Title :
Non-exponential decay of autoionizing shock-wavepackets
Author :
Thoma, J.E. ; Jones, R.R.
Author_Institution :
Dept. of Phys., Virginia Univ., Charlottesville, VA, USA
Abstract :
Summary form only given. Electron correlation has a profound effect on the evolution of doubly-excited states in two-electron atoms. We are currently investigating the use of ultra-fast laser excitation to manipulate the evolution and decay of autoionizing states of alkaline-earth atoms. A straightforward approach to this problem involves the sequential excitation of both electrons to individually tailored Rydberg wavepackets. The key to the success of this type of scheme is understanding the evolution of the intermediate autoionizing states during the multi-step excitation. To this end, we have probed the evolution of the autoionizing wavepacket that is produced when a stationary singly excited Rydberg state undergoes a sudden isolated-core excitation (ICE) of the "inner" electron.
Keywords :
Rydberg states; autoionisation; excited states; high-speed optical techniques; laser beam effects; shock waves; alkaline-earth atoms; autoionizing shock-wavepackets; autoionizing states; autoionizing wavepacket; doubly-excited states; electron correlation; individually tailored Rydberg wavepackets; intermediate autoionizing states; multi-step excitation; non-exponential decay; sequential excitation; stationary singly excited Rydberg state; sudden isolated-core excitation; two-electron atoms; ultra-fast laser excitation; Atom lasers; Atomic beams; Calcium; Electrons; Ice; Laser excitation; Laser theory; Optical pulses; Physics; Stationary state;
Conference_Titel :
Quantum Electronics and Laser Science Conference, 1999. QELS '99. Technical Digest. Summaries of Papers Presented at the
Conference_Location :
Baltimore, MD, USA
Print_ISBN :
1-55752-576-X
DOI :
10.1109/QELS.1999.807311
