Abstract
The development of a very compact, highly efficient, megawatt peak power, subnanosecond pulse width, 266 nm ultraviolet (UV) microlaser is reported. It contains a specially designed passively Q-switched Nd∶YAG/Cr 4+ ∶YAG microchip laser whose high output peak power of 13 MW enables an efficient wavelength conversion without using any optics before the nonlinear crystals. The subnanosecond pulse width region, which delivers high peak power even at moderate pulse energy, is very useful for an efficient wavelength conversion. We achieve 73% second harmonic generation efficiency using a LiB 3 O 5 (lithium triborate) crystal and 45% fourth harmonic generation efficiency using a β−BaB 2 O 4 (β -barium borate) crystal. As a result, we obtain 650 μJ, 4.3 MW peak power, 150 ps, and 100 Hz pulse output at 266 nm. We use an original design for the nonlinear crystal holders to reduce the size of the microlaser. This palm-top size 266 nm UV microlaser will be useful for many applications, such as materials microprocessing, pulsed laser deposition, UV laser induced breakdown spectroscopy, and photoionization.
Highlights
Giant pulse ultraviolet (UV) lasers are needed for several industrial and scientific applications, such as materials microprocessing, fast prototyping, pulsed laser deposition, and photoionization
We have been working on the development of very compact, giant-pulse (>1 MW peak power) Nd∶YAG∕Cr4þ∶YAG microchip lasers using quasi-continuous-wave (QCW) pumping for several applications
We report the development of a palm-top size UV microlaser whose compactness is increased by eliminating any focusing optics between the laser source and the nonlinear crystals and by not using any commercial rotational stages
Summary
Giant pulse ultraviolet (UV) lasers are needed for several industrial and scientific applications, such as materials microprocessing, fast prototyping, pulsed laser deposition, and photoionization. We have been working on the development of very compact, giant-pulse (>1 MW peak power) Nd∶YAG∕Cr4þ∶YAG microchip lasers using quasi-continuous-wave (QCW) pumping for several applications.. We have been working on the development of very compact, giant-pulse (>1 MW peak power) Nd∶YAG∕Cr4þ∶YAG microchip lasers using quasi-continuous-wave (QCW) pumping for several applications.3,4 We have used these lasers to develop a laser ignition module that can be used in automobiles to replace spark plugs.. We proposed the use of [110]-cut Cr4þ∶YAG, instead of the normally used [100]-cut Cr4þ∶YAG, to achieve a stable, linearly polarized output.7 With this approach, we have obtained several megawatt peak power, linearly polarized output with a passively Q-switched Nd∶YAG∕Cr4þ∶YAG microchip laser. We have obtained several megawatt peak power, linearly polarized output with a passively Q-switched Nd∶YAG∕Cr4þ∶YAG microchip laser Using this microchip laser output, we have achieved
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