Controlling Fluorination Density of Soluble Polyimide Gate Dielectrics and its Influence on Organic Crystal Growth and Device Operational Stability

• Published in: ACS applied materials & interfaces Vol. 16; no. 18; pp. 24010 - 24020
• Main Authors: Yoon, Tae Woong, Park, Hyunjin, Lee, Jaehoon, Yoo, Sungmi, Kim, Yun Ho, Weon, Byung Mook, Kim, Junki, Kim, Young Yong, Kang, Boseok
• Format: Journal Article
• Language: English
• Published: United States American Chemical Society 26.04.2024
• Subjects: Surfaces, Interfaces, and Applications; organic thin film transistor; crystal growth; organic semiconductor; fluorinated polyimide; charge trapping
• ISSN: 1944-8244; 1944-8252
• DOI: 10.1021/acsami.4c01767

Fluorinated polyimides (PIs) are among the most promising candidates for gate dielectric materials in organic electronic devices because of their solution processability and outstanding chemical, mechanical, and thermal stabilities. Additionally, fluorine (F) substitution improves the electrical properties of PI thin films, such as enhanced dielectric properties and reduced surface trap densities. However, the relationship between the fluorination density of PIs and crystal growth modes of vacuum-deposited conjugated molecules on PI thin films, which is directly related to the lateral charge transport along the PI–organic semiconductor interface, has not been systematically studied. Herein, five different soluble PIs with different F densities were synthesized, and the correlation between fluorination and thin-film properties was systematically investigated. Not only were their dielectric properties modulated, but the growth modes of the organic molecules deposited on the PI thin films also changed with increasing surface F density. This phenomenon was observed by both surface and crystallographic analyses, which resulted in extremely high operational stability of field-effect transistors and the successful fabrication of organic complementary circuits. We believe that the correlation between PI backbone fluorination and its thin-film properties will provide practical insights into the material design based on controlled molecular directed surface assembly on fluorinated polymer dielectrics.