Generation of coherent phonons by coherent extreme ultraviolet radiation in a transient grating experiment

• Main Authors: Maznev, A. A. (Author), Bencivenga, F. (Author), Cannizzo, A. (Author), Capotondi, F. (Author), Cucini, R. (Author), Duncan, R. A. (Author), Feurer, T. (Author), Frazer, T. D. (Author), Foglia, L. (Author), Frey, H.-M (Author), Kapteyn, H. (Author), Knobloch, J. (Author), Knopp, G. (Author), Masciovecchio, C. (Author), Mincigrucci, R. (Author), Monaco, G. (Author), Murnane, M. (Author), Nikolov, I. (Author), Pedersoli, E. (Author), Simoncig, A. (Author), Vega-Flick, A. (Author), Nelson, K. A. (Author)
• Other Authors: Massachusetts Institute of Technology. Department of Physics (Contributor)
• Format: Article
• Language: English
• Published: AIP Publishing, 2020-01-22T19:07:32Z.
• Subjects: Article
• Online Access: Get fulltext

We investigate the excitation of coherent acoustic and optical phonons by ultrashort extreme ultraviolet (EUV) pulses produced by a free electron laser. Two crossed femtosecond EUV (wavelength 12.7 nm) pulses are used to excite coherent phonons at a wavelength of 280 nm, which are detected via diffraction of an optical probe beam. Longitudinal and surface acoustic waves are measured in BK-7 glass, diamond, and Bi4Ge3O12; in the latter material, the excitation of a coherent optical phonon mode is also observed. We discuss probing different acoustic modes in reflection and transmission geometries and frequency mixing of surface and bulk acoustic waves in the signal. The use of extreme ultraviolet radiation will allow the creation of tunable GHz to THz acoustic sources in any material without the need to fabricate transducer structures.
United States. Department of Energy (Award DE-FG02-00ER15087)