Electronic Structure and Triplet–Triplet Energy Transfer in Artificial Photosynthetic Antennas

Marely E. Tejeda-Ferrari; Chelsea L. Brown; Gabriela C.C.C. Coutinho; Ghabriel A. Gomes de Sá; Julio L. Palma; Manuel J. Llansola-Portoles; Gerdenis Kodis; Vladimiro Mujica; Junming Ho; Devens Gust; Thomas Moore; Ana Moore

doi:10.1111/php.12979

Electronic Structure and Triplet–Triplet Energy Transfer in Artificial Photosynthetic Antennas

Marely E. Tejeda-Ferrari, Chelsea L. Brown, Gabriela C.C.C. Coutinho, Ghabriel A. Gomes de Sá, Julio L. Palma, Manuel J. Llansola-Portoles, Gerdenis Kodis, Vladimiro Mujica, Junming Ho, Devens Gust, Thomas Moore, Ana Moore

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

6 Scopus citations

Abstract

Three Pd(II) phthalocyanine–carotenoid dyads featuring chromophores linked by amide bonds were prepared in order to investigate the rate of triplet–triplet (T-T) energy transfer from the tetrapyrrole to the covalently attached carotenoid as a function of the number of conjugated double bonds in the carotenoid. Carotenoids having 9, 10 and 11 conjugated double bonds were studied. Transient absorption measurements show that intersystem crossing in the Pd(II) phthalocyanine takes place in 10 ps in each case and that T-T energy transfer occurs in 126, 81 and 132 ps in the dyads bearing 9, 10 and 11 double bond carotenoids, respectively. To identify the origin of this variation in T-T energy transfer rates, density functional theory (DFT) was used to calculate the T-T electronic coupling in the three dyads. According to the calculations, the primary reason for the observed T-T energy transfer trend is larger T-T electronic coupling between the tetrapyrrole and the 10-double bond carotenoid. A methyl group adjacent to the amide linker that connects the Pd(II) phthalocyanine and the carotenoid in the 9 and 11-double bond carotenoids is absent in the 10-double bond carotenoid, and this difference alters its electronic structure to increase the coupling.

Original language	English (US)
Pages (from-to)	211-219
Number of pages	9
Journal	Photochemistry and photobiology
Volume	95
Issue number	1
DOIs	https://doi.org/10.1111/php.12979
State	Published - Jan 1 2019

ASJC Scopus subject areas

Radiation
Biochemistry
Physical and Theoretical Chemistry

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Tejeda-Ferrari, M. E., Brown, C. L., Coutinho, G. C. C. C., Gomes de Sá, G. A., Palma, J. L., Llansola-Portoles, M. J., Kodis, G., Mujica, V., Ho, J., Gust, D., Moore, T., & Moore, A. (2019). Electronic Structure and Triplet–Triplet Energy Transfer in Artificial Photosynthetic Antennas. Photochemistry and photobiology, 95(1), 211-219. https://doi.org/10.1111/php.12979

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title = "Electronic Structure and Triplet–Triplet Energy Transfer in Artificial Photosynthetic Antennas",

abstract = "Three Pd(II) phthalocyanine–carotenoid dyads featuring chromophores linked by amide bonds were prepared in order to investigate the rate of triplet–triplet (T-T) energy transfer from the tetrapyrrole to the covalently attached carotenoid as a function of the number of conjugated double bonds in the carotenoid. Carotenoids having 9, 10 and 11 conjugated double bonds were studied. Transient absorption measurements show that intersystem crossing in the Pd(II) phthalocyanine takes place in 10 ps in each case and that T-T energy transfer occurs in 126, 81 and 132 ps in the dyads bearing 9, 10 and 11 double bond carotenoids, respectively. To identify the origin of this variation in T-T energy transfer rates, density functional theory (DFT) was used to calculate the T-T electronic coupling in the three dyads. According to the calculations, the primary reason for the observed T-T energy transfer trend is larger T-T electronic coupling between the tetrapyrrole and the 10-double bond carotenoid. A methyl group adjacent to the amide linker that connects the Pd(II) phthalocyanine and the carotenoid in the 9 and 11-double bond carotenoids is absent in the 10-double bond carotenoid, and this difference alters its electronic structure to increase the coupling.",

author = "Tejeda-Ferrari, {Marely E.} and Brown, {Chelsea L.} and Coutinho, {Gabriela C.C.C.} and {Gomes de S{\'a}}, {Ghabriel A.} and Palma, {Julio L.} and Llansola-Portoles, {Manuel J.} and Gerdenis Kodis and Vladimiro Mujica and Junming Ho and Devens Gust and Thomas Moore and Ana Moore",

note = "Funding Information: This research was supported by the US Department of Energy, Office of Science, Office of Basic Energy Sciences, under Award DE-FG02-03ER15393. JH acknowledges the Australian Research Council for financial support (Grant No. DE160100807) and the Australian NCI and Intersect Australia Ltd for generous allocation of computational resources. Funding Information: Acknowledgements—This research was supported by the US Department of Energy, Office of Science, Office of Basic Energy Sciences, under Award DE-FG02-03ER15393. JH acknowledges the Australian Research Council for financial support (Grant No. DE160100807) and the Australian NCI and Intersect Australia Ltd for generous allocation of computational resources. Publisher Copyright: {\textcopyright} 2018 The American Society of Photobiology",

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doi = "10.1111/php.12979",

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AU - Tejeda-Ferrari, Marely E.

AU - Brown, Chelsea L.

AU - Coutinho, Gabriela C.C.C.

AU - Gomes de Sá, Ghabriel A.

AU - Palma, Julio L.

AU - Llansola-Portoles, Manuel J.

AU - Kodis, Gerdenis

AU - Mujica, Vladimiro

AU - Ho, Junming

AU - Gust, Devens

AU - Moore, Thomas

AU - Moore, Ana

N1 - Funding Information: This research was supported by the US Department of Energy, Office of Science, Office of Basic Energy Sciences, under Award DE-FG02-03ER15393. JH acknowledges the Australian Research Council for financial support (Grant No. DE160100807) and the Australian NCI and Intersect Australia Ltd for generous allocation of computational resources. Funding Information: Acknowledgements—This research was supported by the US Department of Energy, Office of Science, Office of Basic Energy Sciences, under Award DE-FG02-03ER15393. JH acknowledges the Australian Research Council for financial support (Grant No. DE160100807) and the Australian NCI and Intersect Australia Ltd for generous allocation of computational resources. Publisher Copyright: © 2018 The American Society of Photobiology

PY - 2019/1/1

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N2 - Three Pd(II) phthalocyanine–carotenoid dyads featuring chromophores linked by amide bonds were prepared in order to investigate the rate of triplet–triplet (T-T) energy transfer from the tetrapyrrole to the covalently attached carotenoid as a function of the number of conjugated double bonds in the carotenoid. Carotenoids having 9, 10 and 11 conjugated double bonds were studied. Transient absorption measurements show that intersystem crossing in the Pd(II) phthalocyanine takes place in 10 ps in each case and that T-T energy transfer occurs in 126, 81 and 132 ps in the dyads bearing 9, 10 and 11 double bond carotenoids, respectively. To identify the origin of this variation in T-T energy transfer rates, density functional theory (DFT) was used to calculate the T-T electronic coupling in the three dyads. According to the calculations, the primary reason for the observed T-T energy transfer trend is larger T-T electronic coupling between the tetrapyrrole and the 10-double bond carotenoid. A methyl group adjacent to the amide linker that connects the Pd(II) phthalocyanine and the carotenoid in the 9 and 11-double bond carotenoids is absent in the 10-double bond carotenoid, and this difference alters its electronic structure to increase the coupling.

AB - Three Pd(II) phthalocyanine–carotenoid dyads featuring chromophores linked by amide bonds were prepared in order to investigate the rate of triplet–triplet (T-T) energy transfer from the tetrapyrrole to the covalently attached carotenoid as a function of the number of conjugated double bonds in the carotenoid. Carotenoids having 9, 10 and 11 conjugated double bonds were studied. Transient absorption measurements show that intersystem crossing in the Pd(II) phthalocyanine takes place in 10 ps in each case and that T-T energy transfer occurs in 126, 81 and 132 ps in the dyads bearing 9, 10 and 11 double bond carotenoids, respectively. To identify the origin of this variation in T-T energy transfer rates, density functional theory (DFT) was used to calculate the T-T electronic coupling in the three dyads. According to the calculations, the primary reason for the observed T-T energy transfer trend is larger T-T electronic coupling between the tetrapyrrole and the 10-double bond carotenoid. A methyl group adjacent to the amide linker that connects the Pd(II) phthalocyanine and the carotenoid in the 9 and 11-double bond carotenoids is absent in the 10-double bond carotenoid, and this difference alters its electronic structure to increase the coupling.

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Electronic Structure and Triplet–Triplet Energy Transfer in Artificial Photosynthetic Antennas

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