“…Likewise, many scientists then developed nitrogen lasers and worked on improving their efficiency. Afterward, many applications were studied using nitrogen lasers to visualize the pulsed plasma in the range of nanoseconds by M. S Averin in 2004 [5]. A.…”
This work aims to a detailed description of the development of a prototype Transversely Excited Atmospheric (TEA) nitrogen laser and its high-tension electrical pump source, along with its application study of Laser-Induced Fluorescence (LIF). The high-tension pump source is designed and simulated by using NI Multisim to study the voltage behavior at different points. The high-tension pump source is constructed using the flyback transformer. The open-air laser cavity is designed and simulated by using Zemax Optic Studio. Blumlein transmission line equivalent of nitrogen laser is designed in NI Multisim, voltage and current behavior across laser cavity and spark gap are simulated. The air is used as a lasing medium, as it contains 78% molecular nitrogen. The L-shaped electrodes are used as a cavity in the construction of this N 2 laser system. An ignition system in the form of the low inductance spark gap is built using the two bolts. Generally, the current passes through gas either by transverse or longitudinal discharge; in this work, the transverse discharge technique is used. Nitrogen laser produces a beam with a center wavelength of 337.1nm. Laser-induced fluorescence spectrum of the Pyranine is taken which shows its fluorescence in the green region with a maximum peak at the wavelength of 567.5nm. Pyranine is made up of a mixture of C 16 H 7 Na 3 O 10 S 3 so some other peaks can also be seen in the fluorescence spectrum with low intensity.
“…Likewise, many scientists then developed nitrogen lasers and worked on improving their efficiency. Afterward, many applications were studied using nitrogen lasers to visualize the pulsed plasma in the range of nanoseconds by M. S Averin in 2004 [5]. A.…”
This work aims to a detailed description of the development of a prototype Transversely Excited Atmospheric (TEA) nitrogen laser and its high-tension electrical pump source, along with its application study of Laser-Induced Fluorescence (LIF). The high-tension pump source is designed and simulated by using NI Multisim to study the voltage behavior at different points. The high-tension pump source is constructed using the flyback transformer. The open-air laser cavity is designed and simulated by using Zemax Optic Studio. Blumlein transmission line equivalent of nitrogen laser is designed in NI Multisim, voltage and current behavior across laser cavity and spark gap are simulated. The air is used as a lasing medium, as it contains 78% molecular nitrogen. The L-shaped electrodes are used as a cavity in the construction of this N 2 laser system. An ignition system in the form of the low inductance spark gap is built using the two bolts. Generally, the current passes through gas either by transverse or longitudinal discharge; in this work, the transverse discharge technique is used. Nitrogen laser produces a beam with a center wavelength of 337.1nm. Laser-induced fluorescence spectrum of the Pyranine is taken which shows its fluorescence in the green region with a maximum peak at the wavelength of 567.5nm. Pyranine is made up of a mixture of C 16 H 7 Na 3 O 10 S 3 so some other peaks can also be seen in the fluorescence spectrum with low intensity.
“…Such as the measurement of the speed of sound in various materials [1], observance of nanosecond scale plasma [2],bio-molecules analysis by nanoparticles based mass spectrometry [3], and surface-assisted laser desorption [4]. Further applications, thinfilm deposition for non-linear optical purposes [5],Te-doped Ge-Se thin films crystallization [6], andcategorization of change in phase of chalcogenide thin films [7].…”
In the reported article, we have simulated the pulsed high voltage direct current (DC) source andBlumlein transmission line by Multisimulation13 (National Instruments, Inc
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.