Sheng‐Ning Hsu scite author profile

Triplet ground-state organic molecules are of interest with respect to several emerging technologies but usually show limited stability, especially as thin films. We report an organic diradical, consisting of two Blatter radicals, that possesses a triplet ground state with a singlet−triplet energy gap, ΔE ST ≈ 0.4−0.5 kcal mol −1 (2J/k ≈ 220−275 K). The diradical possesses robust thermal stability, with an onset of decomposition above 264 °C (TGA). In toluene/chloroform, glassy matrix, and fluid solution, an equilibrium between two conformations with ΔE ST ≈ 0.4 kcal mol −1 and ΔE ST ≈ −0.7 kcal mol −1 is observed, favoring the triplet ground state over the singlet ground-state conformation in the 110−330 K temperature range. The diradical with the triplet ground-state conformation is found exclusively in crystals and in a polystyrene matrix. The crystalline neutral diradical is a good electrical conductor with conductivity comparable to the thoroughly optimized bis(thiazolyl)-related monoradicals. This is surprising because the triplet ground state implies that the underlying π-system is cross-conjugated and thus is not compatible with either good conductance or electron delocalization. The diradical is evaporated under ultra-high vacuum to form thin films, which are stable in air for at least 18 h, as demonstrated by X-ray photoelectron and electron paramagnetic resonance (EPR) spectroscopies.

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Electronic and Spintronic Open-Shell Macromolecules,Quo Vadis?

Tan

Hsu

Tahir

et al. 2022

J. Am. Chem. Soc.

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Open-shell macromolecules (i.e., polymers containing radical sites either along their backbones or at the pendant sites of repeat units) have attracted significant attention owing to their intriguing chemical and physical (e.g., redox, optoelectronic, and magnetic) properties, and they have been proposed and/or implemented in a wide range of potential applications (e.g., energy storage devices, electronic systems, and spintronic modules). These successes span multiple disciplines that range from advanced macromolecular chemistry through nanoscale structural characterization and on to next-generation solid-state physics and the associated devices. In turn, this has allowed different scientific communities to expand the palette of radical-containing polymers relatively quickly. However, critical gaps remain on many fronts, especially regarding the elucidation of key structure−property− function relationships that govern the underlying electrochemical, optoelectronic, and spin phenomena in these materials systems. Here, we highlight vital developments in the history of open-shell macromolecules to explain the current state of the art in the field. Moreover, we provide a critical review of the successes and bring forward open opportunities that, if solved, could propel this class of materials in a meaningful manner. Finally, we provide an outlook to address where it seems most likely that open-shell macromolecules will go in the coming years. Our considered view is that the future of radical-containing polymers is extremely bright and the addition of talented researchers with diverse skills to the field will allow these materials and their end-use devices to have a positive impact on the global science and technology enterprise in a relatively rapid manner.

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Two-dimensional halide perovskites featuring semiconducting organic building blocks

Gao

Wei

Hsu

et al. 2020

Mater. Chem. Front.

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Sheng‐Ning Hsu

High-Spin (S = 1) Blatter-Based Diradical with Robust Stability and Electrical Conductivity

Electronic and Spintronic Open-Shell Macromolecules,Quo Vadis?

Two-dimensional halide perovskites featuring semiconducting organic building blocks

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