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Posted: September 11, 2008
Lasers pushing the limits - a departure for more extreme light-matter interactions
(Nanowerk News) When matter is hit by a laser-beam, the effects on the molecules can be dramatic, particularly for short pulses of high-intensity radiation. In a quest to push the limits of intensity to achieve extreme light-matter interactions in large molecules, a team of researchers from RIKEN’s Advanced Science Institute in Wako, the SPring-8 Center in Harima, and the University of Tokyo, has demonstrated the ionisation and consequently the dissociation of nitrogen molecules using a free-electron laser.
Laser radiation is an electromagnetic wave that oscillates along a laser beam. These oscillating electromagnetic fields can exert strong forces on the electrons in a molecule, particularly at the very short wavelengths in the extreme ultraviolet (XUV) part of the spectrum. At high laser intensities, the influence on molecules increases, leading to a so-called Coulomb explosion.
Various phenomena observed in molecules with increasingly intense optical laser fields. (From Yamanouchi, K. The next frontier. Science 295, 1660 (2002). Reprinted with permission from AAAS )
A Coulomb explosion is a process where the force exerted by the laser field is so strong on electrons in a molecule that an electron gets ejected and leaves positively charged ions. These ions strongly repel each other and the molecule quickly dissociates. However, few experimental studies on this process have been reported and “little is understood concerning the interaction of intense high-frequency light in the XUV with atoms and molecules,” comments Katsumi Midorikawa from the research team.
The researchers focused laser light of extremely short wavelengths of only 50 nm on nitrogen gas. They found that each nitrogen atom absorbs two light particles from the beam, providing sufficient energy to eject an electron, so that N2 is transformed into the highly unstable N22+ molecule. Because of the strong repulsive forces, the two nitrogen ions separated. The detection of individual N+ atoms provides conclusive evidence that a Coulomb explosion occurred.
Achieving a Coulomb explosion in this way is significant because, as Midorikawa comments, “the XUV-FEL laser has the potential to produce much higher beam intensities that will allow a much better study of the interaction of matter with strong electromagnetic fields.” Indeed, experiments on larger molecules will commence once the XUV-FEL facility reaches full capacity.