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Abstract

Although polyimides (PIs) have been widely used in various fields such as microelectronics, aerospaces, automobiles and flexible electronics, in most cases, they cannot simultaneously fulfill the requirements such as dielectric properties, thermal stability, thermoplasticity, transparency and so on. As numerous devices are increasingly being operated under extreme conditions, it is highly desirable to endow PIs with outstanding comprehensive performance. Herein, we introduce a solvent engineering approach to address this issue by using formic acid (FA). The poor solvent FA for poly (amic acid) leads to an increased degree of chain entanglements of curled-up polymer chains and loosened chain packing. As a result, PI TFMB-BPDA treated by FA is able to achieve higher T_g of 381°C, lower CTE of 23 ppm K⁻¹, higher T_400–800 of 76.7% as well as better mechanical performance than PI TFMB-BPDA with T_g of 362°C, CTE of 38 ppm K⁻¹ and T_400–800 of 70.8%. However, this strategy exhibits varying effectiveness for different kinds of PIs. By comparing the cases of two kinds of PIs, it is found that CTE is not only related to dense chain packing but also the aggregation structure of PIs.

Keywords

polyimide solvent engineering formic acid thermal stability transparency

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Enhancement in thermal stability and transparency enabled by solvent engineering via formic acid

Abstract

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