Incandescent commemorates the installation of electric light in 1934. In its modern form, the incandescent light bulb consists of a coiled filament of
tungsten sealed in a globular glass chamber, either a vacuum or full of an
inert gas such as
argon. When an electric current is connected, the tungsten is heated to and glows, emitting light that approximates a
continuous spectrum. Incandescent bulbs are highly inefficient, in that just 2–5% of the energy consumed is emitted as
visible, usable light. The remaining 95% is lost as
heat. In warmer climates, the emitted heat must then be removed, putting additional pressure on
ventilation or
air conditioning systems. In colder weather, the heat byproduct has some value, and has been successfully harnessed for warming in devices such as
heat lamps. Incandescent bulbs are nonetheless being
phased out in favor of technologies like
CFLs and
LED bulbs in many countries due to their low energy efficiency. The
European Commission estimated in 2012 that a complete ban on incandescent bulbs would contribute 5 to 10 billion euros to the economy and save 15 billion metric tonnes of
carbon dioxide emissions.
Halogen Halogen lamps are usually much smaller than standard incandescent lamps, because for successful operation a bulb temperature over 200 °C is generally necessary. For this reason, most have a bulb of fused silica (quartz) or aluminosilicate glass. This is often sealed inside an additional layer of glass. The outer glass is a safety precaution, to reduce ultraviolet emission and to contain hot glass shards should the inner envelope explode during operation. Oily residue from
fingerprints may cause a hot quartz envelope to shatter due to excessive heat buildup at the contamination site. The risk of burns or fire is also greater with bare bulbs, leading to their prohibition in some places, unless enclosed by the luminaire. Those designed for 12- or 24-volt operation have compact filaments, useful for good optical control. Also, they have higher efficacies (lumens per watt) and longer lives than non-halogen types. The light output remains almost constant throughout their life.
Fluorescent Fluorescent lamps consist of a glass tube that contains mercury vapour or argon under low pressure. Electricity flowing through the tube causes the gases to give off ultraviolet energy. The inside of the tubes are coated with
phosphors that give off visible light when struck by ultraviolet
photons. They have much higher efficiency than incandescent lamps. For the same amount of light generated, they typically use around one-quarter to one-third the power of an incandescent. The typical
luminous efficacy of fluorescent lighting systems is 50–100 lumens per watt, several times the efficacy of incandescent bulbs with comparable light output. Fluorescent lamp fixtures are more costly than incandescent lamps, because they require a
ballast to regulate the
current through the lamp, but the lower energy cost typically offsets the higher initial cost.
Compact fluorescent lamps are available in the same popular sizes as incandescent lamps and are used as an
energy-saving alternative in homes. Because they contain mercury, many fluorescent lamps are classified as
hazardous waste. The
United States Environmental Protection Agency recommends that fluorescent lamps be segregated from general waste for
recycling or safe disposal, and some jurisdictions require recycling of them.
LED with E27
Edison screw base The solid-state
light-emitting diode (LED) has been popular as an indicator light in
consumer electronics and professional audio gear since the 1970s. In the 2000s, efficacy and output have risen to the point where LEDs are now being used in lighting applications such as car headlights and brake lights, and bicycle lights, as well as in decorative applications, such as holiday lighting. Indicator LEDs are known for their extremely long life, up to 100,000 hours, but lighting LEDs are operated much less conservatively, and consequently have shorter lives. LED technology is useful for
lighting designers, because of its low power consumption, low heat generation, instantaneous on/off control, and in the case of single color LEDs, continuity of color throughout the life of the diode and relatively low cost of manufacture. Operating an LED lamp in conditions that increase the internal temperature can greatly shorten the lamp's life. Some lasers have been adapted as an alternative to LEDs to provide highly focused illumination.
Carbon arc used in the
IMAX projection system arc lamp from a
fluorescence microscope Carbon arc lamps consist of two carbon rod
electrodes in open air, supplied by a current-limiting
ballast. The
electric arc is struck by touching the rod tips then separating them. The ensuing arc produces a white-hot
plasma between the rod tips. These lamps have higher efficacy than filament lamps, but the carbon rods are short-lived and require constant adjustment in use, as the intense heat of the arc erodes them. The lamps produce significant
ultraviolet output, they require ventilation when used indoors, and due to their intensity they need protection from direct sight. Invented by
Humphry Davy around 1805, the carbon arc was the first practical electric light. It was used commercially beginning in the 1870s for large building and street lighting until it was superseded in the early 20th century by the incandescent light. Carbon arc lamps operate at high power and produce high intensity white light. They also are a point source of light. They remained in use in limited applications that required these properties, such as
movie projectors,
stage lighting, and
searchlights, until after World War II.
Discharge A discharge lamp has a glass or silica envelope containing two metal
electrodes separated by a gas. Gases used include,
neon,
argon,
xenon,
sodium,
metal halides, and
mercury. The core operating principle is much the same as the carbon arc lamp, but the term "arc lamp" normally refers to carbon arc lamps, with more modern types of gas discharge lamp normally called discharge lamps. With some discharge lamps, very high voltage is used to strike the arc. This requires an electrical circuit called an igniter, which is part of the
electrical ballast circuitry. After the arc is struck, the internal resistance of the lamp drops to a low level, and the ballast limits the current to the operating current. Without a ballast, excess current would flow, causing rapid destruction of the lamp. Some lamp types contain a small amount of neon, which permits striking at normal running voltage with no external ignition circuitry.
Low-pressure sodium lamps operate this way. The simplest ballasts are just an inductor, and are chosen where cost is the deciding factor, such as street lighting. More advanced electronic ballasts may be designed to maintain constant light output over the life of the lamp, may drive the lamp with a square wave to maintain completely flicker-free output, and shut down in the event of certain faults. The most efficient source of electric light is the low-pressure sodium lamp. It produces, for all practical purposes, a
monochromatic orange-yellow light, which gives a similarly monochromatic perception of any illuminated scene. For this reason, it is generally reserved for outdoor public lighting applications. Low-pressure sodium lights are favoured for public lighting by astronomers, since the
light pollution that they generate can be easily filtered, contrary to broadband or continuous spectra. == Characteristics ==