Scientists at the Zuev Institute of Atmospheric Optics at the Siberian Branch of the Russian Academy of Sciences (IOA SB RAS) jointly with colleagues from Tomsk Polytechnic University (TPU) have developed a fundamentally new design of high-frequency amplifier for optical signals.
The development improves the brightness of images in laser monitors with a record pulse repetition frequency (PRF) excited by a barrier and capacitive discharge. The study’s results were published in the journal Optics Communications.
Brightness amplifiers are used to increase the luminous flux in optical systems such as lasers, projectors, and laser monitors. In practice, amplifiers based on pulsed metal vapour lasers are widely used. They have relatively high efficiency and operate at a high pulse repetition frequency, which provides reasonably good temporal resolution. In these optical signal amplifiers, light passes through a gas discharge tube in which metal pairs are activated (excited) by a discharge between the electrodes located inside the tube.
Scientists at IOA SB RAS have developed an alternative amplifier design that excites vapours with a longitudinal capacitive discharge. Electrodes in this device are located outside the gas discharge tube, which gives the design significant advantages, the authors note.
Optical amplifiers based on pulsed metal vapour lasers
The scientists used copper bromide (CuBr), excited by a discharge with a pulse repetition frequency (PRF) of up to 24 kHz, as a substance for the active medium of the amplifier. They experimentally estimated the concentration of CuBr vapours for the most efficient operation of the device. It turned out that the optimal amplification was achieved not at maximum output power, but at a concentration of the CuBr vapours approximately one-third lower.
The amplifier is successfully used to obtain bright images in monostatic and bistatic laser monitor circuits, as well as to raise the output power of the radiation emission in the “master oscillator-fibre amplifier” (MOPA) circuits. The contrast of the images in the monostatic and bistatic laser monitors is over 90%.
Scientists from IOA SB RAS and TPU have been engaged in joint work for many years under the supervision of Professor Gennadiy Evtushenko to study the specifics of active media on metal vapours and their use in solving problems of optics, laser physics, processing, and obtaining materials. They plan to focus further research on improving the efficiency of the developed brightness amplifier and its application to create laser monitors of various spectral ranges. The research work is supported by the Russian Science Foundation, Project No. 19-79-10096.
Sourse: sputniknews.com
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