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Observation of Pulsed Laser – Induced Melting of Solid Surfaces by Optical Spin Orientation
Published online by Cambridge University Press: 25 February 2011
Abstract
The optically induced spin polarization P of the photoelectrons emitted from tin and germanium during ps and ns laser pulses is measured as a function of the pulse energy. P is defined by the lattice symmetry of the sample. It vanishes for amorphous or molten surfaces. The melting of the metal and the semiconductor is found to occur on a time scale which is short compared to the duration of a 70 ps laser pulse. The emission of positive ions starts at the laser intensity for which the drop of the polarization is observed. If Ge is heated with ns laser pulses a temperature dependent shift of the work function causes a decrease of the spin polarization for laser energies far below the energy necessary for melting. With ps laser pulses the polarization only vanishes for pulse energies exceeding Eion- The difference between the ps and ns measurements on Ge points to an unexpected dynamical behavior of the work function shift in semiconductors.
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- Copyright © Materials Research Society 1990
References
REFERENCES
1
Campagna, M., Pierce, D. T., Meier, F., Sattler, K., and Siegmann, H. C., Adv. Electron. Electron Phys.
41, 113 (1976)Google Scholar
2
Bona, G. L., Meier, F., Schönhense, G., Aeschlimann, M., Stampanoni, M., Zampieri, G., and Siegmann, H. C., Phys. Rev. B, 34, 7784 (1986).Google Scholar
3
Bona, G. L., Ph. D. Dissertation, ETH Zürich, no. 8251, 1987 (unpublished). M. Aeschlimann, Ph. D. Dissertation, ETH Zürich, no. 8863, 1989 (unpublished).Google Scholar
4
Meier, F. and Pescia, D., in Optical Orientation, edited by Meier, F. and Zakharchenya, B. P. (North-Holland, Amsterdam, 1984), p. 295.Google Scholar
6
Fujimoto, J. G., Liu, J. M., Ippen, E. P. and Bloembergen, N., Rev. Lett.
53, 1837 (1984).Google Scholar
7
Elsayed-Ali, H. E., Norris, T. B., Pessot, M. A., and Mourou, G.A., Phys. Rev. Lett.
58, 1212 (1987).Google Scholar
8
Schoenlein, R.W., Lin, W. Z., Fujimoto, J. G., and Eesley, G.L., Phys. Rev. Lett.
58, 1680 (1987).Google Scholar
9
Hicks, J.M., Urbach, L. E., Plummer, E. W., and Dai, Hai-Lung, Rev. Lett.
61, 2588 (1988).Google Scholar
10
Corkum, P.B., Brunei, F., Sherman, N. K., and Srinivasan-Rao, T., Phys. Rev. Lett.
61, 2886 (1988).Google Scholar
11
Malvezzi, A. M., Liu, J. M., and Bloembergen, N., Appl. Phys. Lett.
45, 1019 (1984).Google Scholar
12
Fabricius, N., Hermes, P., von der Linde, D., Pospieszczyk, A., and Stritzker, B., in Beam-Solid Interactions and Phase Transformations, edited by Kurz, H., Olson, G. L. and Poate, J. M. (Mater. Res. Soc. Proc. 51, 1986), p.p. 219 – 223.Google Scholar
14
Spicer, W. E., Lindau, I., Skeath, P., Su, C. Y., and Chye, P., Phys. Rev. Lett.
44, 420 (1980).Google Scholar
15
Vitomirov, I. M., Waddill, G. D., Aldao, C. M., Anderson, S. G., Capasso, C., and Weaver, J. H., Phys. Rev. B, 40, 3483 (1989).Google Scholar