Mastering extreme size constraints in the clathrate‐I borosilicide Cs₈B₈Si₃₈

Abstract: Cs8B8Si38 is obtained by high‐pressure high‐temperature synthesis at p=8 GPa and T=1273 K. The new compound (space group Pm3‾ n; a=10.0312(3) Å) is the third example for a clathrate‐I borosilicide after the potassium and rubidium varieties, respectively. The phase slowly deteriorates in air and moisture but is thermally stable up to 1050 K at ambient pressure. [Cs+]8[B–]8[Si0]38 is electronically balanced, diamagnetic, and shows semiconducting behavior.

“…It is interesting to compare the boron substitution trends for carbon clathrates with those of the substitutions observed for silicon clathrate frameworks. In contrast with the type-I carbon clathrates here, previous studies have found that the 16 i site is preferable for boron substitution in type-I silicon clathrates (e.g., K 7 B 7 Si 39 ). − The occupation of 16 i , which is exclusively located in pentagonal rings, helps relieve bond strain caused by the large disparity in B–Si and Si–Si bond distances . For type-I silicon clathrates with Al substitutions, e.g., Ba 8 Al x Si 46– x , the occupation of the 6 c and 24 k sites are favorable for Al atoms at small (e.g., x = 8) and large (e.g., x = 15) bulk Al concentrations, respectively. , Al substitution in type-I silicon clathrates is similar to the trends observed here for B substitution in type-I carbon clathrates.…”

“…83−85 The occupation of 16i, which is exclusively located in pentagonal rings, helps relieve bond strain caused by the large disparity in B−Si and Si−Si bond distances. 84 For type-I silicon clathrates with Al substitutions, e.g., Ba 8 Al x Si 46−x , the occupation of the 6c and 24k sites are favorable for Al atoms at small (e.g., x = 8) and large (e.g., x = 15) bulk Al concentrations, respectively. 86,87 Al substitution in type-I silicon clathrates is similar to the trends observed here for B substitution in type-I carbon clathrates.…”

Computational Screening and Stabilization of Boron-Substituted Type-I and Type-II Carbon Clathrates

“…It is interesting to compare the boron substitution trends for carbon clathrates with those of the substitutions observed for silicon clathrate frameworks. In contrast with the type-I carbon clathrates here, previous studies have found that the 16 i site is preferable for boron substitution in type-I silicon clathrates (e.g., K 7 B 7 Si 39 ). − The occupation of 16 i , which is exclusively located in pentagonal rings, helps relieve bond strain caused by the large disparity in B–Si and Si–Si bond distances . For type-I silicon clathrates with Al substitutions, e.g., Ba 8 Al x Si 46– x , the occupation of the 6 c and 24 k sites are favorable for Al atoms at small (e.g., x = 8) and large (e.g., x = 15) bulk Al concentrations, respectively. , Al substitution in type-I silicon clathrates is similar to the trends observed here for B substitution in type-I carbon clathrates.…”

“…83−85 The occupation of 16i, which is exclusively located in pentagonal rings, helps relieve bond strain caused by the large disparity in B−Si and Si−Si bond distances. 84 For type-I silicon clathrates with Al substitutions, e.g., Ba 8 Al x Si 46−x , the occupation of the 6c and 24k sites are favorable for Al atoms at small (e.g., x = 8) and large (e.g., x = 15) bulk Al concentrations, respectively. 86,87 Al substitution in type-I silicon clathrates is similar to the trends observed here for B substitution in type-I carbon clathrates.…”

Computational Screening and Stabilization of Boron-Substituted Type-I and Type-II Carbon Clathrates

“…In the course of this work, several other Rb- and Cs-containing compounds (not just antimonides) not included in the original machine learning data set were discovered and their structures were experimentally determined: (i) channel structures for ATrSb 4 (A = Rb or Cs; Tr = Al or Ga); (ii) layered structures for ATrSb (A = Rb or Cs; Tr = Cd or Zn), Rb 2 Mo 2 As 3 , CsGa 6.05 In 0.95 , and RbGa 6.31 In 0.69 ; (iii) clathrate structures for A 8 Ga 27 Sb 19 (A = Rb or Cs), Cs 8 In 27 Sb 29 , Rb 4 Si 19 B 4 , Cs 4 Si 19 B 4 , and Cs 4 Ga 3.75 Sn 19.25 ; and (iv) network structures for Rb 3 Ga 12.32 In 0.68 and Rb 3 Hg 0.42 Ga 12.58 . All of these structures are in good agreement with those of the SISSO-derived models (Figure ).…”

Discovery of Ternary Antimonides A–Al–Sb (A = Rb or Cs) with Desired Structural Motifs Guided by Machine Learning

“…27 Hu ¨bner et al synthesized two semiconductors: Rb 8 B 8 Si 38 with moderate thermoelectric properties 28 and Cs 8 B 8 Si 38 with fairly good thermal stability. 29 In contrast, we conducted theoretical investigations on ternary alkali metal borosilicides with the formula AB 3 Si 3 (A = Na/K/Rb/Cs), 30 which is isomorphic to the aforementioned SrB 3 C 3 compound. 15 RbB 3 Si 3 can be quenched under ambient conditions and possess superconductivity with a T c value of 14 K. 30 However, the novel physical phenomena of non-clathrate AB 3 Si 3 (A = Na/K/Rb/Cs) compounds under high pressure, including the rich phase diagram, stability, and tunable electronic properties, are still largely unknown, despite their important role in the field of new materials.…”

Exploration of AB₃Si₃ (A = Na/K/Rb/Cs) compounds under moderate pressure