by Hilling, B., Schemme, T., Voit, K.-M., Schmidt, H.-J. and Imlau, M.
Abstract:
The optical excitation of space-charge waves (SCW) has been realized experimentally by superposition of static and moving light interference patterns with Bi12GeO20 as an example. A clear resonance behavior of the ac detected in an external electric circuit, as well as an inverse dispersion law, is verified, and a low frequency signal due to a modulation of the photoconductivity appears. The results are compared to the classical method using an oscillating light pattern for excitation. The optimized method allows for the detection of the charge carriers participating in SCW formation and yields an excitation of higher quality.
Reference:
Space-charge wave excitation by superposition of static and moving interference patterns (Hilling, B., Schemme, T., Voit, K.-M., Schmidt, H.-J. and Imlau, M.), In Phys. Rev. B, American Physical Society, volume 80, 2009.
Bibtex Entry:
@Article{Hilling2009,
author = {Hilling, B. and Schemme, T. and Voit, K.-M. and Schmidt, H.-J. and Imlau, M.},
title = {{Space-charge wave excitation by superposition of static and moving interference patterns}},
journal = {Phys. Rev. B},
year = {2009},
volume = {80},
number = {20},
pages = {205118},
month = nov,
abstract = {The optical excitation of space-charge waves (SCW) has been realized experimentally by superposition of static and moving light interference patterns with Bi12GeO20 as an example. A clear resonance behavior of the ac detected in an external electric circuit, as well as an inverse dispersion law, is verified, and a low frequency signal due to a modulation of the photoconductivity appears. The results are compared to the classical method using an oscillating light pattern for excitation. The optimized method allows for the detection of the charge carriers participating in SCW formation and yields an excitation of higher quality.},
doi = {10.1103/PhysRevB.80.205118},
numpages = {5},
publisher = {American Physical Society},
}