₄ (IV=Si, Ge)

BaGa₂SnSe₆: a new phase-matchable IR nonlinear optical material with strong second harmonic generation response