Your search keyword '"Gruber, Elisabeth"' showing total 4 results

1. Color tuning of chlorophyll a and b pigments revealed from gas-phase spectroscopy.

Author

Kjær C, Gruber E, Nielsen SB, and Andersen LH

Subjects

Color, Formates chemistry, Quaternary Ammonium Compounds chemistry, Spectrum Analysis methods, Chlorophyll chemistry, Chlorophyll A chemistry

Abstract

Chlorophyll (Chl) pigments are responsible for vital mechanisms in photosynthetic proteins: light harvesting, energy transfer and charge separation. A complex interplay between the Chl molecule and its microenvironment determines its transition energy. Interactions such as excitonic coupling with one or more pigments (Chls or carotenoids), axial ligation to the magnesium center, or electrostatic interactions between Chl and nearby amino-acid residues all influence the photophysical properties. Here we use time-resolved photodissociation action spectroscopy to determine transition energies of Chla/b complexes in vacuo to directly compare the impact of a negatively charged axial ligand (formate) to that of exciton coupling between two Chls. Experiments carried out at the electrostatic ion storage ring ELISA allow dissociation to be sampled on hundreds of milliseconds time scale. Absorption-band maxima of Chla-formate complexes are found at 433 ± 4 nm/2.86 ± 0.03 eV (Soret band) and in the region 654-675 nm/1.84-1.90 eV (Q band) and those of Chla dimers tagged by a quaternary ammonium ion at 419 ± 5 nm/2.96 ± 0.04 eV (Soret band) and 647 nm/1.92 eV (Q band). The axial ligand strongly affects the Chla transition energies causing redshifts of 0.21 eV of the Soret band and 0.04-0.1 eV of the Q band compared to Chla tagged by a quaternary ammonium. Slightly smaller shifts were found in case of Chlb. The redshifts are approximately twice that induced by excitonic coupling between two Chlas, also tagged by a quaternary ammonium ion. Axial ligation brings the absorption by isolated Chls very close to that of photosynthetic proteins.

Published

2020

2. Intrinsic Photophysics of Light-harvesting Charge-tagged Chlorophyll a and b Pigments.

Author

Gruber E, Kjaer C, Nielsen SB, and Andersen LH

Subjects

Energy Transfer, Light-Harvesting Protein Complexes chemistry, Photosynthesis, Plants metabolism, Quantum Theory, Spectrophotometry, Chlorophyll chemistry, Chlorophyll A chemistry

Abstract

Chlorophylls a and b (Chla/b) are responsible for light-harvesting by photosynthetic proteins in plants. They display broad absorption in the visible region with multiple bands, due to the asymmetry of the macrocycle and strong vibronic coupling. Their photophysics relies on the microenvironment, with regard to transition energies as well as quenching of triplet states. Here, we firmly establish the splitting of the Q and Soret bands into x- and y- polarized bands for the isolated molecules in vacuo, and resolve vibronic features. Storage-ring experiments reveal that dissociation of photoexcited charge-tagged complexes occurs over several milliseconds, but with two different time constants. A fast decay is ascribed to dissociation after internal conversion and a slow decay to the population of a triplet state that acts as a bottleneck. Support for the latter is provided by pump-probe experiments, where a second laser pulse probes the long-lived triplet state., (© 2019 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

3. Intrinsic Photophysics of Light‐harvesting Charge‐tagged Chlorophyll a and b Pigments.

Author

Gruber, Elisabeth, Kjær, Christina, Nielsen, Steen Brøndsted, and Andersen, Lars H.

Subjects

*PLANT pigments, *VIBRONIC coupling, *LASER pulses, *PLANT proteins, *PIGMENTS, *CHLOROPHYLL

Abstract

Chlorophylls a and b (Chla/b) are responsible for light‐harvesting by photosynthetic proteins in plants. They display broad absorption in the visible region with multiple bands, due to the asymmetry of the macrocycle and strong vibronic coupling. Their photophysics relies on the microenvironment, with regard to transition energies as well as quenching of triplet states. Here, we firmly establish the splitting of the Q and Soret bands into x‐ and y‐ polarized bands for the isolated molecules in vacuo, and resolve vibronic features. Storage‐ring experiments reveal that dissociation of photoexcited charge‐tagged complexes occurs over several milliseconds, but with two different time constants. A fast decay is ascribed to dissociation after internal conversion and a slow decay to the population of a triplet state that acts as a bottleneck. Support for the latter is provided by pump‐probe experiments, where a second laser pulse probes the long‐lived triplet state. [ABSTRACT FROM AUTHOR]

Published

2019

4. Frontispiece: Intrinsic Photophysics of Light‐harvesting Charge‐tagged Chlorophyll a and b Pigments.

Author

Gruber, Elisabeth, Kjær, Christina, Nielsen, Steen Brøndsted, and Andersen, Lars H.

Subjects

*PIGMENTS, *CHLOROPHYLL, *PLANT pigments, *PHOTOSYNTHETIC pigments, *VIBRONIC coupling

Abstract

Highlights from the article: Keywords: action spectroscopy; chlorophyll; chromophore; gas phase; photosynthesis; triplet state Gruber et al. studied the intrinsic photophysics of charge-tagged chlorophyll I a i and I b i using gas-phase action spectroscopy. Action spectroscopy, chlorophyll, chromophore, gas phase, photosynthesis, triplet state.

Published

2019