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

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

doi:10.1039/d1ce00577d

Cited by 6 publications

(3 citation statements)

References 40 publications

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“…Stable organic radicals that exhibit a hysteretic response to an external stimulus (temperature, light, or pressure) display physical properties such as magnetic bistability that are promising for use in nanotechnology devices. − Neutral organic π radicals have been extensively studied because their electron-exchange interactions can lead to dynamic structures weakly coupled; in which interconversion between radicals ( S = 1 / 2 ) and π or σ dimers ( S = 0) is possible. − These cooperative solid-state interactions between different centers allow variation of the crystalline lattice such that hysteretic first-order phase transitions can arise. While this parallels the well-known spin-crossover (SCO) phenomena of transition metal ion complexes, radical-based magnetically bistable systems are comparatively rare.…”

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confidence: 99%

“…While this parallels the well-known spin-crossover (SCO) phenomena of transition metal ion complexes, radical-based magnetically bistable systems are comparatively rare. The neutral heterocyclic thiazyl π radicals are among the most successful class of radicals in this regard, ,,,− with only a few examples of nitroxides ,− , triazinyl and spirophenalenyl derivatives known to be bistable. In these examples, magnetic switching typically occurs by breaking/forming antiferromagnetically coupled π dimers, although examples of weakly bonded σ dimers have also been reported. , …”

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Room-Temperature Magnetic Bistability in a Salt of Organic Radical Ions

et al. 2021

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Cocrystallization of 7,7′,8,8′-tetracyanoquinodimethane radical anion (TCNQ–•) and 3-methylpyridinium-1,2,3,5-dithiadiazolyl radical cation (3-MepyDTDA+•) afforded isostructural acetonitrile (MeCN) or propionitrile (EtCN) solvates containing cofacial π dimers of homologous components. Loss of lattice solvent from the diamagnetic solvates above 366 K affords a high-temperature paramagnetic phase containing discrete TCNQ–• and weakly bound π dimers of 3-MepyDTDA+•, as evidenced by X-ray diffraction methods and magnetic susceptibility measurements. Below 268 K, a first-order phase transition occurs, leading to a low-temperature diamagnetic phase with TCNQ–• σ dimer and π dimers of 3-MepyDTDA+•. This study reveals the first example of cooperative interactions between two different organic radical ions leading to magnetic bistability, and these results are central to the future design of multicomponent functional molecular materials.

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Room-Temperature Magnetic Bistability in a Salt of Organic Radical Ions

et al. 2021

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“…Molecular systems exhibiting magnetic bistability, i.e., two interchangeable stable magnetic phases that respond to external stimulus such as light, pressure, or temperature, have been of substantial interest for a variety of nanotechnological applications such as thermal sensors, switching units, information storage media, and so on. − Particularly, such bistable materials based on stable organic radicals are extremely appealing because they manifest not only the desired hysteretic responses that are traditionally considered to be exclusive to transition-metal-based spin-crossover (SCO) complexes but also the unique advantages of using versatile organic synthetic tools to facilely modulate their chemical structures and related properties including molecular packing patterns, spin states, electronic structures, charge distributions, etc. Therefore, accompanied by the extensive efforts devoted to the magnetic property studies of organic radicals over the past several decades, a body of magnetic bistable materials have been developed based on both charge neutral and ionic radicals, − among which the seminal examples include the thiazyl-, − spirophenalenyl-, nitroxide-, − and dithiadiazolyl-based neutral radicals, as well as several charged (di)radical ion salts. , However, when compared to the well-known inorganic transition metal ion complex-based bistable materials enabled by SCO, currently the reported amounts of radicals-based all-organic materials with controlled magnetic bistability are far rarer, − imposing severe restrictions on their practical applications. Therefore, it is still imperative, but highly challenging, to further develop novel organic-radical-based bistable material systems with informative illustrations of how the chemical/electronic structures of these materials affect their magnetic bistable behaviors.…”

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Magnetic Bistability in an Organic Radical-Based Charge Transfer Cocrystal

Lai,

Bu,

Xiao

et al. 2023

J. Am. Chem. Soc.

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We report herein an organic charge transfer cocrystal complex, consisting of a stable radical TPVr and an electron acceptor TCNQF 4 , as a rare sort of all-organic-based magnetic bistable materials with a thermally activated magnetic hysteresis loop over the temperature range from 170 to 260 K. Detailed X-ray crystallographic studies and theoretical calculations revealed that while a π-associated radical anion dimer was formed upon an integer charge transfer process from TPVr to the TCNQF 4 molecules within the cocrystal lattice, the resulting TCNQF 4 ·– π-dimers were found to exhibit varied intradimer π-stacking distances and singly occupied molecular orbital overlaps at different temperatures, thus yielding two different singlet states with distinct singlet–triplet gaps above and below the loop, which eventually contributed to the thermally excited molecular magnetic bistability.

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Hysteretic Room‐Temperature Magnetic Bistability of the Crystalline 4,7‐Difluoro‐1,3,2‐Benzodithiazolyl Radical

Makarov,

Buravlev,

Romanenko

et al. 2024

ChemPlusChem

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The title radical R·, synthesized by reduction of the corresponding cation R+, is thermally stable up to ~380 K in the crystalline state under anaerobic conditions. With SQUID magnetometry, single‐crystal and powder XRD, solid‐state EPR and TG‐DSC, reversible spin‐Peierls transition between diamagnetic and paramagnetic states featuring ~10 K hysteretic loop is observed for R· in the temperature range ~ 310‐325 K; ΔH = ~2.03 kJ mol–1 and ΔS = ~6.23 J mol–1 K–1. The transition is accompanied by mechanical movement of the crystals, i.e., by thermosalient behavior. The low‐temperature diamagnetic P–1 polymorph of R· consists of R·2 π‐dimers arranged in (…R·2…)n π‐stacks; whereas the high‐temperature paramagnetic P21/c polymorph, of uniform (…R·…)n π‐stacks. With the XRD geometries, CASSCF and broken‐symmetry DFT jointly suggest strong antiferromagnetic (AF) interactions within R·2 and weak between R·2 for the (…R·2…)n stacks; and moderate AF interactions between R· for the (…R·…)n stacks. The fully hydrocarbon archetype of R· does not reveal the aforementioned properties. Thus, the fluorinated 1,3,2‐benzodithiazolyls pave a new pathway in the design and synthesis of metal‐less magnetically‐bistable materials.

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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...

Cited by 6 publications

References 40 publications

Room-Temperature Magnetic Bistability in a Salt of Organic Radical Ions

Room-Temperature Magnetic Bistability in a Salt of Organic Radical Ions

Magnetic Bistability in an Organic Radical-Based Charge Transfer Cocrystal

Hysteretic Room‐Temperature Magnetic Bistability of the Crystalline 4,7‐Difluoro‐1,3,2‐Benzodithiazolyl Radical

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