Scientists watch a crystal shake
British researchers say for the first time they have watched light riding through a crystal on the back of vibrations of the atomic lattice.
Oxford University physicist Andrea Cavalleri and colleagues used X-rays in a lithium tantalate crystal to see the coordinated vibrations of its ions, linked with the passage of particles of low-frequency light called terahertz radiation.
Lithium tantalate is a material in which an electric field induces a change in the positions of the ions that make up the crystal. The scientists say it’s that behavior that creates the coupling of vibrations in the ion lattice to the oscillating electromagnetic fields of light waves.
The lattice vibrations can be induced by shining a laser pulse onto the crystal, the scientists explained. As the lattice oscillates, it creates a fluctuating electromagnetic field that takes the form of a light polariton with a frequency close to that of the lattice vibration: at terahertz frequencies, lower than infrared, but higher than microwaves.
The study marked the first time such polariton-linked vibrations of a crystal have been directly tracked.
The research appears in the current issue (Aug. 10) of the journal Nature.
Source: UPI.
First ‘Molecular Movie’ of Light Made
OXFORD, England, Aug. 14, 2006 — What happens on a microscopic level when light travels through a medium has been captured in the first “molecular movie” of the elementary interaction between light and matter.
The research was done as part of a collaborative project involving scientists from Oxford University, the Lawrence Berkeley Laboratory in California and the Massachusetts Institute of Technology and involved watching light riding through a lithium tantalate crystal on the back of vibrations of the atomic lattice.
Oxford University’s Andrea Cavalleri of the department of physics is lead author of the study, which was recently published in Nature. He said, “We’ve all seen how a stick in a pond appears to be at a different angle depending on whether we look at it from outside or inside the water. At a microscopic level, this effect depends on how stiff atomic bonds are, and with how much delay atoms and electrons respond when they are placed in the rapidly wiggling electric field of light.
“If you want to understand the propagation of light at a microscopic level, especially in some the complex materials that are of interest for modern optoelectronic applications, you need to make a ‘molecular movie’ of how the atoms and electrons wiggle in the light field. To do so, you need to find a camera with an extremely quick shutter speed — that of a handful of femtoseconds (less than one thousandth of a billionth of a second).
“This very fast timescale can be reached with modern laser technology — but lasers can’t see where the constituents atoms actually are. If you want to see this ‘shape’ of a molecule you need x-rays, but there are currently no x++-ray beams with short enough pulses to take snapshots of atomic motions.
“What we have managed to do is combine ultrafast laser pulses with electron beams in a particle accelerator, deflecting a small slice of the long electron pulse on a separate orbit of the accelerator. Thus, these electrons radiated short enough x-ray pulses to measure elementary atomic motions on the femtosecond timescale. This enabled us to measure the motion of charged atoms on the ultrafast timescale with an accuracy of less than one thousandth of one billionth of a meter. This means we are capable of resolving in time the displacements of atoms by less than one atomic nucleus. “This technology can now be applied to other elementary processes at the microscopic level, and we can measure their displacements with unprecedented speed and resolution,” Cavalleri said.
For more information, visit: www.ox.ac.uk
Source: Photonics.com.