A pulsed laser diode is a semiconductor device that emits laser light in short, controlled pulses. It operates based on the principle of stimulated emission, where the release of photons (light particles) is triggered by the recombination of charge carriers within the semiconductor material. Let's go through the basic working principle of a pulsed laser diode:
Semiconductor Material: The heart of a laser diode is a semiconductor material, typically made of gallium arsenide (GaAs) or other compound semiconductors. The semiconductor has two layers: an n-type (negative) layer and a p-type (positive) layer, separated by a junction known as the p-n junction.
Energy Levels: Within the semiconductor material, electrons exist in different energy levels. The valence band contains electrons at lower energy levels, and the conduction band contains electrons at higher energy levels. The energy gap between these bands is known as the bandgap energy.
Injection and Recombination: When a forward bias voltage is applied across the p-n junction, electrons from the n-type layer and holes from the p-type layer are injected into the region near the junction. These electrons and holes move into the opposite type layer due to the bias, and when they recombine, they release energy in the form of photons.
Optical Feedback: The laser diode is designed with reflective facets on each end. One facet is highly reflective, acting as a mirror, while the other facet is partially reflective. The partially reflective facet allows a portion of the emitted light to escape as the laser output.
Population Inversion: For lasing action to occur, a population inversion must be achieved. This means that more electrons are in higher energy levels (conduction band) than in lower energy levels (valence band). Achieving population inversion is crucial to generating laser light.
Pulsing: To produce pulsed output, the laser diode is typically driven with electrical pulses rather than a continuous current. By controlling the current and pulse duration, the laser diode can emit light in short bursts.
Light Emission: When the electrons and holes recombine, photons are emitted. These photons undergo reflections between the facets due to the optical feedback, stimulating further emission of photons through the process of stimulated emission. This amplification of light builds up rapidly, resulting in a coherent beam of laser light emerging from the partially reflective facet.
The rapid, coherent emission of light in pulsed form makes pulsed laser diodes useful in various applications, such as telecommunications, rangefinders, lidar systems, material processing, and scientific research. The ability to control the pulse duration and repetition rate allows for tailored light output to suit specific applications.