Cortical layer-specific critical dynamics triggering perception.

Perceptual experiences may arise from neuronal activity patterns in mammalian neocortex. We probed mouse neocortex during visual discrimination using a red-shifted channelrhodopsin (ChRmine, discovered through structure-guided genome mining) alongside multiplexed multiphoton-holography (MultiSLM), achieving control of individually specified neurons spanning large cortical volumes with millisecond precision. Stimulating a critical number of stimulus-orientation-selective neurons drove widespread recruitment of functionally related neurons, a process enhanced by (but not requiring) orientation-discrimination task learning.

Effect of pulse temporal shape on optical trapping and impulse transfer using ultrashort pulsed lasers.

We investigate the effects of pulse duration on optical trapping with high repetition rate ultrashort pulsed lasers, through Lorentz-Mie theory, numerical simulation, and experiment. Optical trapping experiments use a 12 femtosecond duration infrared pulsed laser, with the trapping microscope's temporal dispersive effects measured and corrected using the Multiphoton Intrapulse Interference Phase Scan method. We apply pulse shaping to reproducibly stretch pulse duration by 1.

Control of molecular fragmentation using shaped femtosecond pulses.

The possibility that chemical reactions may be controlled by tailored femtosecond laser pulses has inspired recent studies that take advantage of their short pulse duration, comparable to intramolecular dynamics, and high peak intensity to fragment and ionize molecules. In this article, we present an experimental quest to control the chemical reactions that take place when isolated molecules interact with shaped near-infrared laser pulses with peak intensities ranging from 1013 to 1016 W/cm2. Through the exhaustive evaluation of hundreds of thousands of experiments, we methodically evaluated the molecular response of 16 compounds, including isomers, to the tailored light fields, as monitored by time-of-flight mass spectrometry.

Automated phase characterization and adaptive pulse compression using multiphoton intrapulse interference phase scan in air.

We introduce a non-interferometric single beam method for automated spectral phase characterization and adaptive pulse compression of amplified ultrashort femtosecond pulses taking advantage of third order harmonic generation in air. This new method, air-MIIPS, compensates high-order phase distortions based on multiphoton intrapulse interference phase scan (MIIPS).

Advantages of ultrashort phase-shaped pulses for selective two-photon activation and biomedical imaging.

Two-photon excitation using ultrashort laser pulses can selectively activate nanoparticles or excite fluorophores within thick biological samples. We show how the use of methods such as multiphoton intrapulse interference phase scan (MIIPS) to compensate phase distortions caused by microscope objectives with a high numerical aperture increases signal intensity and reproducibility in two-photon imaging. Using phase shaping of our compensated pulses, we demonstrate selective excitation of fluorophores within a mouse kidney sample, increasing the contrast between different subcellular structures compared to unshaped pulses.

Search space mapping: getting a picture of coherent laser control.

Search space mapping is a method for quickly visualizing the experimental parameters that can affect the outcome of a coherent control experiment. We demonstrate experimental search space mapping for the selective fragmentation and ionization of para-nitrotoluene and show how this method allows us to gather information about the dominant trends behind our achieved control.

Spectral phase optimization of femtosecond laser pulses for narrow-band, low-background nonlinear spectroscopy.

We use experimental search space mapping to examine the problem of selective nonlinear excitation with binary phase shaped femtosecond laser pulses. The search space maps represent a graphical view of all the possible solutions to the selective nonlinear excitation problem along with their experimental degrees of success. Using the information learned from these maps, we generate narrow lines with low background in second harmonic generation and stimulated Raman scattering spectra.