Ultrathin near-infrared transmitting films enabled by deprotonation-induced intramolecular charge transfer of a dopant
Dingfang Hu, Lingya Peng, Wenjun Xu, Shenghui Zhang, Zhongshan Liu, Yu Fang
Abstract
Near-infrared transparent films demonstrate important applications in many fields, but how to eliminate light interference from ultraviolet-visible region and how to tackle the trade-off effect between film thickness and transmittance remain as challenges. Herein, we report a near-infrared transparent film that achieves high-efficient combination of thin thickness (16 μm), suitable cut-off wavelength (890 nm), and ideal transmittance (TNIR > 90%, TVis < 1%). Moreover, the film is photo-chemically stable, heating resistance and moisture insensitive. The key component of the film is a complex of a specially designed boron compound containing a perylene monoimide unit (PMI-CBN) with an organic base 1,8-diazabicyclo[5,4,0]undec-7-ene. The complex depicts red-shifted absorption from 709 to 943 nm owing to deprotonation of the N-H group of PMI-CBN. Dispersion of the complex in polymethyl methacrylate results in the high-performance film. As demos, the film is successfully used for night vision imaging and information encryption. Near-infrared transparent films have a number of applications, but combining elimination of UV-vis light and the balance of film thickness and transmittance is challenging. Here, the authors report the development of a thin material with good transmittance and a suitable wavelength cutoff.