Near-Infrared, Organic Chiroptic Switch with High Dissymmetry Factors
Si Tong Bao, Shayan Louie, Haoyu Jiang, Qifeng Jiang, Shantao Sun, Michael L. Steigerwald, Colin Nuckolls, Zexin Jin
Abstract
Here we unveil a chiral molecular redox switch derived from PDI-based twistacenes─ c hPDI[2] that has the remarkable attributes of high-intensity and a broadband chiral response. This material exhibits facile, stable, and reversible multistate chiroptical switching behavior over a broad active wavelength range close to 700 nm, encompassing ultraviolet, visible, and near-infrared regions. Upon reduction, c hPDI[2] exhibits a substantial increase in the amplitude of its circular dichroic response, with an outstanding |ΔΔε| > 300 M –1 cm –1 and a high dissymmetry factor of 3 × 10 –2 at 960 nm. DFT calculations suggest that the long wavelength CD signal for doubly reduced c hPDI[2] originates from excitation of the PDI backbone to the π* orbital of the bridging alkene. Importantly, the dimer’s molecular contortion facilitates ionic diffusion, enabling chiral switching in solid state films. The high dissymmetry factors and near-infrared response establish c hPDI[2] as a unique chiroptic switch.