Title :
Optomechanical self-organization in cold atomic gases
Author :
Ackemann, T. ; Tesio, E. ; Labeyrie, G. ; Robb, G.R.M. ; Gomes, P.M. ; Arnold, A.S. ; Firth, W.J. ; Oppo, G.-L. ; Kaiser, Rene
Author_Institution :
Dept. of Phys., Univ. of Strathclyde, Glasgow, UK
Abstract :
We discuss the formation of optomechanical structures from the interaction between linear dielectric scatterers and a light field via dipole forces without the need for optical nonlinearities. The experiment uses a high density sample of Rb atoms in a single mirror feedback geometry. We observe hexagonal structures in the light field and a complementary honeycomb pattern in the atomic density. Different theoretical approaches are discussed assuming either viscous damping of the atomic velocity or not. The interplay between electronic and optomechanical nonlinearities is analyzed. A prediction for dissipative light - matter density solitons is given. The investigations demonstrate novel prospects for the manipulation of matter in a pattern forming system in which quantum effects should be accessible.
Keywords :
geometrical optics; light scattering; mirrors; optical feedback; optical solitons; quantum optics; radiation pressure; rubidium; self-assembly; Rb; cold atomic gases; complementary honeycomb pattern; dipole forces; dissipative light-matter density solitons; electronic nonlinearities; hexagonal structures; linear dielectric scatterer-light field interaction; optomechanical nonlinearities; optomechanical self-organization; optomechanical structure formation; quantum effects; rubidium atomic density; rubidium atomic velocity; single-mirror feedback geometry; viscous damping; Magnetic resonance imaging; Magnetomechanical effects; Solitons; Switches;
Conference_Titel :
Laser Dynamics and Nonlinear Photonics, 2013 Sixth "Rio De La Plata" Workshop on
Conference_Location :
Montevideo
DOI :
10.1109/LDNP.2013.6777412
