Our scholars synthesize organic nanopolymers, what will be the impact on flexible electronics?

In recent years, a team led by our scholars has proposed the concept of organic nanopolymers in response to the problem of the limitations of polymers, and has opened up the new subject of organic nanopolymers. When the synthesis of organic nanopolymers, organic nanopolymer semiconductors will provide a new program for plastic electronics, which will affect the new generation of organic wide bandgap semiconductor materials, flexible electronic devices, electrically pumped lasers, printed display technology, and information storage and neuromorphic computing and other technologies and other developments. Want to know our scholars synthesize organic nanopolymers, the impact on flexible electronics technology, we first need to understand what is organic nanopolymers and flexible electronics technology these two concepts. Organic nanopolymers are organic nanomonomers as, repeat unit by *** valence nano-connections and become a class of polymers. This kind of molecular skeleton structure can take into account the carbon nano-like inorganic photoelectric properties and polymer solution can be processed advantage. Flexible electronics is a technology commonly known as organic or inorganic materials, electronic devices made in the flexible ductile substrate of the emerging electronic technology. Compared with traditional electronics, flexible electronics is more flexible, can adapt to different working environments to a certain extent, to meet the deformation needs of a variety of devices. However, today's technical requirements also limit the development of flexible electronics. Flexible electronics technology, especially organic electronics technology in organic display, organic photovoltaics, organic field effect transistors, organic lasers, sensing and execution, information storage and amnesia computing and other aspects are still facing huge challenges. Currently, only organic light-emitting diodes have been commercialized, while still facing fierce competition from a variety of new materials such as quantum dots, chalcogenide and two-dimensional nano.

Developing synthesis strategies from an innovative structural point of view is a key direction to open up the post impact. In our synthesis studies, we designed A2B2-type synthesizers that not only overcome the cross-linking problem, but also effectively control the cubic regularity of the nanopolymers.

Flexible electrons will show stretching and bending without damaging their own electronic properties, which will pose new challenges and more requirements for circuit fabrication materials.