Fluoropolymer-diluted small molecule organic semiconductors with extreme thermal stability

Jared S. Price; Baomin Wang; Taehwan Kim; Alex J. Grede; Jesse M. Sandoval; Renxuan Xie; Yufei Shen; DIllon R. Adams; Michael J. Eller; Anatoliy Sokolov; Sukrit Mukhopadhyay; Peter Trefonas; Enrique D. Gomez; Emile A. Schweikert; Noel C. Giebink

doi:10.1063/1.5053923

Fluoropolymer-diluted small molecule organic semiconductors with extreme thermal stability

Jared S. Price, Baomin Wang, Taehwan Kim, Alex J. Grede, Jesse M. Sandoval, Renxuan Xie, Yufei Shen, DIllon R. Adams, Michael J. Eller, Anatoliy Sokolov, Sukrit Mukhopadhyay, Peter Trefonas, Enrique D. Gomez, Emile A. Schweikert, Noel C. Giebink

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

Thermal stability is important for many thin film organic semiconductor devices but is challenging due to their weakly Van der Waals-bonded nature. Here, we show that diluting common small molecule hole transport materials through co-evaporation with the amorphous fluoropolymer Teflon AF leads to a dramatic improvement in their thermal and morphological stability without sacrificing electrical performance. Blend films with 25 vol. % Teflon decrease the drive voltage of single layer hole-only devices by more than 30% and dramatically increase their operating temperature limit to over 250 °C. The stability improvement appears to result from a nanoscale network of Teflon chains that repolymerize throughout the blend film following evaporation and inhibit gross movement of the organic semiconductor molecules. These results open up a pathway to stabilize the morphology of small molecule organic semiconductors and point to a more general opportunity to exploit semiconductor dilution to systematically vary thermal, optical, and other material properties without compromising electrical transport.

Original language	English (US)
Article number	263302
Journal	Applied Physics Letters
Volume	113
Issue number	26
DOIs	https://doi.org/10.1063/1.5053923
State	Published - Dec 24 2018
Externally published	Yes

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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Price, J. S., Wang, B., Kim, T., Grede, A. J., Sandoval, J. M., Xie, R., Shen, Y., Adams, DI. R., Eller, M. J., Sokolov, A., Mukhopadhyay, S., Trefonas, P., Gomez, E. D., Schweikert, E. A., & Giebink, N. C. (2018). Fluoropolymer-diluted small molecule organic semiconductors with extreme thermal stability. Applied Physics Letters, 113(26), Article 263302. https://doi.org/10.1063/1.5053923

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abstract = "Thermal stability is important for many thin film organic semiconductor devices but is challenging due to their weakly Van der Waals-bonded nature. Here, we show that diluting common small molecule hole transport materials through co-evaporation with the amorphous fluoropolymer Teflon AF leads to a dramatic improvement in their thermal and morphological stability without sacrificing electrical performance. Blend films with 25 vol. % Teflon decrease the drive voltage of single layer hole-only devices by more than 30% and dramatically increase their operating temperature limit to over 250 °C. The stability improvement appears to result from a nanoscale network of Teflon chains that repolymerize throughout the blend film following evaporation and inhibit gross movement of the organic semiconductor molecules. These results open up a pathway to stabilize the morphology of small molecule organic semiconductors and point to a more general opportunity to exploit semiconductor dilution to systematically vary thermal, optical, and other material properties without compromising electrical transport.",

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AU - Price, Jared S.

AU - Wang, Baomin

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AU - Grede, Alex J.

AU - Sandoval, Jesse M.

AU - Xie, Renxuan

AU - Shen, Yufei

AU - Adams, DIllon R.

AU - Eller, Michael J.

AU - Sokolov, Anatoliy

AU - Mukhopadhyay, Sukrit

AU - Trefonas, Peter

AU - Gomez, Enrique D.

AU - Schweikert, Emile A.

AU - Giebink, Noel C.

PY - 2018/12/24

Y1 - 2018/12/24

N2 - Thermal stability is important for many thin film organic semiconductor devices but is challenging due to their weakly Van der Waals-bonded nature. Here, we show that diluting common small molecule hole transport materials through co-evaporation with the amorphous fluoropolymer Teflon AF leads to a dramatic improvement in their thermal and morphological stability without sacrificing electrical performance. Blend films with 25 vol. % Teflon decrease the drive voltage of single layer hole-only devices by more than 30% and dramatically increase their operating temperature limit to over 250 °C. The stability improvement appears to result from a nanoscale network of Teflon chains that repolymerize throughout the blend film following evaporation and inhibit gross movement of the organic semiconductor molecules. These results open up a pathway to stabilize the morphology of small molecule organic semiconductors and point to a more general opportunity to exploit semiconductor dilution to systematically vary thermal, optical, and other material properties without compromising electrical transport.

AB - Thermal stability is important for many thin film organic semiconductor devices but is challenging due to their weakly Van der Waals-bonded nature. Here, we show that diluting common small molecule hole transport materials through co-evaporation with the amorphous fluoropolymer Teflon AF leads to a dramatic improvement in their thermal and morphological stability without sacrificing electrical performance. Blend films with 25 vol. % Teflon decrease the drive voltage of single layer hole-only devices by more than 30% and dramatically increase their operating temperature limit to over 250 °C. The stability improvement appears to result from a nanoscale network of Teflon chains that repolymerize throughout the blend film following evaporation and inhibit gross movement of the organic semiconductor molecules. These results open up a pathway to stabilize the morphology of small molecule organic semiconductors and point to a more general opportunity to exploit semiconductor dilution to systematically vary thermal, optical, and other material properties without compromising electrical transport.

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Fluoropolymer-diluted small molecule organic semiconductors with extreme thermal stability

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