SU500512A1 - Acousto-optic deflector - Google Patents

Claims (1)

(54) ACOUSTOPTIC DEFLECTOR is blowing: if the incident light has left circular polarization, then the diffracted light-right circular polarization and vice versa. Paratellurite-based deflector allows to obtain large angles of deviation with a small deviation of the ultrasound frequency and greater efficiency of the optical-acoustic interaction at low control powers. Lasers commonly used as light sources now have linear polarization; therefore, only half of the incident light effectively interacts with light (due to the optical activity observed in parathalurite crystals, a linearly polarized light beam splits into two circularly polarized beams and Only one of these rays interacts with the sound, the interaction with one of the soul of light rays in the crystal is determined by the angle between the normal to the direction of sound propagation and the direction falling szeta). Since the diffracted light has a circular (or more precisely elliptical, but close to circular) polarization, the noise caused by the scattered light is difficult to attenuate. The purpose of the invention is to increase the intensity of the diffracted light and the total extinction of the non-deflected light beam. For this, an acousto-optic deflector is proposed, using an optically active crystal placed between two quarter-wave phase plates. The drawing shows the layout of the proposed deflector. The deflector contains a laser 1, a high-frequency generator 2, a matching element 3, an optically active crystal 4 with a transducer f 5 and an absorber 6. A quarter-wave plate 7 is placed in front of the optically active crystal, which turns a linearly polarized beam of incident light into a circular beam with circular circular radiation. {for definiteness, for example, right). This beam passes through an optically active crystal, in which an ultrasonic wave transmitted by a piezoelectric transducer propagates. The interaction of light with an ultrasonic wave leads to a highly diffracted light having a circular polarization of the opposite polarization of the incident light of the direction (in this case, the left one). After the crystal, the diffracted light passes through another; one phase quarter-wave plate 8, at the exit from which its polarization is transformed from circularly polarized to linearly polarized. It is very important that this linear polarization of incident light and Polarization of the nondifferentiated light exiting through the deflector. This circumstance allows using the polarizer 9 to isolate only the diffracted deflected beam and suppress unwanted scattered or non-ultrasound-interacting light .. To reduce the ultrasonic signal reflected from the absorber crystal, a bevel provides for the alignment of acoustic impedances the absorber with the crystal, and the ingress of the residual reflected signal to the additional absorber 10 located on the side face of the crystal. Tests of the proposed difflector showed that it gives a gain in the intensity of the deflected light compared to the conventional scheme by 4O% and the suppression of the intensity of un-deflected light and noise from the scattered light more than 9O times. The angle between the non-deflected and deflected light varied from 2.3 to 5.2 when the frequency of the exciting signal was varied from 40 to 9 MHz. The intensity of the deflected light reached 5O% of the incident light with a control power of an acoustic signal of 1 MW. An acoustooptic deflector containing an element of an optically active paratellurite crystal, a piezoelectric transducer, an elastic wave absorber located on a beveled crystal face opposite to the piezoelectric transducer, characterized in that, in order to increase the intensity of light and completely neutralize it. of the beam, a quarter-wave phase plate is installed in front of the crystal, and after the crystal, the second plate and polarization analyzer are in position. gaishnii neot; yunennogo.