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Lasers in Medical Science is a bimonthly peer-reviewed medical journal covering laser medicine. It was established in 1986 and is published by Springer Science+Business Media. It is the official journal of Sociedad Española de Láser Médico Quirúrgico, the British Medical Laser Association, the International Academy for Laser Medicine and ...
Airborne laser; Airborne wind turbine; Airy beam; ALKA; All gas-phase iodine laser; Ambient ionization; Amplified spontaneous emission; Analytical chemistry; Aneutronic fusion; Antiproton Decelerator; Apache Arrowhead; Apache Point Observatory Lunar Laser-ranging Operation; Arago spot; Argon fluoride laser; Argus laser; Asterix IV laser ...
FEL – free electron laser; FREAG – frequency-resolved electro-absorption gating [citation needed] FROG – frequency-resolved optical gating; FROG-CRAB – frequency-resolved optical gating for complete reconstruction of attosecond bursts [citation needed] FWM – four-wave mixing; FP – Fabry–Perot laser
Whereas high-power lasers are used in laser medicine to cut or destroy tissue, it is claimed that application of low-power lasers relieves pain or stimulates and enhances cell function. The effects appear to be limited to a specified set of wavelengths and new research has demonstrated effectiveness at myopia control. [6]
Research, Future applications may include collision-avoidance radar, industrial-process control and medical diagnostics such as breath analyzers. Quantum dot laser: wide range. Medicine (laser scalpel, optical coherence tomography), display technologies (projection, laser TV), spectroscopy and telecommunications. Quantum well laser
Laser radiation being delivered via a fiber for photodynamic therapy to treat cancer. A 40-watt CO 2 laser with applications in ENT, gynecology, dermatology, oral surgery, and podiatry. Laser medicine is the use of lasers in medical diagnosis, treatments, or therapies, such as laser photodynamic therapy, [1] photorejuvenation, and laser surgery.
Final amplifier of the Nike laser where laser beam energy is increased from 150 J to ~5 kJ by passing through a krypton/fluorine/argon gas mixture excited by irradiation with two opposing 670,000 volt electron beams. An excimer laser typically uses a combination of a noble gas (argon, krypton, or xenon) and a reactive gas (fluorine or chlorine).
Diagram of the design of a STED device. The double laser design allows for excitation and stimulated emission to be used together for STED. In traditional microscopy, the resolution that can be obtained is limited by the diffraction of light. Ernst Abbe developed an equation to describe this limit. The equation is: