Energy transfer pathways in semiconducting carbon nanotubes revealed using two-dimensional white-light spectroscopy

Proteins exhibit structural fluctuations over decades of time scales. From the picosecond side chain motions to aggregates that form over the course of minutes, characterizing protein structure over these vast lengths of time is important to understanding their function. In the past 15 years, two-dimensional infrared spectroscopy (2D IR) has been established as a versatile tool that can uniquely probe proteins structures on many time scales. In this review, we present some of the basic principles behind 2D IR and show how they have, and can, impact the field of protein biophysics. We highlight experiments in which 2D IR spectroscopy has provided structural and dynamical data that would be difficult to obtain with more standard structural biology techniques. We also highlight technological developments in 2D IR that continue to expand the scope of scientific problems that can be accessed in the biomedical sciences.

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“…However, there have been recent cases where frequency correlations do give a more detailed understanding of the system. 73 …”

Section: Theory Of 2d Ir Spectroscopymentioning

confidence: 99%

Watching Proteins Wiggle: Mapping Structures with Two-Dimensional Infrared Spectroscopy

2017

Self Cite

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“…In particular, two-dimensional electronic spectroscopy (2DES), which uses ultrafast visible pulses to excite electronic transitions of the system, has been extensively utilized to unravel couplings between electronic and vibronic states, [2][3][4][5] energy relaxation pathways and quantum coherence in a variety of systems including photosynthetic light harvesting complexes [6,7] as well as organic and inorganic semiconductor nanostructures [8][9][10][11][12][13][14][15]. 2DES has proven to be particularly incisive for interrogating complex systems with highly congested energy states, because time evolution of the third-order signal along one frequency axis (emission frequency, ω t ) is spread out to a second frequency axis (excitation frequency, ω τ ).…”

Section: Introductionmentioning

confidence: 99%

Ultrabroadband 2D electronic spectroscopy with high-speed, shot-to-shot detection

Son¹,

Mosquera-Vázquez²,

Schlau‐Cohen³

2017

Opt. Express

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Two-dimensional electronic spectroscopy (2DES) is an incisive tool for disentangling excited state energies and dynamics in the condensed phase by directly mapping out the correlation between excitation and emission frequencies as a function of time. Despite its enhanced frequency resolution, the spectral window of detection is limited to the laser bandwidth, which has often hindered the visualization of full electronic energy relaxation pathways spread over the entire visible region. Here, we describe a high-sensitivity, ultrabroadband 2DES apparatus. We report a new combination of a simple and robust setup for increased spectral bandwidth and shot-to-shot detection. We utilize 8-fs supercontinuum pulses generated by gas filamentation spanning the entire visible region (450 -800 nm), which allows for a simultaneous interrogation of electronic transitions over a 200-nm bandwidth, and an all-reflective interferometric delay system with angled nanopositioner stages achieves interferometric precision in coherence time control without introducing wavelength-dependent dispersion to the ultrabroadband spectrum. To address deterioration of detection sensitivity due to the inherent instability of ultrabroadband sources, we introduce a 5-kHz shot-to-shot, dual chopping acquisition scheme by combining a high-speed line-scan camera and two optical choppers to remove scatter contributions from the signal. Comparison of 2D spectra acquired by shot-to-shot detection and averaged detection shows a 15-fold improvement in the signal-to-noise ratio. This is the first direct quantification of detection sensitivity on a filamentation-based ultrabroadband 2DES apparatus.

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“…Coherent two-dimensional (2D) electronic spectroscopy [1][2][3][4][5] has become an established method to study, among others, energy transfer in light harvesting complexes, [6][7][8] electronic dynamics in semiconductors, [9][10][11][12][13] plasmonic coherences, 14 and photochemical reactions. 15 Most of the experimental realizations rely on the non-collinear box geometry and heterodyned detection of a coherent optical signal.…”

Section: Introductionmentioning

confidence: 99%

Optimizing sparse sampling for 2D electronic spectroscopy

Roeding

Klimovich

Brixner

2017

The Journal of Chemical Physics

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We present a new data acquisition concept using optimized non-uniform sampling and compressed sensing reconstruction in order to substantially decrease the acquisition times in action-based multidimensional electronic spectroscopy. For this we acquire a regularly sampled reference data set at a fixed population time and use a genetic algorithm to optimize a reduced non-uniform sampling pattern. We then apply the optimal sampling for data acquisition at all other population times. Furthermore, we show how to transform two-dimensional (2D) spectra into a joint 4D time-frequency von Neumann representation. This leads to increased sparsity compared to the Fourier domain and to improved reconstruction. We demonstrate this approach by recovering transient dynamics in the 2D spectrum of a cresyl violet sample using just 25% of the originally sampled data points.

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Energy transfer pathways in semiconducting carbon nanotubes revealed using two-dimensional white-light spectroscopy

Cited by 93 publications

References 47 publications

Watching Proteins Wiggle: Mapping Structures with Two-Dimensional Infrared Spectroscopy

Watching Proteins Wiggle: Mapping Structures with Two-Dimensional Infrared Spectroscopy

Ultrabroadband 2D electronic spectroscopy with high-speed, shot-to-shot detection

Optimizing sparse sampling for 2D electronic spectroscopy

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