. "San Diego" . . . "8"^^ . . . . . "Demonstration of multi-dimensional optical binding in counter-propagating laser beams with variable beam properties"@en . . . . "Optical Trapping and Optical Micromanipulation VIII (Proceedings of SPIE Vol. 8097)" . . "optical binding; optical tweezers; dual-beam trap; self-arrangement; colloids"@en . "Zem\u00E1nek, Pavel" . . "000296029200020" . "P(ED0017/01/01), P(GA202/09/0348), P(GPP205/11/P294), P(LC06007), Z(AV0Z20650511)" . . "Demonstration of multi-dimensional optical binding in counter-propagating laser beams with variable beam properties"@en . . "Kar\u00E1sek, V\u00EDt\u011Bzslav" . . . "Bellingham" . "Demonstration of multi-dimensional optical binding in counter-propagating laser beams with variable beam properties" . "RIV/68081731:_____/11:00368395!RIV12-MSM-68081731" . "978-0-8194-8707-0" . "Demonstration of multi-dimensional optical binding in counter-propagating laser beams with variable beam properties" . "193284" . "RIV/68081731:_____/11:00368395" . "Brzobohat\u00FD, Oto" . . . . "We report on dynamic modifications of the size of micro-structures self-arranged in counter-propagating laser beams by means of beams width changing. In contrast to previous published results, where the optically bound structures were kept stationary without dynamic control, here we present a method that allows dynamic modification of the self-arranged structure employing shrinking or enlargement of the %22optical cage%22 where the particles are kept. We show the full potential of this method and demonstrate tunable optical self-arrangement of particles in one-dimension using a pair of counter-propagating Bessel beams or Gaussian beams, in two-dimensions far from the surface using a pair of counter-propagating elliptical Gaussian beams, in three-dimensions using three pairs of counter-propagating Gaussian beams arranged in space." . "2011-08-21+02:00"^^ . . . . . . "3"^^ . "We report on dynamic modifications of the size of micro-structures self-arranged in counter-propagating laser beams by means of beams width changing. In contrast to previous published results, where the optically bound structures were kept stationary without dynamic control, here we present a method that allows dynamic modification of the self-arranged structure employing shrinking or enlargement of the %22optical cage%22 where the particles are kept. We show the full potential of this method and demonstrate tunable optical self-arrangement of particles in one-dimension using a pair of counter-propagating Bessel beams or Gaussian beams, in two-dimensions far from the surface using a pair of counter-propagating elliptical Gaussian beams, in three-dimensions using three pairs of counter-propagating Gaussian beams arranged in space."@en . "SPIE" . "[A90EF92E614D]" . "\u010Ci\u017Em\u00E1r, T." . . "4"^^ . .