We
introduce femtosecond wide-field transient absorption microscopy
combining sub-10 fs pump and probe pulses covering the complete visible
(500–650 nm) and near-infrared (650–950 nm) spectrum
with diffraction-limited optical resolution. We demonstrate the capabilities
of our system by reporting the spatially- and spectrally-resolved
transient electronic response of MAPbI3–xClx perovskite films and reveal
significant quenching of the transient bleach signal at grain boundaries.
The unprecedented temporal resolution enables us to directly observe
the formation of band-gap renormalization, completed in 25 fs after
photoexcitation. In addition, we acquire hyperspectral Raman maps
of TIPS pentacene films with sub-400 nm spatial and sub-15 cm–1 spectral resolution covering the 100–2000
cm–1 window. Our approach opens up the possibility
of studying ultrafast dynamics on nanometer length and femtosecond
time scales in a variety of two-dimensional and nanoscopic systems.
A hallmark of the primary visual event is the barrierless, ultrafast, and efficient 11-cis to all-trans photoisomerization of the retinal protonated Schiff base (RPSB) chromophore. The remarkable reactivity of RPSB in the visual pigment rhodopsin has been attributed to potential energy surface modifications enabled by evolution-optimized chromophore-protein interactions. Here, we use a combined synthetic and ultrafast spectroscopic approach to show that barrierless photoisomerization is an intrinsic property of 11-cis RPSB, suggesting that the protein may merely adjust the ratio between fast reactive and slow unreactive decay channels. These results call for a re-evaluation of our understanding and theoretical description of RPSB photochemistry.
Chemical and structural composition of wood biomass is studied by label-free and chemically specific Coherent Anti-Stokes Raman Scattering (CARS) microscopy. A concept developed for assignment and semi-quantitative imaging of sample components; cellulose, hemicellulose, and lignin; by multiplex CARS microspectroscopy and subsequent data analysis is presented. Specific imaging without fluorescence backround is achieved an order of magnitude faster compared with conventional Raman microscopy. Laser polarization control yield information on molecular arrangement in wood fibers. Narrowband CARS excitation of single vibrations allows for three-dimensional volume imaging. Thus, CARS microscopy has potential as an important instrument for characterization of lignocellulosic materials.
We present a wide-field imaging implementation of Fourier transform coherent anti-Stokes Raman scattering (wide-field detected FT-CARS) microscopy capable of acquiring high-contrast label-free but chemically specific images over the full vibrational ‘fingerprint’ region, suitable for a large field of view. Rapid resonant mechanical scanning of the illumination beam coupled with highly sensitive, camera-based detection of the CARS signal allows for fast and direct hyperspectral wide-field image acquisition, while minimizing sample damage. Intrinsic to FT-CARS microscopy, the ability to control the range of time-delays between pump and probe pulses allows for fine tuning of spectral resolution, bandwidth and imaging speed while maintaining full duty cycle. We outline the basic principles of wide-field detected FT-CARS microscopy and demonstrate how it can be used as a sensitive optical probe for chemically specific Raman imaging.
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