Organic semiconductors and flexible electronic technology are the carriers with great potential for the future information industry and intelligent manufacturing. Academician Huang Wei of the Chinese Academy of Sciences and Prof. Xie Linghai from the Institute of Information Materials and Nanotechnology at Nanjing University of Posts and Telecommunications, recently borrowed from China's square culture and ancient pane structure, broke through the new concept of polymer and synthesized organic nanopolymers to achieve central symmetry The three-dimensional selective lattice and poly lattice of molecular arrangement. The international top journal "Nature · Newsletter" published the results online. Flexible electronic technology, especially organic electronic technology still faces huge challenges in organic display, organic laser, organic photovoltaic, organic field effect transistor, sensing and execution, information storage and memristance calculation. At present, only organic light-emitting diodes have achieved large-scale commercialization, and they are also facing fierce competition from emerging materials such as quantum dots, perovskite and two-dimensional nanometers. In recent years, the team led by Huang Wei and Xie Linghai proposed the concept of organic nanopolymers in response to the limitations of polymers, and pioneered the new research direction of polyorganic organic nanopolymers. The development of synthetic strategies from the perspective of innovative structures is the key to starting this direction. "In this study, the A2B2 type synthesizer we designed not only overcomes the cross-linking problem, but also effectively controls the stereoregularity of the nanopolymer." Xie Linghai Introduced, they borrowed the hand-painted hand created by Dutch printmaker Moritz Cornelis Escher in 1948 to name this type of nanopolymer, that is, hand-painted hand poly lattice, showing the organic nanopolymer Key features. Huang Wei said that organic nano-polymer semiconductors will provide new solutions for plastic electronics, which will affect a new generation of organic wide band gap semiconductor materials, electric pump lasers, flexible electronic devices, printed display technology and information storage and neuromorphic computing technologies development of.
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Chinese scientists synthesize organic nanopolymers will affect flexible electronic technology