LED

Light-emitting diodes have largely replaced older lighting technologies, such as incandescent bulbs While incandescent bulbs typically abruptly burn out or stop working, LED lights dim over time.

LED, in electronics, a semiconductor device that emits infrared or visible light when charged with an electric current. LED displays began to be used for consumer electronic devices starting in 1968, when Hewlett-Packard (HP) introduced the first LED display. Visible LED lights are used in many electronic devices as indicator lamps, car brake lights, and as alphanumeric displays or even full-color posters on billboards and signs. Infrared LEDs are employed in autofocus cameras and television remote controls and also as light sources in fiber-optic telecommunication systems.

The familiar but now outdated light bulb gave off light through incandescence, a phenomenon in which the heating of a wire filament by an electric current causes the wire to emit photons, the basic energy packets of light. Incandescent light bulbs were gradually phased out in the United States starting in 2007 with the Energy Independence and Security Act. They were fully banned in the European Union (EU) starting in 2012. In 2023 the Biden administration’s ban on the manufacture and sale of incandescent bulbs took effect.

LEDs, on the other hand, operate by electroluminescence, in which the emission of photons is caused by electronic excitation of a material. The material used most often in LEDs is gallium arsenide, though there are many variations on this basic compound, such as aluminum gallium arsenide or aluminum gallium indium phosphide. These compounds are members of the “III-V” group of semiconductors—that is, compounds made of elements listed in columns III and V of the periodic table. Varying the precise composition of the semiconductor can alter the wavelength (and therefore the color) of the emitted light.

LED emission is generally in the visible part of the light spectrum (i.e., with wavelengths from 0.4 to 0.7 micrometer) or in the near-infrared section (with wavelengths between 0.78 and 2.5 micrometers). The brightness of the light observed from an LED depends on the power emitted by the LED and on the relative sensitivity of the eye at the emitted wavelength. Maximum sensitivity occurs at 0.555 micrometer, which is in the yellow-orange and green region. The applied voltage in most LEDs is quite low, about 2.0 volts. The current depends on the application and ranges from a few milliamperes to several hundred milliamperes.

The term diode refers to the twin-terminal structure of the light-emitting device. In a flashlight, for example, a wire filament is connected to a battery through two terminals, one (the anode) bearing the negative electric charge and the other (the cathode) bearing the positive charge. In LEDs, as in other semiconductor devices such as transistors, the “terminals” are actually two semiconductor materials of different composition and electronic properties brought together to form a junction. In one material (the negative, or n-type, semiconductor) the charge carriers are electrons, and in the other (the positive, or p-type, semiconductor) the charge carriers are “holes” created by the absence of electrons. Under the influence of an electric field (supplied by a battery, for instance, when the LED is switched on), current can be made to flow across the p-n junction, providing the electronic excitation that causes the material to emanate light.

In a typical LED structure the clear epoxy dome serves as a structural element to hold the lead frame together, as a lens to focus the light, and as a refractive index match to permit more light to escape from the LED chip. The chip, typically 250 × 250 × 250 micrometers in dimension, is mounted in a reflecting cup formed in the lead frame. The p-n-type GaP:N layers represent nitrogen added to gallium phosphide to give green emission; the p-n-type GaAsP:N layers represent nitrogen added to gallium arsenide phosphide to give orange and yellow emission; and the p-type GaP:Zn,O layer represents zinc and oxygen added to gallium phosphide to give red emission. Two further enhancements, developed in the 1990s, are LEDs based on aluminum gallium indium phosphide, which emit light efficiently from green to red-orange, and also blue-emitting LEDs based on silicon carbide or gallium nitride. Blue LEDs can be combined on a cluster with other LEDs to give all colors, including white, for full-color moving displays.

Any LED can be used as a light source for a short-range fiber-optic transmission system—that is, over a distance of less than 100 meters (330 feet). For long-range fiber optics, however, the emission properties of the light source are selected to match the transmission properties of the optical fiber, and in this case the infrared LEDs are a better match than the visible-light LEDs. Glass optical fibers suffer their lowest transmission losses in the infrared region at wavelengths of 1.3 and 1.55 micrometers. To match these transmission properties, LEDs are employed that are made of gallium indium arsenide phosphide layered on a substrate of indium phosphide. The exact composition of the material may be adjusted to emit energy precisely at 1.3 or 1.55 micrometers.

The Editors of Encyclopaedia BritannicaThis article was most recently revised and updated by Tara Ramanathan.