( This is an EPR spectrometer at UCSB. (Credit: Susumu Takahashi)
ScienceDaily (Sep. 19,
2012) — A multi-university team has employed a high-powered
laser based at UC Santa Barbara to dramatically improve one of the tools
scientists use to study the world at the atomic level. The team used their
amped-up electron paramagnetic resonance (EPR) spectrometer to study the
electron spin of free radicals and nitrogen atoms trapped inside a diamond.
The
improvement will pull back the veil that shrouds the molecular world, allowing
scientists to study tiny molecules at a high resolution.
The
team, which includes researchers from UCSB, University of Southern California
(USC), and Florida
State University ,
published its findings this week in Nature.
"We
developed the world's first free-electron laser-powered EPR spectrometer,"
said Susumu Takahashi, assistant professor of chemistry at the USC Dornsife
College of Letters, Arts and Sciences, and lead author of the Nature paper.
"This ultra high-frequency, high-power EPR system gives us extremely good
time resolution. For example, it enables us to film biological molecules in
motion."
By
using a high-powered laser, the researchers were able to significantly enhance
EPR spectroscopy, which uses electromagnetic radiation and magnetic fields to
excite electrons. These excited electrons emit electromagnetic radiation that
reveals details about the structure of the targeted molecules.
EPR
spectroscopy has existed for decades. Its limiting factor is the
electromagnetic radiation source used to excite the electrons -- it becomes
more powerful at high magnetic fields and frequencies, and, when targeted,
electrons are excited with pulses of power as opposed to continuous waves.
Until
now, scientists performed pulsed EPR spectroscopy with a few tens of GHz of
electromagnetic radiation. Using UCSB's free electron laser (FEL), which emits
a pulsed beam of electromagnetic radiation, the team was able to use 240 GHz of
electromagnetic radiation to power an EPR spectrometer.
"Each
electron can be thought of as a tiny magnet that senses the magnetic fields
caused by atoms in its nano-neighborhood," said Mark Sherwin, professor of
physics and director of the Institute for Terahertz Science and Technology at
UCSB. "With FEL-powered EPR, we have shattered the electromagnetic
bottleneck that EPR has faced, enabling electrons to report on faster motions
occurring over longer distances than ever before. We look forward to
breakthrough science that will lay foundations for discoveries like new drugs
and more efficient plastic solar cells."
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