9,9′-BI(XANTHENE)-TYPE HEXAPHENYLETHANE DERIVATIVES AS ADVANCED ORGANIC ELECTROCHROMIC SYSTEMS

9-Phenylxanthenyl radical can undergo facile C-C bond formation at C9-position when the two units of the radical are connected at C2'-positions to give stable intramolecular dimer (1), which is a clamped hexaphenylethane derivative with an elongated C-C bond. The newly formed bond in 1 can be cleaved easily upon two-electron oxidation to give bis(9-xanthenylium)-type dication (2(2+)), from which the diradical is generated upon two-electron reduction. This review account describes the dynamic redox (dyrex) pair of colorless 1 and yellow-orange 2(2+), which provides a versatile scaffold to develop multi-functional electrochromic systems. Both of 1 and 2(2+) are sterically challenged molecules and thus adopt characteristic skewed geometries. Electrochiroptical response was realized by suppressing the chiral inversion of helicity in 1 and axial chirality in 2(2+) whereas redox-induced fluorescence switching was attained by attaching the fluorophore whose emission is quenched by xanthenylium in 2(2+) but not by spiro(xanthene) unit in 1. By the molecular design that allows intramolecular chiral transmission, the spectral changes were also induced by the external stimuli (e.g. heat, pH) other than redox input, which made it possible to construct less well-explored multi-input-multi-output response systems. More advanced functions could be endowed, such as chiral redox memory or reversible O-2-storage, by further modification of the prototype.

Automated summary

9-Phenylxanthenyl radical can easily form C-C bonds at the C9-position and undergo oxidation to give versatile diradical compounds, serving as a scaffold for developing multi-functional electrochromic systems. Both molecules exhibit unique skewed geometries and exhibit electrochiroptical response and redox-induced fluorescence switching for potential applications in advanced technology.