Understanding Laser Diodes

Temporal coherence

Spatial coherence

Phase alignment

Frequency modulation

The type of semiconductor used

The diode's temperature

The frequency and wavelength of photons

The diode's size

To increase the diode's size

To change the diode's color

To transport electromagnetic waves

To absorb electromagnetic waves

The diode stops working

The diode heats up

A photon is released

A photon is absorbed

To change the diode's color

To decrease the diode's efficiency

To promote recombination and channel photons

To increase the diode's size

To change the wavelength of light

To create a standing wave for temporal coherence

To absorb excess photons

To scatter light in all directions

By adjusting the diode's temperature

By changing the semiconductor material

By increasing the diode's power

By adjusting the distance between resonator ends

They have a short lifespan

They are expensive to manufacture

They are easy to produce

They are very powerful

They tend to heat up

They are too large

They have perfect collimation

They are very powerful

It changes the diode's color

It increases the diode's power

It decreases the diode's efficiency

It creates a collimated beam