Explaining the temperature dependence of Spirilloxanthin's S* signal by an inhomogeneous ground state model

J. Hauer; M. Maiuri; D. Viola; V. Lukes; S. Henry; A. M. Carey; R. J. Cogdell; G. Cerullo; D. Polli

doi:10.1021/jp4011372

Explaining the temperature dependence of Spirilloxanthin's S* signal by an inhomogeneous ground state model

J. Hauer, M. Maiuri, D. Viola, V. Lukes, S. Henry, A. M. Carey, R. J. Cogdell, G. Cerullo, D. Polli

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20 Scopus citations

Abstract

We investigate the nature of the S* excited state in carotenoids by performing a series of pump-probe experiments with sub-20 fs time resolution on spirilloxanthin in a polymethyl-methacrylate matrix varying the sample temperature. Following photoexcitation, we observe sub-200 fs internal conversion of the bright S₂ state into the lower-lying S₁ and S* states, which in turn relax to the ground state on a picosecond time scale. Upon cooling down the sample to 77 K, we observe a systematic decrease of the S*/S₁ ratio. This result can be explained by assuming two thermally populated ground state isomers. The higher lying one generates the S* state, which can then be effectively frozen out by cooling. These findings are supported by quantum chemical modeling and provide strong evidence for the existence and importance of ground state isomers in the photophysics of carotenoids.

Original language	English
Pages (from-to)	6303-6310
Number of pages	8
Journal	Journal of Physical Chemistry A
Volume	117
Issue number	29
DOIs	https://doi.org/10.1021/jp4011372
State	Published - 25 Jul 2013
Externally published	Yes

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title = "Explaining the temperature dependence of Spirilloxanthin's S* signal by an inhomogeneous ground state model",

abstract = "We investigate the nature of the S* excited state in carotenoids by performing a series of pump-probe experiments with sub-20 fs time resolution on spirilloxanthin in a polymethyl-methacrylate matrix varying the sample temperature. Following photoexcitation, we observe sub-200 fs internal conversion of the bright S2 state into the lower-lying S1 and S* states, which in turn relax to the ground state on a picosecond time scale. Upon cooling down the sample to 77 K, we observe a systematic decrease of the S*/S1 ratio. This result can be explained by assuming two thermally populated ground state isomers. The higher lying one generates the S* state, which can then be effectively frozen out by cooling. These findings are supported by quantum chemical modeling and provide strong evidence for the existence and importance of ground state isomers in the photophysics of carotenoids.",

author = "J. Hauer and M. Maiuri and D. Viola and V. Lukes and S. Henry and Carey, {A. M.} and Cogdell, {R. J.} and G. Cerullo and D. Polli",

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day = "25",

doi = "10.1021/jp4011372",

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TY - JOUR

T1 - Explaining the temperature dependence of Spirilloxanthin's S* signal by an inhomogeneous ground state model

AU - Hauer, J.

AU - Maiuri, M.

AU - Viola, D.

AU - Lukes, V.

AU - Henry, S.

AU - Carey, A. M.

AU - Cogdell, R. J.

AU - Cerullo, G.

AU - Polli, D.

PY - 2013/7/25

Y1 - 2013/7/25

N2 - We investigate the nature of the S* excited state in carotenoids by performing a series of pump-probe experiments with sub-20 fs time resolution on spirilloxanthin in a polymethyl-methacrylate matrix varying the sample temperature. Following photoexcitation, we observe sub-200 fs internal conversion of the bright S2 state into the lower-lying S1 and S* states, which in turn relax to the ground state on a picosecond time scale. Upon cooling down the sample to 77 K, we observe a systematic decrease of the S*/S1 ratio. This result can be explained by assuming two thermally populated ground state isomers. The higher lying one generates the S* state, which can then be effectively frozen out by cooling. These findings are supported by quantum chemical modeling and provide strong evidence for the existence and importance of ground state isomers in the photophysics of carotenoids.

AB - We investigate the nature of the S* excited state in carotenoids by performing a series of pump-probe experiments with sub-20 fs time resolution on spirilloxanthin in a polymethyl-methacrylate matrix varying the sample temperature. Following photoexcitation, we observe sub-200 fs internal conversion of the bright S2 state into the lower-lying S1 and S* states, which in turn relax to the ground state on a picosecond time scale. Upon cooling down the sample to 77 K, we observe a systematic decrease of the S*/S1 ratio. This result can be explained by assuming two thermally populated ground state isomers. The higher lying one generates the S* state, which can then be effectively frozen out by cooling. These findings are supported by quantum chemical modeling and provide strong evidence for the existence and importance of ground state isomers in the photophysics of carotenoids.

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JO - Journal of Physical Chemistry A

JF - Journal of Physical Chemistry A

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ER -

Explaining the temperature dependence of Spirilloxanthin's S* signal by an inhomogeneous ground state model

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