A long-lived charge-separated state of spiro compact electron donor-acceptor dyads based on rhodamine and naphthalenediimide chromophores.

Spiro rhodamine (Rho)-naphthalenediimide (NDI) electron donor-acceptor orthogonal dyads were prepared to generate a long-lived charge separation (CS) state based on the electron spin control approach, to form the CS state, not the CS state, to prolong the CS state lifetime by the electron spin forbidden feature of the charge recombination process of CS → S. The electron donor Rho (lactam form) is attached three σ bonds, including two C-C and one N-N bonds (Rho-NDI), or an intervening phenylene, to the electron acceptor NDI (Rho-Ph-NDI and Rho-PhMe-NDI). Transient absorption (TA) spectra show that fast intersystem crossing (ISC) (<120 fs) occurred to generate an upper triplet state localized on the NDI moiety (NDI*), and then to form the CS state. For Rho-NDI in both non-polar and polar solvents, a long-lived CS state (lifetime = 0.13 μs) and charge separation quantum yield ( ) up to 25% were observed, whereas for Rho-Ph-NDI ( = 1.1 μs) and Rho-PhMe-NDI ( = 2.0 μs), a low-lying NDI* state was formed by charge recombination (CR) in -hexane (HEX). In toluene (TOL), however, CS states were observed for Rho-Ph-NDI (0.37 μs) and Rho-PhMe-NDI (0.63 μs). With electron paramagnetic resonance (EPR) spectra, weak electronic coupling between the Rho and NDI moieties for Rho-NDI was proved. Time-resolved EPR (TREPR) spectra detected two transient species including NDI-localized triplets (formed SOC-ISC) and a CS state. The CS state of Rho-NDI features the largest dipolar interaction (|| = 184 MHz) compared to Rho-Ph-NDI (|| = 39 MHz) and Rho-PhMe-NDI (|| = 41 MHz) due to the smallest distance between Rho and NDI moieties. For Rho-NDI, the time-dependent , → , phase change of the CS state TREPR spectrum indicates that the long-lived CS state is based on the electron spin control effect.