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Synthesis and thermal studies of two phosphonium tetrahy-droxidohexaoxidopentaborate(1-) salts: single-crystal XRD characterization of [iPrPPh3][B5O6(OH)4].3.5H2O and [MePPh3][B5O6(OH)4].B(OH)3.0.5H2O. / Beckett, Michael; Horton, Peter; Hursthouse, M.B. et al.
In: Molecules, Vol. 28, No. 19, 6867, 29.09.2023.

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T1 - Synthesis and thermal studies of two phosphonium tetrahy-droxidohexaoxidopentaborate(1-) salts: single-crystal XRD characterization of [iPrPPh3][B5O6(OH)4].3.5H2O and [MePPh3][B5O6(OH)4].B(OH)3.0.5H2O

AU - Beckett, Michael

AU - Horton, Peter

AU - Hursthouse, M.B.

AU - Timmis, James

PY - 2023/9/29

Y1 - 2023/9/29

N2 - Two substituted phosphonium tetrahydoxidohexaoxidopentaborate(1-) salts, [ iPrPPh 3][B 5O 6(OH) 4]·3.5H 2O ( 1) and [MePPh 3][B 5O 6(OH) 4]·B(OH) 3·0.5H 2O ( 2), were prepared by templated self-assembly processes with good yields by crystallization from basic methanolic aqueous solutions primed with B(OH) 3 and the appropriate phosphonium cation. Salts 1 and 2 were characterized by spectroscopic (NMR and IR) and thermal (TGA/DSC) analysis. Salts 1 and 2 were thermally decomposed in air at 800 °C to glassy solids via the anhydrous phosphonium polyborates that are formed at lower temperatures (<300 °C). BET analysis of the anhydrous and pyrolysed materials indicated they were non-porous with surface areas of 0.2-2.75 m 2/g. Rhe recrystallization of 1 and 2 from aqueous solution afforded crystals suitable for single-crystal XRD analyses. The structure of 1 comprises alternating cationic/anionic layers with the H 2O/pentaborate(1-) planes held together by H-bonds. The cationic planes have offset face-to-face ( off) and vertex-to-face ( vf) aromatic ring interactions with the iPr groups oriented towards the pentaborate(1-)/H 2O layers. The anionic lattice in 2 is expanded by the inclusion of B(OH) 3 molecules to accommodate the large cations; this results in the formation of a stacked pentaborate(1-)/B(OH) 3 structure with channels occupied by the cations. The cations within the channels have vf, ef (edge-to-face), and off phenyl embraces. Both H-bonding and phenyl embrace interactions are important in stabilizing these two solid-state structures.

AB - Two substituted phosphonium tetrahydoxidohexaoxidopentaborate(1-) salts, [ iPrPPh 3][B 5O 6(OH) 4]·3.5H 2O ( 1) and [MePPh 3][B 5O 6(OH) 4]·B(OH) 3·0.5H 2O ( 2), were prepared by templated self-assembly processes with good yields by crystallization from basic methanolic aqueous solutions primed with B(OH) 3 and the appropriate phosphonium cation. Salts 1 and 2 were characterized by spectroscopic (NMR and IR) and thermal (TGA/DSC) analysis. Salts 1 and 2 were thermally decomposed in air at 800 °C to glassy solids via the anhydrous phosphonium polyborates that are formed at lower temperatures (<300 °C). BET analysis of the anhydrous and pyrolysed materials indicated they were non-porous with surface areas of 0.2-2.75 m 2/g. Rhe recrystallization of 1 and 2 from aqueous solution afforded crystals suitable for single-crystal XRD analyses. The structure of 1 comprises alternating cationic/anionic layers with the H 2O/pentaborate(1-) planes held together by H-bonds. The cationic planes have offset face-to-face ( off) and vertex-to-face ( vf) aromatic ring interactions with the iPr groups oriented towards the pentaborate(1-)/H 2O layers. The anionic lattice in 2 is expanded by the inclusion of B(OH) 3 molecules to accommodate the large cations; this results in the formation of a stacked pentaborate(1-)/B(OH) 3 structure with channels occupied by the cations. The cations within the channels have vf, ef (edge-to-face), and off phenyl embraces. Both H-bonding and phenyl embrace interactions are important in stabilizing these two solid-state structures.

KW - Organotriphenylphosphonium salts; -interactions; pentaborate(1-); phenyl embraces; phos-phonium salts; tetrahydroxidohexaoxidopentaborate(1-); X-ray structures.

U2 - 10.3390/molecules28196867

DO - 10.3390/molecules28196867

M3 - Article

C2 - 37836710

VL - 28

JO - Molecules

JF - Molecules

SN - 1420-3049

IS - 19

M1 - 6867

ER -