Jana B. Nieder scite author profile

The initial steps of photosynthesis comprise the absorption of sunlight by pigment-protein antenna complexes followed by rapid and highly efficient funneling of excitation energy to a reaction center. In these transport processes, signatures of unexpectedly long-lived coherences have emerged in two-dimensional ensemble spectra of various light-harvesting complexes. Here, we demonstrate ultrafast quantum coherent energy transfer within individual antenna complexes of a purple bacterium under physiological conditions. We find that quantum coherences between electronically coupled energy eigenstates persist at least 400 femtoseconds and that distinct energy-transfer pathways that change with time can be identified in each complex. Our data suggest that long-lived quantum coherence renders energy transfer in photosynthetic systems robust in the presence of disorder, which is a prerequisite for efficient light harvesting.

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Ultrafast dynamics of single molecules

Brinks

et al. 2014

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The detection of individual molecules has found widespread application in molecular biology, photochemistry, polymer chemistry, quantum optics and super-resolution microscopy. Tracking of an individual molecule in time has allowed identifying discrete molecular photodynamic steps, action of molecular motors, protein folding, diffusion, etc. down to the picosecond level. However, methods to study the ultrafast electronic and vibrational molecular dynamics at the level of individual molecules have emerged only recently. In this review we present several examples of femtosecond single molecule spectroscopy. Starting with basic pump-probe spectroscopy in a confocal detection scheme, we move towards deterministic coherent control approaches using pulse shapers and ultra-broad band laser systems. We present the detection of both electronic and vibrational femtosecond dynamics of individual fluorophores at room temperature, showing electronic (de)coherence, vibrational wavepacket interference and quantum control. Finally, two colour phase shaping applied to photosynthetic light-harvesting complexes is presented, which allows investigation of the persistent coherence in photosynthetic complexes under physiological conditions at the level of individual complexes.

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Spectral Diffusion Induced by Proton Dynamics in Pigment−Protein Complexes

Brecht¹,

Studier²,

Radics³

et al. 2008

J. Am. Chem. Soc.

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The fluorescence emission of individual photosystem I complexes from Synechocystis PCC 6803 in protonated and deuterated buffer shows zero-phonon lines as well as broad intensity distributions. The number and the line width of the zero phonon lines depend strongly on the solvent (H(2)O/D(2)O). The spectral diffusion rate of the whole fluorescence emission from photosystem I is significantly reduced upon deuteration of the solvent. This leads to a substantial increase of well-resolved zero-phonon lines. Since the chlorophyll a chromophores lack exchangeable protons, these observed changes in the spectral diffusion have to be assigned to exchangeable protons at the amino acids and structural water molecules in the chromophore binding pocket.

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Fluorescence Studies into the Effect of Plasmonic Interactions on Protein Function

2010

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Jana B. Nieder

Quantum Coherent Energy Transfer over Varying Pathways in Single Light-Harvesting Complexes

Ultrafast dynamics of single molecules

Spectral Diffusion Induced by Proton Dynamics in Pigment−Protein Complexes

Fluorescence Studies into the Effect of Plasmonic Interactions on Protein Function

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