Research
The DeCamp lab uses ultrafast radiation to study the sub-picosecond dynamics of complex systems. This ranges from the structural dynamics of crystalline systems to molecular dynamics in solution. The DeCamp Lab is developing several time-domain spectroscopic tools to fulfill these goals, including time-resolved x-ray scattering, time-domain THz spectroscopy, and time-domain optical spectroscopy.
Laser system
The backbone of any ultrafast spectroscopy lab is the laser source. The DeCamp lab has a 1kHz Spectra-Physics Spitfire XP amplifier seeded by a KMLabs Oscillator. The laser generates 3mJ, sub-40fs laser pulses for ultrafast spectroscopy. The laser output has been upgraded to produce 5+mJ at 1kHz by the construction of a home built, LN2 cooled multipass power amplifier. Using modest focusing, this laser is able to generate optical fields greater than 10^{17}W/cm^2.
Time-resolved X-ray diffraction
We are currently utilizing a sub-picosecond x-ray source based upon generation of a dense plasma via intense (>10^15 W/cm2) laser excitation of solid targets, specifically a copper wire. In conjunction with stroboscopic pump-probe techniques, we are able to measure structural changes in crystals as small as 10^{-13}m with picosecond time resolution. The figure below demonstrates the capabilities of the system by measuring the sub-picosecond optical excitation of a Germanium (111) crystal. The generation of x-ray diffraction sidebands indicate the presence of a transient acoustic wave inside the bulk crystal.
Current experiments utilizing this x-ray source for the study of the ultrafast lattice dynamics of nanostructured systems.
Time-Domain Terahertz spectroscopy
THz radiation is the wavelength range of .020-1mm and can have pulse lengths as fast as 30fs. While these wavelengths are relatively long, it is the spectral region of low frequency molecular vibrations and rotations, making this a useful range for molecular spectroscopy. However, as the photon energy exceeding small, traditional direct detection methods are impossible. To detect the THz radiation, we utilize a time-domain THz spectrometer (TDTS), whereby the THz field directly modifies the optical polarization in a birefringent medium. By detecting the change in optical polarization, we can directly map the electric field of the THz radiation in the time-domain. In the figure below, we show a typical time-domain signal from the free-space electro-optic sampling spectrometer. A simple numerical Fourier transform of the electric field reveals the spectral content of the pulse. In this example we see distinct absorption lines associated with water vapor in the laboratory.
Currently we are using TDTS to measure vibrational dynamics in molecules as well as electron dynamics in solid-state devices.