Laser diodes

The laser diode is a further development upon the regular light-emitting diode, or LED. The term “laser” itself is actually an acronym, despite the fact its often written in lower-case letters. “Laser” stands for Light Amplification by Stimulated Emission of Radiation, and refers to another strange quantum process whereby characteristic light emitted by electrons falling from high-level to low-level energy states in a material stimulate other electrons in a substance to make similar “jumps,” the result being a synchronized output of light from the material. This synchronization extends to the actual phase of the emitted light, so that all light waves emitted from a “lasing” material are not just the same frequency (color), but also the same phase as each other, so that they reinforce one another and are able to travel in a very tightly-confined, nondispersing beam. This is why laser light stays so remarkably focused over long distances: each and every light wave coming from the laser is in step with each other.

(a) White light of many wavelengths. (b) Mono-chromatic LED light, a single wavelength. (c) Phase coherent laser light.

Incandescent lamps produce “white” (mixed-frequency, or mixed-color) light as in Figure above (a). Regular LEDs produce monochromatic light: same frequency (color), but different phases, resulting in similar beam dispersion in Figure above (b). Laser LEDs produce coherent light: light that is both monochromatic (single-color) and monophasic (single-phase), resulting in precise beam confinement as in Figure above (c).

Laser light finds wide application in the modern world: everything from surveying, where a straight and nondispersing light beam is very useful for precise sighting of measurement markers, to the reading and writing of optical disks, where only the narrowness of a focused laser beam is able to resolve the microscopic “pits” in the disk’s surface comprising the binary 1′s and 0′s of digital information.

Some laser diodes require special high-power “pulsing” circuits to deliver large quantities of voltage and current in short bursts. Other laser diodes may be operated continuously at lower power. In the continuous laser, laser action occurs only within a certain range of diode current, necessitating some form of current-regulator circuit. As laser diodes age, their power requirements may change (more current required for less output power), but it should be remembered that low-power laser diodes, like LEDs, are fairly long-lived devices, with typical service lives in the tens of thousands of hours.

Jered Wierzbicki (December 2002): Pointed out error in diode equation — Boltzmann’s constant shown incorrectly.

Keyword :
laser diode ,laser diodes ,diode laser ,red laser ,wavelengths ,wavelength ,voltage ,products ,output power ,temperature controller ,semiconductor lasers ,semiconductor ,quantum well ,power supply ,power laser ,optics ,modules ,lasers ,laser pointers ,laser pointer ,laser modules ,laser module ,laser diode modules ,laser diode module ,laser diode driver ,high power ,violet laser ,threshold current ,stable ,setpoint ,project ,pigtail ,line generators ,laser products ,laser diode controller ,high power laser diode ,high power diode laser ,green laser ,energy ,electronic components ,driver ,dpss laser ,diodes ,diode lasers ,datasheet ,current source ,controller ,circuit ,cavity ,butterfly ,beam divergence ,battery ,accuracy.