Overview of laser applications: the state of the art and the future trend

The range and maturity of commercially useful laser applications are illustrated by selected examples. Macroscopic applications (commercialized or potentially so in the near future) include cutting, machining and welding metals, cutting fabrics, shock hardening of steels, nitrogenization of iron, and laser drilling through rock. Microscopic applications include drilling micro-holes for cooling of jet engine turbine blades, thin film growth, precision machining of structures inside transparent materials and inertially-confined deuterium-tritium fusion. To be commercially useful, these applications take advantage of the special properties of laser light, such as monochromaticity, high brightness, high pulse energy or intensity, wavelength range from soft xray to far infrared and pulse duration from femtoseconds to CW. This talk will be divided into three sections: (a) summary of the theory of laser-materials interactions with examples from published laser impulse production studies, (b) macroscopic applications, (c) microscopic applications and (d) exotic and futuristic applications, including a diode-laser-driven μN thruster for micro- and nano-satellites, and proposals to use lasers to clean hundreds of thousands of small but hazardous space debris from near-Earth space and to launch 5kg payloads into near-Earth orbit.

[1]  Robert C. Sze,et al.  Cloth-cutting studies using excimer laser ablation , 2000, SPIE High-Power Laser Ablation.

[2]  R. G. Root,et al.  Plasma Energy Transfer to Metal Surfaces Irradiated by Pulsed Lasers , 1977 .

[3]  Leonard J. Marabella,et al.  High-average-power industrial laser for precision machining , 1998, Other Conferences.

[4]  Claude R. Phipps,et al.  Enhanced vacuum laser-impulse coupling by volume absorption at infrared wavelengths , 1990 .

[5]  Michael L. Lander,et al.  Pulsed-laser capabilities at the Laser-Hardened Materials Evaluation Laboratory (LHMEL) , 2000, SPIE High-Power Laser Ablation.

[6]  Yurii M. Klimachev,et al.  Interaction of pulsed CO and CO2 laser radiation with rocks , 2000, SPIE High-Power Laser Ablation.

[7]  Leik N. Myrabo,et al.  Flight experiments and evolutionary development of a laser-propelled transatmospheric vehicle , 1998, Other Conferences.

[8]  William W. Hansen,et al.  Fabrication of true 3D microstructures in glass/ceramic materials by pulsed UV laser volumetric exposure techniques , 1999, Photonics West.

[9]  John O. Bagford,et al.  Laser-boosted light sail experiments with the 150-kW LHMEL II CO2 laser , 2002, SPIE High-Power Laser Ablation.

[10]  Wolfgang Riede,et al.  Comparative lightcraft impulse measurements , 2002, SPIE High-Power Laser Ablation.

[11]  Iu. P. Raizer Laser-induced discharge phenomena , 1977 .

[12]  J. Mazumder,et al.  Alloying based laser welding of galvanized steel , 2000 .

[13]  Jonathan W. Campbell,et al.  Optimum parameters for laser launching objects into low Earth orbit , 2000 .

[14]  A. Pirri Theory for momentum transfer to a surface with a high‐power laser , 1973 .