Your search keyword '"bias-stress effects"' showing total 2 results

1. Improving OFF-State Bias-Stress Stability in High-Mobility Conjugated Polymer Transistors with an Antisolvent Treatment

Author

Nguyen, Malgorzata, Kraft, Ulrike, Tan, Wen Liang, Dobryden, Illia, Broch, Katharina, Zhang, Weimin, Un, Hio-Ieng, Simatos, Dimitrios, Venkateshavaran, Deepak, McCulloch, Iain, Claesson, Per M, McNeill, Christopher R, Sirringhaus, Henning, Sirringhaus, Henning [0000-0001-9827-6061], and Apollo - University of Cambridge Repository

Subjects

solvent treatments, electron trapping, stability, solvent treatment, bias-stress effects, organic field-effect transistors

Abstract

Conjugated polymer field-effect transistors are emerging as an enabling technology for flexible electronics due to their excellent mechanical properties combined with sufficiently high charge carrier mobilities and compatibility with large-area, low-temperature processing. However, their electrical stability remains a concern. ON-state (accumulation mode) bias-stress instabilities in organic semiconductors have been widely studied, and multiple mitigation strategies have been suggested. In contrast, OFF-state (depletion mode) bias-stress instabilities remain poorly understood despite being crucial for many applications in which the transistors are held in their OFF-state for most of the time. Here, we present a simple method of using an anti-solvent treatment to achieve significant improvements in OFF-state bias-stress and environmental stability as well as general device performance for one of the best performing polymers, solution-processable indacenodithiophene-co-benzothiadiazole (IDT-BT). IDT-BT is weakly crystalline, and we attribute the notable improvements to an anti-solvent-induced, increased degree of crystallinity, resulting in a lower probability of electron trapping and the removal of charge traps. Our work highlights the importance of the microstructure in weakly crystalline polymer films and offers a simple processing strategy for achieving the reliability required for applications in flexible electronics. This article is protected by copyright. All rights reserved.

Published

2023

2. Improving OFF-State Bias-Stress Stability in High-Mobility Conjugated Polymer Transistors with an Anti-Solvent Treatment

Author

Malgorzata Nguyen, Ulrike Kraft, Wen Liang Tan, Illia Dobryden, Katharina Broch, Weimin Zhang, Hio‐Ieng Un, Dimitrios Simatos, Deepak Venkateshavaran, Iain McCulloch, Per M. Claesson, Christopher R. McNeill, and Henning Sirringhaus

Subjects

solvent treatments, electron trapping, Mechanics of Materials, Mechanical Engineering, General Materials Science, stability, Condensed Matter Physics, bias-stress effects, Den kondenserade materiens fysik, organic field-effect transistors

Abstract

Conjugated polymer field-effect transistors are emerging as an enabling technology for flexible electronics due to their excellent mechanical properties combined with sufficiently high charge carrier mobilities and compatibility with large-area, low-temperature processing. However, their electrical stability remains a concern. ON-state (accumulation mode) bias-stress instabilities in organic semiconductors have been widely studied, and multiple mitigation strategies have been suggested. In contrast, OFF-state (depletion mode) bias-stress instabilities remain poorly understood despite being crucial for many applications in which the transistors are held in their OFF-state for most of the time. Here, we present a simple method of using an anti-solvent treatment to achieve significant improvements in OFF-state bias-stress and environmental stability as well as general device performance for one of the best performing polymers, solution-processable indacenodithiophene-co-benzothiadiazole (IDT-BT). IDT-BT is weakly crystalline, and we attribute the notable improvements to an anti-solvent-induced, increased degree of crystallinity, resulting in a lower probability of electron trapping and the removal of charge traps. Our work highlights the importance of the microstructure in weakly crystalline polymer films and offers a simple processing strategy for achieving the reliability required for applications in flexible electronics. Validerad;2023;Nivå 2;2023-07-05 (hanlid);Funder: Engineering and Physical Sciences Research Council (EP/R031894/1); EPSRC Centre for Doctoral Training (EP/L015889/1); EPSRC (EP/S030662/1)

Published

2022