Predictions of hole mobilities in oligoacene organic semiconductors from quantum mechanical calculations

Wei Qiao Deng; William A. Goddard

doi:10.1021/jp0495848

Predictions of hole mobilities in oligoacene organic semiconductors from quantum mechanical calculations

Wei Qiao Deng
, William A. Goddard

California Institute of Technology

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

Abstract

We estimate the hole mobility for oligoacene crystals using quantum mechanics (QM) to calculate the reorganization energy and electron-transfer coupling matrix elements and molecular dynamics (MD) to do the thermal averaging. Using an incoherent transport model we calculate a hole mobility of 6.5 cm ²/(V s) for pentacene crystals at 300 K. This can be compared to recent experimental results of 5 cm ²/(V s). However, we find that an alternative packing into the crystal could lead to a hole mobility of 15.2 cm ²/(V s). This suggests that current materials might still be improved by a factor of ∼3. Such calculations might be useful for finding solid-state structures that would increase the hole mobility for use in high-performance molecular devices.

Original language	English
Pages (from-to)	8614-8621
Number of pages	8
Journal	Journal of Physical Chemistry B
Volume	108
Issue number	25
DOIs	https://doi.org/10.1021/jp0495848
Publication status	Published - 24 Jun 2004
Externally published	Yes

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title = "Predictions of hole mobilities in oligoacene organic semiconductors from quantum mechanical calculations",

abstract = "We estimate the hole mobility for oligoacene crystals using quantum mechanics (QM) to calculate the reorganization energy and electron-transfer coupling matrix elements and molecular dynamics (MD) to do the thermal averaging. Using an incoherent transport model we calculate a hole mobility of 6.5 cm 2/(V s) for pentacene crystals at 300 K. This can be compared to recent experimental results of 5 cm 2/(V s). However, we find that an alternative packing into the crystal could lead to a hole mobility of 15.2 cm 2/(V s). This suggests that current materials might still be improved by a factor of ∼3. Such calculations might be useful for finding solid-state structures that would increase the hole mobility for use in high-performance molecular devices.",

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doi = "10.1021/jp0495848",

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journal = "Journal of Physical Chemistry B",

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T1 - Predictions of hole mobilities in oligoacene organic semiconductors from quantum mechanical calculations

AU - Deng, Wei Qiao

AU - Goddard, William A.

PY - 2004/6/24

Y1 - 2004/6/24

N2 - We estimate the hole mobility for oligoacene crystals using quantum mechanics (QM) to calculate the reorganization energy and electron-transfer coupling matrix elements and molecular dynamics (MD) to do the thermal averaging. Using an incoherent transport model we calculate a hole mobility of 6.5 cm 2/(V s) for pentacene crystals at 300 K. This can be compared to recent experimental results of 5 cm 2/(V s). However, we find that an alternative packing into the crystal could lead to a hole mobility of 15.2 cm 2/(V s). This suggests that current materials might still be improved by a factor of ∼3. Such calculations might be useful for finding solid-state structures that would increase the hole mobility for use in high-performance molecular devices.

AB - We estimate the hole mobility for oligoacene crystals using quantum mechanics (QM) to calculate the reorganization energy and electron-transfer coupling matrix elements and molecular dynamics (MD) to do the thermal averaging. Using an incoherent transport model we calculate a hole mobility of 6.5 cm 2/(V s) for pentacene crystals at 300 K. This can be compared to recent experimental results of 5 cm 2/(V s). However, we find that an alternative packing into the crystal could lead to a hole mobility of 15.2 cm 2/(V s). This suggests that current materials might still be improved by a factor of ∼3. Such calculations might be useful for finding solid-state structures that would increase the hole mobility for use in high-performance molecular devices.

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DO - 10.1021/jp0495848

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JO - Journal of Physical Chemistry B

JF - Journal of Physical Chemistry B

IS - 25

ER -

Predictions of hole mobilities in oligoacene organic semiconductors from quantum mechanical calculations

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