Evaluating the high-pressure structural response and crystal lattice interactions of the magnetically-bistable organic radical TTTA

Jonathan G. Richardson; Asato Mizuno; Yoshiaki Shuku; Kunio Awaga; Neil Robertson; Carole A. Morrison; Mark R. Warren; David R. Allan; Stephen A. Moggach

doi:10.1039/d1ce00577d

Evaluating the high-pressure structural response and crystal lattice interactions of the magnetically-bistable organic radical TTTA

Jonathan G. Richardson, Asato Mizuno, Yoshiaki Shuku, Kunio Awaga, Neil Robertson, Carole A. Morrison, Mark R. Warren, David R. Allan, Stephen A. Moggach

School of Molecular Sciences

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Abstract

Magnetic bistability has previously been observed and evaluated in an organic thiazyl radical 1,3,5-triathia-2,4,6-triazapentalenyl (TTTA). Herein, the structure-pressure response of TTTA has been evaluated by X-ray diffraction, where a lack of a structural phase transition up to 4.6 GPa certifies that the paramagnetic suppression is caused by a steady decrease in the separation between the moieties containing the radical electron along the π-stacking chains. The intermolecular interactions throughout the crystal lattice have also been calculated using the PIXEL method, and highlight the relative strength of the inter-column interactions in the two known polymorphs of TTTA, which provides extra justification for the cause of the wide magnetic hysteresis and its response to pressure.

Original language	English
Pages (from-to)	4444-4450
Number of pages	7
Journal	CrystEngComm
Volume	23
Issue number	25
DOIs	https://doi.org/10.1039/d1ce00577d
Publication status	Published - 7 Jul 2021

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title = "Evaluating the high-pressure structural response and crystal lattice interactions of the magnetically-bistable organic radical TTTA",

abstract = "Magnetic bistability has previously been observed and evaluated in an organic thiazyl radical 1,3,5-triathia-2,4,6-triazapentalenyl (TTTA). Herein, the structure-pressure response of TTTA has been evaluated by X-ray diffraction, where a lack of a structural phase transition up to 4.6 GPa certifies that the paramagnetic suppression is caused by a steady decrease in the separation between the moieties containing the radical electron along the π-stacking chains. The intermolecular interactions throughout the crystal lattice have also been calculated using the PIXEL method, and highlight the relative strength of the inter-column interactions in the two known polymorphs of TTTA, which provides extra justification for the cause of the wide magnetic hysteresis and its response to pressure.",

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T1 - Evaluating the high-pressure structural response and crystal lattice interactions of the magnetically-bistable organic radical TTTA

AU - Richardson, Jonathan G.

AU - Mizuno, Asato

AU - Shuku, Yoshiaki

AU - Awaga, Kunio

AU - Robertson, Neil

AU - Morrison, Carole A.

AU - Warren, Mark R.

AU - Allan, David R.

AU - Moggach, Stephen A.

PY - 2021/7/7

Y1 - 2021/7/7

N2 - Magnetic bistability has previously been observed and evaluated in an organic thiazyl radical 1,3,5-triathia-2,4,6-triazapentalenyl (TTTA). Herein, the structure-pressure response of TTTA has been evaluated by X-ray diffraction, where a lack of a structural phase transition up to 4.6 GPa certifies that the paramagnetic suppression is caused by a steady decrease in the separation between the moieties containing the radical electron along the π-stacking chains. The intermolecular interactions throughout the crystal lattice have also been calculated using the PIXEL method, and highlight the relative strength of the inter-column interactions in the two known polymorphs of TTTA, which provides extra justification for the cause of the wide magnetic hysteresis and its response to pressure.

AB - Magnetic bistability has previously been observed and evaluated in an organic thiazyl radical 1,3,5-triathia-2,4,6-triazapentalenyl (TTTA). Herein, the structure-pressure response of TTTA has been evaluated by X-ray diffraction, where a lack of a structural phase transition up to 4.6 GPa certifies that the paramagnetic suppression is caused by a steady decrease in the separation between the moieties containing the radical electron along the π-stacking chains. The intermolecular interactions throughout the crystal lattice have also been calculated using the PIXEL method, and highlight the relative strength of the inter-column interactions in the two known polymorphs of TTTA, which provides extra justification for the cause of the wide magnetic hysteresis and its response to pressure.

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Evaluating the high-pressure structural response and crystal lattice interactions of the magnetically-bistable organic radical TTTA

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Evaluating the high-pressure structural response and crystal lattice interactions of the magnetically-bistable organic radical TTTA

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