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s, bottom, two regular tubes. Matchstick shown for scale.]] A fluorescent lamp is a Gas-discharge Lamp that uses Electricity to excite Mercury Vapor in Argon or Neon gas, resulting in a Plasma that produces short-wave Ultraviolet light. This light then causes a Phosphor to Fluoresce , producing Visible Light . Unlike Incandescent Lamp s, fluorescent lamps always require a Ballast to regulate the flow of power through the lamp. In common tube fixtures (typically 4 ft (120 cm) or 8 ft (240 cm) in length), the ballast is enclosed in the fixture. Compact Fluorescent Light Bulb s may have a conventional ballast located in the fixture or they may have ballasts integrated in the bulbs, allowing them to be used in lampholders normally used for incandescent lamps. LIES! The earliest ancestor of the fluorescent lamp is probably the device by Heinrich Geissler who, in 1856, obtained a bluish glow from a gas which was sealed in a tube and excited with an Induction Coil . At the 1893 World's Fair , the World Columbian Exposition in Chicago , Illinois displayed Nikola Tesla 's fluorescent lights. In 1894, D. McFarlane Moore created the Moore lamp, a commercial Gas Discharge Lamp meant to compete with the Incandescent Light Bulb of his former boss Thomas Edison . The gases used were Nitrogen and Carbon Dioxide emitting respectively pink and white light, and had moderate success. In 1901, Peter Cooper Hewitt demonstrated the mercury-vapor lamp, which emitted light of a blue-green color, and thus was unfit for most practical purposes. It was, however, very close to the modern design, and had much higher efficiency than incandescent lamps. In 1926, Edmund Germer and coworkers proposed to increase the operating pressure within the tube and to coat the tube with Fluorescent Powder which converts Ultraviolet light emitted by an excited plasma into more uniformly white-colored light. Germer is today recognized as the inventor of the fluorescent lamp. General Electric later bought Germer's patent and under the direction of George E. Inman brought the fluorescent lamp to wide commercial use by 1938. PRINCIPLES OF OPERATION The main principle of fluorescent tube operation is based around Inelastic Scattering of electrons. An incident electron (emitted from the coils of wire forming the Cathode electrode) collides with an atom in the gas (such as mercury, argon or krypton) used as the ultraviolet emitter. This causes an electron in the atom to temporarily jump up to a higher Energy Level to absorb some, or all, of the Kinetic Energy delivered by the colliding electron. This is why the collision is called 'inelastic' as some of the energy is absorbed. This higher energy state is unstable, and the atom will emit an ultraviolet Photon as the atom's electron reverts to a lower, more stable, energy level. The photons that are released from the chosen gas mixtures tend to have a wavelength in the ultraviolet part of the spectrum. This is not visible to the human eye, so must be converted into visible light. This is done by making use of Fluorescence . This fluorescent conversion occurs in the phosphor coating on the inner surface of the fluorescent tube, where the ultraviolet photons are absorbed by electrons in the phosphor's atoms, causing a similar energy jump, then drop, with emission of a further photon. The photon that is emitted from this second interaction has a lower energy than the one that caused it. The chemicals that make up the phosphor are specially chosen so that these emitted photons are at wavelengths visible to the human eye. The difference in energy between the absorbed ultra-violet photon and the emitted visible light photon goes to heat up the phosphor coating. Mechanism of light production (an essentially-similar design that uses no fluorescent phosphor, allowing the electrodes to be seen.)]] is produced by a low pressure mercury vapor discharge (identical to that in a fluorescent lamp) in an uncoated fused quartz envelope.]] A fluorescent lamp is filled with a Gas containing low pressure mercury vapor and Argon (or Xenon ), or more rarely argon- Neon , or sometimes even Krypton . The inner surface of the bulb is coated with a Fluorescent (and often slightly Phosphorescent ) coating made of varying blends of Metal lic and Rare-earth Phosphor Salt s. The bulb's cathode is typically made of coiled Tungsten which is coated with a mixture of barium, strontium and calcium oxides (chosen to have a relatively low Thermionic Emission temperature). When the light is turned on, the electric power heats up the cathode enough for it to emit electrons. These electrons collide with and ionize Noble Gas atoms in the bulb surrounding the filament to form a Plasma by a process of Impact Ionization . As a result of ) to emit Visible Light . The blend of phosphors controls the Color of the light, and along with the bulb's Glass prevents the harmful UV light from escaping. Electrical aspects of operation Fluorescent lamps are Negative Resistance devices, so as more current flows through them (more gas ionized), the electrical resistance of the fluorescent lamp drops, allowing even more current to flow. Connected directly to a constant- Voltage mains power line, a fluorescent lamp would rapidly self-destruct due to the uncontrolled current flow. To prevent this, fluorescent lamps must use an auxiliary device, commonly called a Ballast , to regulate the current flow through the tube. While the ballast could be (and occasionally is) as simple as a Resistor , substantial power is wasted in a resistive ballast so ballasts usually use a Reactance ( Inductor or Capacitor ) instead. For operation from AC mains voltage, the use of simple inductor (a so-called " Magnetic Ballast ") is common. In countries that use 120 V AC mains, the mains voltage is insufficient to light large fluorescent lamps so the ballast for these larger fluorescent lamps is often a step-up Autotransformer with substantial Leakage Inductance (so as to limit the current flow). Either form of inductive ballast may also include a Capacitor for Power Factor Correction . In the past, fluorescent lamps were occasionally run directly from a DC supply of sufficient voltage to strike an arc. In this case, there was no question that the ballast must have been resistive rather than reactive, leading to power losses in the ballast resistor. Also, when operated directly from DC, the polarity of the supply to the lamp must be reversed every time the lamp is started; otherwise, the mercury accumulates at one end of the tube. Nowadays, fluorescent lamps are essentially never operated directly from DC; instead, an inverter converts the DC into AC and provides the current-limiting function as described below for electronic ballasts. More sophisticated ballasts may employ Transistor s or other Semiconductor components to convert mains voltage into high- Frequency AC while also regulating the current flow in the lamp. These are referred to as " Electronic ballasts". Flicker Fluorescent lamps which operate directly from mains frequency AC will flicker at twice the mains frequency, since the power being delivered to the lamp drops to zero twice per cycle. This means the light flickers at 120 times per second (Hz) in countries which use 60-cycle-per-second (60 Hz) AC, and 100 times per second in those which use 50 Hz. This same principle can also cause hum from fluorescent lamps, actually from its ballast. Both the annoying hum and flicker are eliminated in lamps which use a high-frequency electronic ballast, such as the increasingly popular Compact Fluorescent Bulb . In some circumstances, fluorescent lamps operated at mains frequency can also produce flicker at the mains frequency (50 or 60 Hz) itself, which is noticeable by more people. This can happen in the last few hours of tube life when the cathode emission coating at one end is almost run out, and that Cathode starts having difficulty emitting enough Electron s into the gas fill, resulting in slight Rectification and hence uneven light output in positive and negative going mains cycles. Mains frequency flicker can also sometimes be emitted from the very ends of the tubes, as a result of each tube electrode alternately operating as an Anode and Cathode each half mains cycle, and producing slightly different light output pattern in anode or cathode mode. (This was a more serious issue with tubes over 40 years ago, and many fittings of that era shielded the tube ends from view as a result.) Flicker at mains frequency is more noticeable in the Peripheral Vision than it is in the center of gaze. Efficiency The efficiency of fluorescent tubes ranges from about 16 lumens/watt for a 4 watt tube with an ordinary ballast to as high as about 95 lumens/watt for a 32 watt tube with modern electronic ballast, commonly averaging 50 to 67 lm/W overall. Most compact fluorescents 13 watts or more with integral electronic ballasts achieve about 60 lumens/watt. Due to phosphor degradation as they age, the average brightness over the entire service life is actually about 10% less. {Link without Title} Method of 'starting' a fluorescent lamp The mercury atoms in the fluorescent tube must be ionized before the arc can "strike" within the tube. For small lamps, it does not take much voltage to strike the arc and starting the lamp presents no problem, but larger tubes require a substantial voltage (in the range of a thousand volts). In some cases, that is exactly how it is done: ''instant start'' fluorescent tubes simply use a high enough voltage to break down the gas and mercury column and thereby start arc conduction. These tubes can be identified by the facts that # they have a single pin at each end of the tube and # the lampholders that they fit into have a "disconnect" socket at the low-voltage end to ensure that the mains current is automatically removed so that a person replacing the lamp cannot receive a high-voltage Electric Shock . In other cases, a separate starting aid must be provided. Some fluorescent designs (''preheat lamps'') use a combination Filament / Cathode at each end of the lamp in conjunction with a mechanical or automatic switch (see photo) that initially connect the filaments in series with the ballast and thereby preheats the filaments prior to striking the arc. These systems are standard equipment in 240 V countries, and generally use a glowstarter. Before the 1960s, four-pin thermal starters and manual switches were also used. Electronic starters are also sometimes used with these electromagnetic ballast fittings. During preheating, the filaments emit electrons into the gas column by Thermionic Emission , creating a Glow Discharge around the filaments. Then, when the starting switch opens, the inductive ballast and a small value capacitor across the starting switch create a high voltage which strikes the arc. Tube strike is reliable in these systems, but glowstarters will often cycle a few times before letting the tube stay lit, which causes objectionable flashing during starting. The older thermal starters behaved better in this respect. Once the tube is struck, the impinging main discharge then keeps the filament/cathode hot, permitting continued emission. If the tube fails to strike, or strikes then extinguishes, the starting sequence is repeated. With automated starters such as glowstarters, a failing tube will thus cycle endlessly, flashing time and time again as the starter repeatedly starts the worn-out lamp, and the lamp then quickly goes out as emission is insufficient to keep the cathodes hot, and lamp current is too low to keep the glowstarter open. This causes visually unpleasant frequent bright flashing, and runs the ballast at above design temperature. Turning the glowstarter a quarter turn anticlockwise will disconnect it, opening the circuit. Some more advanced starters time out in this situation, and do not attempt repeated starts until power is reset. Some older systems used a thermal overcurrent trip to detect repeated starting attempts. These require manual reset. Newer ''rapid start'' ballast designs provide filament power windings within the ballast; these rapidly and continuously warm the filaments/cathodes using low-voltage AC. No inductive voltage spike is produced for starting, so the lamps must usually be mounted near a grounded (earthed) reflector to allow the glow discharge to propagate through the tube and initiate the arc discharge. Electronic ballasts often revert to a style in-between the preheat and rapid-start styles: a capacitor (or sometimes an autodisconnecting circuit) may complete the circuit between the two filaments, providing filament preheating. When the tube lights, the voltage and frequency across the tube and capacitor typically both drop, thus capacitor current falls to a low but non-zero value. Generally this capacitor and the inductor, which provides current limiting in normal operation, form a Resonant circuit, increasing the voltage across the lamp so it can easily start. Some electronic ballasts use programmed start. The output AC Frequency is started above the resonance frequency of the output circuit of the ballast; and after the filaments are heated, the frequency is rapidly decreased. If the frequency approaches the Resonant Frequency of the ballast, the output voltage will increase so much that the lamp will ignite. If the lamp does not ignite, an electronic circuit stops the operation of the ballast. Mechanisms of lamp failure at end of life The end of life failure mode for fluorescent lamps varies depending how you use them and their control gear type. There are three main failure modes currently, and a fourth which is starting to appear: Emission mix runs out , Strontium and Calcium oxides, the coating is sputtered away through normal use, often eventually resulting in lamp failure.]] The "emission mix" on the tube filaments/cathodes is necessary to enable electrons to pass into the gas via Thermionic Emission at the tube operating voltages used. The mix is slowly sputtered off by bombardment with electrons and mercury ions during operation, but a larger amount is sputtered off each time the tube is started with cold cathodes. (The method of starting the lamp and hence the control gear type has a significant impact on this.) Lamps operated for typically less than 3 hours each switch-on will normally run out of the emission mix before other parts of the lamp fail. The sputtered emission mix forms the dark marks at the tube ends seen in old tubes. When all the emission mix is gone, the cathode cannot pass sufficient electrons into the gas fill to maintain the discharge at the designed tube operating voltage. Ideally, the control gear should shut down the tube when this happens. However, some control gear will provide sufficient increased voltage to continue operating the tube in Cold Cathode mode, which will cause overheating of the tube end and rapid disintegration of the electrodes and their support wires until they are completely gone or the glass cracks, wrecking the low pressure gas fill and stopping the gas discharge. Failure of integral ballast electronics This is only relevant to Compact Fluorescent Lamp s with integral Electrical Ballast s. Ballast electronics failure is a somewhat random process which follows the standard failure profile for any electronic devices. Integral electronic ballasts suffer from shortened lifespans in high humidity applications. There is an initial small peak of early failures, followed by a drop and steady increase over lamp life. Life of electronics is heavily dependent on operating temperature—it typically halves for each 10 C temperature rise. The quoted average life of a lamp is usually at 25 C ambient (this may vary by country). The average life of the electronics at this temperature is normally greater than this, so at this temperature, not many lamps will fail due to failure of the electronics. In some fittings, the ambient temperature could be well above this, in which case failure of the electronics may become the predominant failure mechanism. Similarly, running a compact fluorescent lamp base-up will result in hotter electronics and shorter average life (particularly with higher power rated ones). Electronic ballasts should be designed to shut down the tube when the emission mix runs out as described above. In the case of integral electronic ballasts, since they never have to work again, this is sometimes done by having them deliberately burn out some component to permanently cease operation. Failure of the phosphor The phosphor drops off in efficiency during use. By around 25,000 operating hours, it will typically be half the brightness of a new lamp (although some manufacturers claim much longer half-lives for their lamps). Lamps which do not suffer failures of the emission mix or integral ballast electronics will eventually develop this failure mode. They still work, but have become dim and inefficient. The process is slow, and often only becomes obvious when a new lamp is operating next to an old lamp. Tube runs out of mercury Mercury is lost from the gas fill throughout the lamp life, as it is slowly absorbed into glass, phosphor, and tube electrodes, where it can no longer function. Historically this hasn't been a problem because tubes have had an excess of mercury. However, environmental concerns are now resulting in low mercury content tubes which are much more accurately dosed with just enough mercury to last the expected life of the lamp. This means that loss of mercury will take over from failure of the phosphor in some lamps. The failure symptom is similar, except loss of mercury initially causes an extended run-up time (time to reach full light output), and finally causes the lamp to glow a dim pink when the mercury runs out and the argon base gas takes over as the primary discharge. Phosphors and the spectrum of emitted light Some people find the Color Spectrum produced by some fluorescent lamps to be harsh and displeasing. A healthy person can sometimes appear to have an unhealthy skin tone under fluorescent lighting. The extent to which this phenomenon occurs is related to the light's Color Rendering Index (CRI). CRI is a measure of how well balanced the different color components of the white light are. By definition, an incandescent lamp has a CRI of 100. Real life fluorescent tubes achieve CRIs of anywhere from 50% to 99%. Fluorescent lamps with low CRI have phosphors which emit too little red light. Skin appears less pink and unhealthy compared to incandescent lighting. Colored objects appear muted. For example a low CRI 6800K halophosphate tube, which is about as visually unpleasant as they get, will make reds appear dull red or brown. CCT Color Temperature is a measure of the whiteness of a light source. Typical incandescent lighting is 2700K which is yellowish-white. Halogen lighting is 3000K. Fluorescent lamps are manufactured to a chosen CCT by altering the mixture of phosphors inside the tube. Warm-white fluorescents have CCT of 2700K and are popular for residential lighting. Neutral-white fluorescents have a CCT of 3000K or 3500K. Cool-white fluorescents have a CCT of 4100K and are popular for office lighting. Daylight fluorescents have a CCT of 5000K to 6500K, which is bluish-white. High CCT lighting generally requires higher light levels. At dimmer illumination levels, the human eye perceives lower color temperatures as more natural. So, a dim 2700K incandescent lamp appears natural, and a bright 5000K lamp also appears natural, but a dim 5000K fluorescent lamp appears too pale. Daylight-type fluorescents look natural only if they are very bright. Some of the least pleasant light comes from tubes containing the older 3+, Mn 2+). The bad color reproduction is due to the fact that this phosphor mainly emits yellow and blue light, and relatively little green and red. To the eye, this mixture appears white, but the light has an incomplete Spectrum . The CRI of such lamps is only 60. Since the 1990s, higher quality fluorescent lamps use either a higher CRI halophosphate coating, or a ''triphosphor'' mixture, based on Europium and Terbium ions, that have emission bands more evenly distributed over the spectrum of visible light. High CRI halophosphate and triphosphor tubes give a more natural color reproduction to the human eye. The CRI of such lamps is typically 82-100. USAGE Fluorescent light bulbs come in many shapes and sizes. An increasingly popular one is the Compact Fluorescent Light Bulb (CF). Many compact fluorescent lamps integrate the auxiliary electronics into the base of the lamp, allowing them to fit into a regular light bulb socket. In the US, Residential use of fluorescent lighting remains low (generally limited to Kitchen s, Basement s, Hall ways and other areas), but School s and Business es find the cost savings of fluorescents to be significant and only rarely use incandescent lights. Lighting arrangements often use fluorescent tubes in an assortment of tints of white. Sometimes this is done due to failure to appreciate the difference or importance of differing tube types. Mixing tube types within fittings is also sometimes done to improve the color reproduction of lower quality tubes. Use is substantially higher and increasing in places such as California , where tax incentives exist, and environmental awareness are relatively high. In other countries, residential use of fluorescent lighting varies depending on the price of energy, financial and environmental concerns of the local population, and acceptability of the light output. In East and Southeast Asia it is very rare to see Incandescent bulbs in buildings anywhere. In February 2007, Australia enacted a law that will ban most sales of incandescent light bulbs by 2010 [http://www.environment.gov.au/minister/env/2007/pubs/mr20feb07.pdf . While the law does not specify which alternative Australians are to use, compact fluorescents are likely to be the primary replacements. In April 2007, Canada announced a similar plan to phase out the sale of incandescent bulbs by 2012.[http://www.canada.com/calgaryherald/news/story.html?id=174b0c15-7fa6-426e-9460-b6f4de5b35c4&k=84333&p=1]. MERCURY TOXICITY Because fluorescent lamps contain Mercury , a Toxic Heavy Metal , governmental regulations in many areas require special disposal of fluorescent lamps, separate from general and household wastes. Mercury poses the greatest hazard to pregnant women, infants, and children. Landfills often refuse fluorescent lamps due to their high mercury content. Households and commercial waste sources are often treated differently. The amount of mercury in a standard lamp can vary dramatically, from 3 to 46 mg. Page 183 of http://www.chem.unep.ch/MERCURY/Toolkit/UNEP-final-pilot-draft-toolkit-Dec05.pdf Newer lamps contain less mercury and the 3-4 mg versions are sold as low-mercury types. (A typical 2006-era 4 ft (120 cm) T-12 fluorescent lamp (i.e., F32T12) contains about 12 Milligrams of mercuryhttp://lightingdesignlab.com/articles/mercury_in_fl/mercurycfl.htm.) In early 2007, the National Electrical Manufacturers Association in the US announced that "Under the voluntary commitment, effective April 15, 2007, participating manufacturers will cap the total mercury content in CFLs under 25 watts at 5 milligrams (mg) per unit. CFLs that use 25 to 40 watts of electricity will have total mercury content capped at 6 mg per unit." NEMA Voluntary Commitment on Mercury in CFLs CLEANUP OF BROKEN FLUORESCENT LAMPS A broken fluorescent tube is more hazardous than a broken conventional incandescent bulb due to the mercury content. Because of this, the safe cleanup of broken fluorescent bulbs differs from cleanup of conventional broken glass or incandescent bulbs. 99% of the mercury is typically contained in the phosphor, especially on lamps that are near their end of life Floyd, et al. (2002), quoted on page 184 of Toolkit for identification and quantification of mercury releases ( PDF ). Therefore, a typical safe cleanup usually involves first opening a window and then leaving the room (restricting access) for at least 15 minutes, wearing gloves carefully dispose of any broken glass, as well as any loose white powder (fluorescent glass coating) you can use sticky tape to pick up small pieces... double bag any waste. Dispose of waste in accordance with local hazardous waste laws. Finally a wet paper towel should be used instead of a vacuum cleaner for cleanup of glass and powder, to reduce the vaporization of the mercury into the air. The first time you vacuum the area where the bulb was broken, remove the vacuum bag once done cleaning the area (or empty and wipe the canister) and put the bag and/or vacuum debris, as well as the cleaning materials, in two sealed plastic bags in the outdoor trash or protected outdoor location for normal disposal {Link without Title} What to Do if a Fluorescent Light Bulb Breaks ADVANTAGES OVER INCANDESCENT LAMPS Fluorescent lamps are more Efficient than Incandescent Light Bulb s of an equivalent brightness. This is because a greater proportion of the power used is converted to usable Light and a smaller proportion is converted to Heat , allowing fluorescent lamps to run cooler. A typical 100 Watt tungsten filament incandescent lamp may convert only 2.6% of its power input to visible light, whereas typical fluorescent lamps convert between 6.6% and 15.2% of their power input to visible light - see the table in the Luminous Efficacy article. Typically a fluorescent lamp will last between 10 to 20 times as long as an equivalent incandescent lamp. The higher initial cost of a fluorescent lamp is usually more than compensated for by lower energy consumption over its life. The longer life may also reduce lamp replacement costs, providing additional saving especially where labour is costly. Therefore it is widely used by businesses worldwide, but not so much by households. DISADVANTAGES Ultraviolet light Fluorescent lamps can cause problems among individuals with pathological sensitivity to ultraviolet light. They can induce disease activity in photosensitive individuals with Systemic Lupus Erythematosus ; standard acrylic diffusers absorb UV-B radiation and appear to protect against this.1 In rare cases individuals with solar Urticaria (allergy to sunlight) can get a rash from fluorescent lighting.2 Ballasts Fluorescent lamps require a ballast to stabilize the lamp and to provide the initial striking voltage required to start the arc discharge. This increases the cost of fluorescent Luminaire s, though often one ballast is shared between two or more lamps. Electromagnetic ballasts with a minor fault can produce an audible humming or buzzing noise. Conventional lamp ballasts do not operate on direct current. If a direct current supply with a high enough voltage to strike the arc is available, a resistor can be used to ballast the lamp but this leads to low efficiency because of the power lost in the resistor. Also, the mercury tends to migrate to one end of the tube leading to only one end of the lamp producing most of the light. Because of this effect, the lamps (or the polarity of the current) must be reversed at regular intervals. Power factor Fluorescent lamp ballasts have a Power Factor of less than unity. For large installations, this makes the provision of electrical power more expensive as special measures need to be taken to bring the power factor closer to unity. Power harmonics Fluorescent lamps are a non-linear load and generate harmonics on the 50 Hz or 60 Hz sinusoidal waveform of electrical power supply. This can generate radio frequency noise in some cases. Suppression of generation of harmonics is standard practice, but imperfect. Very good suppression is possible, but adds to the cost of the fluorescent fixtures. The result can be interference with some radio reception bands in some cases. Optimum operating temperature Fluorescent lamps operate best around room temperature (say, 20 °C or 68 °F). At much lower or higher temperatures, efficiency decreases and at low temperatures (below freezing) standard lamps may not start. Special lamps may be needed for reliable service outdoors in cold weather. A "cold start" electrical circuit was also developed in the mid-1970s. Non-compact light source Because the arc is quite long relative to higher-pressure discharge lamps, the amount of light emitted per unit of surface of the lamps is low, so tube lamps were large compared with incandescent sources. However, in many cases low luminous intensity of the emitting surface was useful because it reduced Glare . The bulk created by this lamp affected the design of fixtures since light must be directed from long tubes instead of a compact source. Recently, a new type of fluorescent lamp, the CFL has been introduced to address this issue and allow regular incandescent sockets to be fitted with this type of lamp, thereby negating the need to mount it on special fixtures. Flicker problems Fluorescent fittings using a magnetic mains frequency ballast do not give out a steady light; instead, they flicker (fluctuate in intensity) at twice the supply frequency. While this is not easily discernible by the human eye, it can cause a Strobe Effect posing a safety hazard in a workshop for example, where something spinning at just the right speed may appear stationary if illuminated solely by a fluorescent lamp. It also causes problems for video recording as there can be a 'beat effect' between the periodic reading of a camera's sensor and the fluctuations in intensity of the fluorescent lamp. Incandescent Lamp s, due to the Thermal Inertia of their element, fluctuate to a lesser extent. This is also less of a problem with compact fluorescents, since they multiply the line frequency to levels that are not visible. Installations can reduce the Stroboscope effect by using lead-lag ballasts, by operating the lamps on different phases of a Polyphase power supply, or by use of electronic ballasts. Electronic ballasts do not produce light flicker, since the phosphor persistence is longer than a half cycle of the higher operation frequency. The non-visible 100–120 Hz flicker from fluorescent tubes powered by magnetic ballasts is associated with headaches and eyestrain. Individuals with high Flicker Fusion Threshold are particularly affected by magnetic ballasts: their EEG alpha waves are markedly attenuated and they perform office tasks with greater speed and decreased accuracy. The problems are not observed with electronic ballasts.3 Ordinary people have better reading performance using high-frequency (20–60 kHz) electronic ballasts than magnetic ballasts.4 The flicker of fluorescent lamps, even with magnetic ballasts, is so rapid that it is unlikely to present a hazard to individuals with Epilepsy .5 Early studies suspected a relationship between the flickering of fluorescent lamps with magnetic ballasts and Repetitive Movement in Autistic children.6 However, these studies had interpretive problems7 and have not been replicated. Color rendition The issues with color faithfulness of some tube types are discussed above. Dimming Unless specifically designed and approved to accommodate dimming, most fluorescent light fixtures cannot be connected to a standard Dimmer switch used for incandescent lamps. Two effects are responsible for this: the waveshape of the voltage emitted by a standard phase-control dimmer interacts badly with many ballasts and it becomes difficult to sustain an arc in the fluorescent tube at low power levels. Many installations require 4-pin fluorescent lamps and compatible controllers for successful fluorescent dimming; these systems tend to keep the cathodes of the fluorescent tube fully heated even as the arc current is reduced, promoting easy thermionic emission of electrons into the arc stream. Disposal and recycling The disposal of phosphor and particularly the Mercury in the tubes is an environmental issue. (Incandescent lamps do not contain mercury.) For large commercial or industrial users of fluorescent lights, recycling services are available in many nations, and may be required by regulation. In some areas, recycling is also available to consumers. The need for a recycling infrastructure is an issue with instituting proposed bans of incandescent bulbs. TUBE DESIGNATIONS ''Note: the information in this section might be inapplicable outside of North America .'' Lamps are typically Identified by a Code such as F##T##, where F is for fluorescent, the first number indicates the power in watts (or strangely, length in Inch es in very long lamps), the T indicates that the shape of the bulb is Tubular , and the last number is Diameter in eighths of an inch. Typical diameters are T12 (1½" or 38 Mm ) for residential bulbs with old Magnet ic Ballast s, T8 (1" or 25 mm) for commercial energy-saving lamps with electronic ballasts, and T5 (5⁄8" or 16 mm) for very small lamps which may even operate from a Battery - Power ed Device . Slimline lamps operate on an Instant Start ballast and are recognizable by their single-pin bases. High- Output lamps are brighter and draw more Electrical Current , have different ends on the Pin s so they cannot be used in the wrong Fixture , and are labeled F##T12HO, or F##T12VHO for very high output. Since about the early to mid 1950s to today, General Electric developed and improved the Power Groove(R) lamp with the label F##PG17. These lamps are recognisable by their large diameter, grooved tubes. U-shaped tubes are FB##T##, with the B meaning "bent". Most commonly, these have the same designations as linear tubes. Circular bulbs are FC##T#, with the ''diameter'' of the circle (''not'' Circumference or watts) being the first number, and the second number usually being 9 (29 mm) for standard fixtures. Color is usually indicated by WW for warm white, EW for enhanced (neutral) white, CW for cool white (the most common), and DW for the bluish Daylight white. BL is used for Blacklight lamps commonly used in Bug Zapper s. BLB is used for blacklight-blue lamps commonly used in nightclubs. Other non-standard designations apply for Plant Light s or Grow Light s. Philips uses numeric color codes for the colors:
Odd lengths are usually added after the color. One example is an F25T12/CW/33, meaning 25 watts, 1.5" diameter, cool white, 33" or 84 cm long. Without the 33, it would be assumed that an F25T12 is the more-common 30" long. Compact fluorescents do not have such a designation system. OTHER FLUORESCENT LAMPS ; Blacklight s :Blacklights are a subset of fluorescent lamps that are used to provide long-wave Ultraviolet light (at about 360nm wavelength). They are built in the same fashion as conventional fluorescent lamps but the glass tube is coated with a phosphor that converts the short-wave UV within the tube to long-wave UV rather than to visible light. They are used to provoke Fluorescence (to provide dramatic effects using Blacklight Paint and to detect materials such as Urine and certain Dye s that would be invisible in visible light) as well as to attract Insect s to Bug Zapper s. :So-called '' Blacklite Blue '' lamps are also made from more expensive deep purple glass known as Wood's Glass rather than clear glass. The deep purple glass filters out most of the visible colors of light directly emitted by the mercury-vapor discharge, producing proportionally less visible light compared with UV light. This allows UV-induced fluorescence to be seen more easily (thereby allowing ''blacklight posters'' to seem much more dramatic). The blacklight lamps used in Bug Zapper s do not require this refinement so it is usually omitted in the interest of cost; they are called simply '' Blacklite '' (and not blacklite blue). ; Sun Lamp s :Sun lamps contain a different phosphor that emits more strongly in medium-wave UV, provoking a Tanning response in most Human Skin . ; Grow Lamp s :Grow lamps contain a phosphor blend that encourages photosynthesis in plants; they usually appear pinkish to human eyes. ; Germicidal Lamp s :Germicidal lamps contain no phosphor at all (technically making them gas discharge lamps rather than fluorescent) and their tubes are made of Fused Quartz that is transparent to the short-wave UV directly emitted by the mercury discharge. The UV emitted by these tubes will kill germs, ionize Oxygen to Ozone , and cause eye and skin damage. Besides their uses to kill Germ s and create ozone, they are sometimes used by Geologist s to identify certain species of Mineral s by the color of their fluorescence. When used in this fashion, they are fitted with filters in the same way as blacklight-blue lamps are; the filter passes the short-wave UV and blocks the visible light produced by the mercury discharge. They are also used in EPROM erasers. ; Electrodeless Induction Lamp s :Electrodeless induction lamps are fluorescent lamps without internal electrodes. They have been commercially available since 1990 . A current is induced into the gas column using Electromagnetic Induction . Because the electrodes are usually the life-limiting element of fluorescent lamps, such electrodeless lamps can have a very long service life, although they also have a higher purchase price. ; Cold-cathode Fluorescent Lamp s (CCFL) :Cold-cathode fluorescent lamps are used as Backlighting for LCD Display s in personal computer and TV monitors. They are also popular with Case Modder s in recent years. SCIENCE DEMONSTRATIONS Fluorescent lamps can be illuminated by means other than a proper electrical connection. These other methods however result in very dim or very short-lived illumination, and so are seen mostly in science demonstrations. With the exception of static electricity, these methods can be very dangerous if done improperly:
FILM AND VIDEO USE Special fluorescent lights are often used in film/video production. The brand name Kino Flos are used to create softer fill light and are less hot than traditional halogen light sources. These fluorescent lights are designed with special high-frequency ballasts to prevent video flickering and high color-rendition index bulbs to approximate daylight color temperatures. SEE ALSO REFERENCES EXTERNAL LINKS
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