Lightning: Difference between revisions

Not to be confused with lighting. For information on lightning precautions, see Lightning safety. For other uses, see Lightning (disambiguation).

Lightning over Oradea in Romania

Lightning over Zwickau in Germany

Lightning is an atmospheric discharge of electricity, which typically occurs during thunderstorms, and sometimes during volcanic eruptions or dust storms.^[1] The leader of a bolt of lightning can travel at speeds of 60,000 m/s, and can reach temperatures approaching 30,000 °C (54,000 °F), hot enough to fuse soil or sand into glass channels.^[2][3] There are over 16 million lightning storms every year.^[1]

Lightning can also occur within the ash clouds from volcanic eruptions, or can be caused by violent forest fires which generate sufficient dust to create a static charge.^[1][4]

How lightning initially forms is still a matter of debate:^[5] Scientists have studied root causes ranging from atmospheric perturbations (wind, humidity, and atmospheric pressure) to the impact of solar wind and accumulation of charged solar particles.^[6] Ice inside a cloud is thought to be a key element in lightning development, and may cause a forcible separation of positive and negative charges within the cloud, thus assisting in the formation of lightning.^[6]

NIGGERS LIVE IN NIGER

Properties of lightning

World map showing frequency of lightning strikes, in flashes per km² per year. Lightning strikes most frequently in the Democratic Republic of the Congo.

An average bolt of lightning carries a negative electric current of 40 kiloamperes (kA) (although some bolts can be up to 120 kA), and transfers a charge of five coulombs and 500 MJ, or enough energy to power a 100 watt lightbulb for just under two months. The voltage depends on the length of the bolt, with the dielectric breakdown of air being three million volts per meter; this works out to approximately one gigavolt (one billion volts) for a 300 m (1000 ft) lightning bolt. With an electric current of 100 kA, this gives a power of 100 terawatts.

Lightning heats nearby air to about 10,000 °C (18,000 °F) nearly instantly, which is almost twice the temperature of the Sun’s surface. The heating creates a shock wave that is heard as thunder.^[7]

The return stroke of a lightning bolt follows a charge channel only about a centimeter (0.5-in) wide — no wider than a pencil. Most lightning bolts are about 1.6 kilometers (1 mi) long. The longest recorded length was 190 kilometers (118 mi), sighted near Dallas, Texas.^[8]

Different locations have different potentials (voltages) and currents for an average lightning strike. For example, Florida, with the United States' largest number of recorded strikes in a given period during the summer season, has very sandy ground in some areas and conductive saturated mucky soil in others. As much of Florida lies on a peninsula, it is bordered by the ocean on three sides. The result is the daily development of sea and lake breeze boundaries that collide and produce thunderstorms. Arizona, which has very dry, sandy soil and a very dry air, has cloud bases as high as 1800-2100 m (6,000-7,000 ft) above ground level, and gets very long and thin purplish discharges which crackle; while Oklahoma, with cloud bases about 450-600 m (1,500-2,000 ft) above ground level and fairly soft, clay-rich soil, has big, blue-white explosive lightning strikes that are very hot (high current) and cause sudden, explosive noise when the discharge comes. The difference in each case may consist of differences in voltage levels between clouds and ground. Research on this is still ongoing.^{[citation needed]}

NASA scientists have found the radio waves created by lightning clear a safe zone in the radiation belt surrounding the earth. This zone, known as the Van Allen Belt slot, can potentially be a safe haven for satellites, offering them protection from the Sun's radiation.^[9][10][11]

Formation

Note

Positive lightning (a rarer form of lightning that originates from positively charged regions of the thundercloud) does not generally fit the following pattern.

Charge separation

The first process in the generation of lightning is charge separation.

Polarization mechanism theory

The mechanism by which charge separation happens is still the subject of research, but one theory is the polarization mechanism, which has two components:^[12]

1. Falling droplets of ice and rain become electrically polarized as they fall through the atmosphere's natural electric field;
2. Colliding ice particles become charged by electrostatic induction.

Ice and supercooled water are the keys to the process. Violent winds buffet tiny hailstones as they form, causing them to collide. When the hailstones hit ice crystals, some negative ions transfer from one particle to another. The smaller particles lose negative ions and become positive and the larger more massive particles gain negative ions and become negative.^[13]

Electrostatic induction theory

Another theory is that opposite charges are driven apart by the above mechanism and energy is stored in the electric field between them. Cloud electrification appears to require strong updrafts which carry water droplets upward, supercooling them to -10 to -20 °C. These collide with ice crystals to form a soft ice-water mixture called graupel. The collisions result in a slight positive charge being transferred to ice crystals, and a slight negative charge to the graupel. Updrafts drive lighter ice crystals upwards, causing the cloud top to accumulate increasing positive charge. The heavier negatively charged graupel falls towards the middle and lower portions of the cloud, building up an increasing negative charge. Charge separation and accumulation continue until the electrical potential becomes sufficient to initiate lightning discharges, which occurs when the gathering of positive and negative charges forms a sufficiently strong electric field.

There are several additional theories for the origin of charge separation.^[14]

Leader formation

As a thundercloud moves over the Earth's surface, an equal but opposite charge is induced in the Earth below, and the induced ground charge follows the movement of the cloud.

An initial bipolar discharge, or path of ionized air, starts from a negatively charged mixed water and ice region in the thundercloud. The discharge ionized channels are called leaders. The negative charged leaders, called a "stepped leader", proceed generally downward in a number of quick jumps, each up to 50 meters long. Along the way, the stepped leader may branch into a number of paths as it continues to descend. The progression of stepped leaders takes a comparatively long time (hundreds of milliseconds) to approach the ground. This initial phase involves a relatively small electric current (tens or hundreds of amperes), and the leader is almost invisible compared to the subsequent lightning channel.

When a stepped leader approaches the ground, the presence of opposite charges on the ground enhances the electric field. The electric field is highest on trees and tall buildings. If the electric field is strong enough, a conductive discharge (called a positive streamer) can develop from these points. This was first theorized by Heinz Kasemir. As the field increases, the positive streamer may evolve into a hotter, higher current leader which eventually connects to the descending stepped leader from the cloud. It is also possible for many streamers to develop from many different objects simultaneously, with only one connecting with the leader and forming the main discharge path. Photographs have been taken on which non-connected streamers are clearly visible. When the two leaders meet, the electric current greatly increases. The region of high current propagates back up the positive stepped leader into the cloud with a "return stroke" that is the most luminous part of the lightning discharge.

Discharge

Lightning sequence (Duration: 0.32 seconds)

When the electric field becomes strong enough, an electrical discharge (the bolt of lightning) occurs within clouds or between clouds and the ground. During the strike, successive portions of air become a conductive discharge channel as the electrons and positive ions of air molecules are pulled away from each other and forced to flow in opposite directions.

The electrical discharge rapidly superheats the discharge channel, causing the air to expand rapidly and produce a shock wave heard as thunder. The rolling and gradually dissipating rumble of thunder is caused by the time delay of sound coming from different portions of a long stroke.^[15]

Gurevich's cosmic ray theory

A theory proposed by Alex Gurevich of the Lebedev Physical Institute in 1992 suggests that lightning strikes are triggered by cosmic rays which ionize atoms, releasing electrons that are accelerated by the electric fields, ionizing other air molecules and making the air conductive by a runaway breakdown, then starting a lightning strike.^[16][17][18]

Gamma rays and the runaway breakdown theory

Double lightning

It has been discovered in the past 15 years that among the processes of lightning is some mechanism capable of generating gamma rays, which escape the atmosphere and are observed by orbiting spacecraft. Brought to light by NASA's Gerald Fishman in 1994 in an article in Nature, these so-called Terrestrial Gamma-Ray Flashes (TGFs) were observed by accident, while he was documenting instances of extraterrestrial gamma ray bursts observed by the Compton Gamma Ray Observatory (CGRO). TGFs are much shorter in duration, however, lasting only ~1 ms.

Professor Umran Inan of Stanford University linked a TGF to an individual lightning stroke occurring within 1.5 ms of the TGF event,^[19] proving for the first time that the TGF was of atmospheric origin and associated with lightning strikes.

CGRO recorded only about 77 events in 10 years; however, more recently the RHESSI spacecraft, as reported by David Smith of UC Santa Cruz, has been observing TGFs at a much higher rate, indicating that these occur ~50 times per day globally (still a very small fraction of the total lightning on the planet). The energy levels recorded exceed 20 MeV.

Scientists from Duke University have also been studying the link between certain lightning events and the mysterious gamma ray emissions that emanate from the Earth's own atmosphere, in light of newer observations of TGFs made by RHESSI. Their study suggests that this gamma radiation fountains upward from starting points at surprisingly low altitudes in thunderclouds.

Steven Cummer, from Duke University's Pratt School of Engineering, said, "These are higher energy gamma rays than come from the sun. And yet here they are coming from the kind of terrestrial thunderstorm that we see here all the time."

Early theories of this pointed to lightning generating high electric fields at altitudes well above the cloud, where the thin atmosphere allows gamma rays to easily escape into space, known as "relativistic runaway breakdown", similar to the way sprites are generated. Subsequent evidence has cast doubt, though, and suggested instead that TGFs may be produced at the tops of high thunderclouds. Though hindered by atmospheric absorption of the escaping gamma rays, these theories do not require the exceptionally high electric fields that high altitude theories of TGF generation rely on.

The role of TGFs and their relationship to lightning remains a subject of ongoing scientific study.

Re-strike

Lightning is a highly visible form of energy transfer.

High speed videos (examined frame-by frame) show that most lightning strikes are made up of multiple individual strokes. A typical strike is made of 3 to 4 strokes. There may be more.^[15]

Each re-strike is separated by a relatively large amount of time, typically 40 to 50 milliseconds. Re-strikes can cause a noticeable "strobe light" effect.^[15]

Each successive stroke is preceded by intermediate dart leader strokes akin to, but weaker than, the initial stepped leader. The stroke usually re-uses the discharge channel taken by the previous stroke.^{[citation needed]}

The variations in successive discharges are the result of smaller regions of charge within the cloud being depleted by successive strokes.^{[citation needed]}

The sound of thunder from a lightning strike is prolonged by successive strokes.

Types of lightning

Cloud-to-cloud lightning, Steinenbronn, Germany

Some lightning strikes take on particular characteristics; scientists and the public have given names to these various types of lightning. Most lightning is streak lightning. This is nothing more than the return stroke, the visible part of the lightning stroke. Because most of these strokes occur inside a cloud, we do not see many of the individual return strokes in a thunderstorm.

The return stroke of a lightning bolt, which is the visible bolt itself, follows a charge channel only about a half-inch (1.3 cm) wide. Most lightning bolts are about a mile (1.6 km) long.^[20]

Positive lightning

See also: High_voltage § Lightning

Positive lightning, also known colloquially as a "bolt from the blue" makes up less than 5% of all lightning.^[21] It occurs when the leader forms at the positively charged cloud tops, with the consequence that a negatively charged streamer issues from the ground. The overall effect is a discharge of positive charges to the ground. Research carried out after the discovery of positive lightning in the 1970s showed that positive lightning bolts are typically six to ten times more powerful than negative bolts, last around ten times longer, and can strike tens of kilometres/miles from the clouds.^{[citation needed]} The voltage difference for positive lightning must be considerably higher, due to the tens of thousands of additional metres/feet the strike must travel. During a positive lightning strike, huge quantities of ELF and VLF radio waves are generated.^[22]

As a result of their greater power, positive lightning strikes are considerably more dangerous. At the present time, aircraft are not designed to withstand such strikes, since their existence was unknown at the time standards were set, and the dangers unappreciated until the destruction of a glider in 1999.^[23]

Positive lightning is also now believed to have been responsible for the 1963 in-flight explosion and subsequent crash of Pan Am Flight 214, a Boeing 707.^{[citation needed]} Subsequently, aircraft operating in U.S. airspace have been required to have lightning discharge wicks to reduce the chances of a similar occurrence.

Positive lightning has also been shown to trigger the occurrence of upper atmosphere lightning. It tends to occur more frequently in winter storms and at the end of a thunderstorm.^[24]

An average bolt of positive lightning carries a current of up to 300 kA (kiloamperes) (about ten times as much current as a bolt of negative lightning), transfers a charge of up to 300 coulombs, has a potential difference up to 1 gigavolt (one billion volts), and lasts for hundreds of milliseconds, with a discharge energy of up to 300 GJ (gigajoules) (a billion joules).^{[citation needed]}

Anvil-to-ground

One special type of cloud-to-ground lightning is anvil-to-ground lightning. It is a form of positive lightning, since it emanates from the anvil top of a cumulonimbus cloud where the ice crystals are positively charged. The leader stroke issues forth in a nearly horizontal direction until it veers toward the ground. These usually occur kilometers/miles from (often ahead) of the main storm and will sometimes strike without warning on a sunny day. An anvil-to-ground lightning bolt is a sign of an approaching storm, and if one occurs in a largely clear sky, it is known colloquially as a "Bolt from the blue."^[25]

Cloud-to-cloud

Multiple paths of cloud-to-cloud lightning, Swifts Creek, Australia

Lightning discharges may occur between areas of cloud having different potentials without contacting the ground. These are most common between the anvil and lower reaches of a given thunderstorm. This lightning can sometimes be observed at great distances at night as so-called "heat lightning". In such instances, the observer may see only a flash of light without thunder. The "heat" portion of the term is a folk association between locally-experienced warmth and the distant lightning flashes.

Dry lightning

Dry lightning is a folk misnomer in common usage in the United States for thunderstorms which produce no precipitation at the surface. This type of lightning is the most common natural cause of wildland fires.

Rocket lightning

Rocket Lightning, Queanbeyan, Australia

It is a form of cloud discharge, generally horizontal and at cloud base, with a luminous channel appearing to advance through the air with visually resolvable speed, often intermittently.^[26]

The movement has been compared to that of a skyrocket, hence its name. It is also one of the rarest of cloud discharges.^[27]

Cloud-to-ground

Cloud-to-ground lightning is a great lightning discharge between a cumulonimbus cloud and the ground initiated by the downward-moving leader stroke. This is the second most common type of lightning, and poses the greatest threat to life and property of all known types.

Bead lightning

Bead lightning is a type of cloud-to-ground lightning which appears to break up into a string of short, bright sections, which last longer than the usual discharge channel. It is fairly rare. Several theories have been proposed to explain it; one is that the observer sees portions of the lightning channel end on, and that these portions appear especially bright. Another is that, in bead lightning, the width of the lightning channel varies; as the lightning channel cools and fades, the wider sections cool more slowly and remain visible longer, appearing as a string of beads.^[28][29]

Ribbon lightning

Ribbon lightning occurs in thunderstorms with high cross winds and multiple return strokes. The wind will blow each successive return stroke slightly to one side of the previous return stroke, causing a ribbon effect.

Staccato lightning

Staccato lightning is nothing more than a leader stroke with only one return stroke.

Ground-to-cloud lightning

Ground-to-cloud lightning is a lightning discharge between the ground and a cumulonimbus cloud from an upward-moving leader stroke.

Ball lightning

Main article: Ball lightning

Ball lightning is described as a floating, illuminated ball that occurs during thunderstorms. They can be fast moving, slow moving or nearly stationary. Some make hissing or crackling noises or no noise at all. Some have been known to pass through windows and even dissipate with a bang. Ball lightning has been described by eyewitnesses but rarely recorded by meteorologists.^[30]

The engineer Nikola Tesla wrote, "I have succeeded in determining the mode of their formation and producing them artificially".^[31] There is some speculation that electrical breakdown and arcing of cotton and gutta-percha wire insulation used by Tesla may have been a contributing factor, since some theories of ball lightning require the involvement of carbonaceous materials. Some later experimenters have been able to briefly produce small luminous balls by igniting carbon-containing materials atop sparking Tesla Coils.

Several theories have been advanced to describe ball lightning, with none being universally accepted. Any complete theory of ball lightning must be able to describe the wide range of reported properties, such as those described in Singer's book "The Nature of Ball Lightning" and also more contemporary research. Japanese research shows that several instances have been reported of ball lightning without any connection to stormy weather or lightning.

Ball lightning is typically 20 – 30 cm (8-12 inches) in diameter, but ball lightning several meters in diameter has been reported.^[32] Ball lightning has been seen in tornadoes, and has also been seen to split apart into two or more separate balls and recombine, and vertically-linked fireballs have been reported.^{[citation needed]} Ball lightning has carved trenches in the peat swamps in Ireland.^{[citation needed]} Because of its strange behavior, ball lightning has been mistaken for a UFO by many witnesses. One theory that may account for this wider spectrum of observational evidence is the idea of combustion inside the low-velocity region of axisymmetric (spherical) vortex breakdown of a natural vortex (e.g., the 'Hill's spherical vortex').^[33]

Ball lightning apparently is created when lightning strikes silicon in soil, and has been created in a lab in this manner.^[34]

Upper-atmospheric

Reports by scientists of strange lightning phenomena above storms date back to at least 1886. However, it is only in recent years that fuller investigations have been made. This has sometimes been called megalightning.^[35][36]

Sprites

Main article: Upper-atmospheric lightning § Sprites

Sprites are now well-documented electrical discharges that occur high above some types of thunderstorms. They appear as luminous reddish-orange, plasma-like flashes, last longer than normal lower stratospheric discharges (typically around 17 milliseconds), and are triggered by the discharges of positive lightning between the thundercloud and the ground.^[22] Sprites often occur in clusters of two or more, and typically span the distance from Template:Mi to km to Template:Mi to km above the earth, with what appear to be tendrils hanging below, and branches reaching above. A 2007 paper reports that the apparent tendrils and branches of sprites are actually formed by bright streamer heads of less than 140 m diameter moving up or down at 1 to 10 percent of the speed of light.^[37] The abstract is publicly accessible.^[38][39][36]

Sprites may be horizontally displaced by up to Template:Mi to km from the location of the underlying lightning strike, with a time delay following the lightning that is typically a few milliseconds, but on rare occasions may be up to 100 milliseconds. Sprites are sometimes, but not always, preceded by a sprite halo, a broad, pancake-like region of transient optical emission centered at an altitude of about Template:Mi to km above lightning.^[35] Sprite halos are produced by weak ionization from transient electric fields of the same type that causes sprites, but which are insufficiently intense to exceed the threshold needed for sprites. Sprites were first photographed on July 6, 1989 by scientists from the University of Minnesota and named after the mischievous sprite (air spirit) Ariel in Shakespeare's The Tempest.

Recent research carried out at the University of Houston in 2002 indicates that some normal (negative) lightning discharges produce a sprite halo, the precursor of a sprite, and that every lightning bolt between cloud and ground attempts to produce a sprite or a sprite halo.^{[citation needed]} Research in 2004 by scientists from Tohoku University found that very low frequency emissions occur at the same time as the sprite, indicating that a discharge within the cloud may generate the sprites.^[38]

Blue jets

Blue jets differ from sprites in that they project from the top of the cumulonimbus above a thunderstorm, typically in a narrow cone, to the lowest levels of the ionosphere Template:Mi to km to Template:Mi to km above the earth.^{[citation needed]} They are also brighter than sprites and, as implied by their name, are blue in color. They were first recorded on October 21 1989, on a video taken from the space shuttle as it passed over Australia, and subsequently extensively documented in 1994 during aircraft research flights by the University of Alaska.^[40][41][36]

On September 14 2001, scientists at the Arecibo Observatory photographed a huge jet double the height of those previously observed, reaching around Template:Mi to km into the atmosphere. The jet was located above a thunderstorm over the ocean, and lasted under a second. Lightning was initially observed traveling up at around 50,000 m/s in a similar way to a typical blue jet, but then divided in two and sped at 250,000 m/s to the ionosphere, where they spread out in a bright burst of light.^[42] On July 22 2002, five gigantic jets between 60 and 70 km (35 to 45 miles) in length were observed over the South China Sea from Taiwan, reported in Nature.^[40] The jets lasted under a second, with shapes likened by the researchers to giant trees and carrots.^{[citation needed]}

In 2001, the Arecibo scientists modeled the blue-jet phenomenon to better understand how it works. It is like an electron avalanche that can flood up toward the ionosphere or slide earthward, depending on the electric field direction. Intense hail may trigger the avalanche. The field accelerates the electrons and slams them into air molecules. The molecules break down into ions and free electrons and emit light. The newly generated electrons also accelerate.^[41]

Elves

Elves often appear as a dim, flattened, expanding glow around Template:Mi to km in diameter that lasts for, typically, just one millisecond.^[43] They occur in the ionosphere Template:Mi to km above the ground over thunderstorms. Their color was a puzzle for some time, but is now believed to be a red hue. Elves were first recorded on another shuttle mission, this time recorded off French Guiana on October 7 1990. Elves is a frivolous acronym for Emissions of Light and Very Low Frequency Perturbations From Electromagnetic Pulse Sources. This refers to the process by which the light is generated; the excitation of nitrogen molecules due to electron collisions (the electrons possibly having been energized by the electromagnetic pulse caused by a discharge from the Ionosphere).^[36]

Triggered lightning

Rocket-triggered

Volcanic material thrust high into the atmosphere can trigger spectacular lightning.

Lightning has been triggered directly by human activity in several instances. Lightning struck the Apollo 12 soon after takeoff, and has struck soon after thermonuclear explosions.^[44] It has also been triggered by launching lightning rockets carrying spools of wire into thunderstorms. The wire unwinds as the rocket ascends, providing a path for lightning. These bolts are typically very straight due to the path created by the wire.^[45]

Flying aircraft can trigger lightning.^[46]

Volcanically-triggered

Extremely large volcanic eruptions, which eject gases and material high into the atmosphere, can trigger lightning. This phenomenon was documented by Pliny The Elder during the AD79 eruption of Vesuvius, in which he perished.^[47]

Laser-triggered

Since at least the 1970s, researchers have attempted to trigger lightning strikes by means of ultra-violet lasers, which create a channel of ionized gas through which the lightning would be conducted to ground. Such triggered lightning is intended to protect rocket launching pads, electric power facilities, and other sensitive targets.^{[48][49][50][51][52][53]}

Extraterrestrial lightning

Lightning requires the electrical breakdown of a gas, so it cannot exist in a visual form in the vacuum of space. However, lightning has been observed within the atmospheres of other planets, such as Venus and Jupiter. Lightning on Venus is still a controversial subject after decades of study. During the Soviet Venera and U.S. Pioneer missions of the 1970s and '80s, signals suggesting lightning may be present in the upper atmosphere were detected.^[54] However, recently the Cassini-Huygens mission fly-by of Venus detected no signs of lightning at all.

Trees and lightning

Lightning damage to tree in Maplewood, NJ

Eucalyptus tree that was blown apart by a lightning strike

Trees are frequent conductors of lightning to the ground.^[55] Since sap is a poor conductor, its electrical resistance causes it to be heated explosively into steam, which blows off the bark outside the lightning's path. In following seasons trees overgrow the damaged area and may cover it completely, leaving only a vertical scar. If the damage is severe, the tree may not be able to recover, and decay sets in, eventually killing the tree. It is commonly thought that a tree standing alone is more frequently struck, though in some forested areas, lightning scars can be seen on almost every tree.

After the two most frequently struck tree types, the Oak and the Elm,^[56] the Pine tree is also quite often hit by lightning. Unlike the Oak, which has a relatively shallow root structure, pine trees have a deep central root system that goes down into the water table.^[57] Pine trees usually stand taller than other species, which also makes them a likely target. Factors which lead to its being targeted are a high resin content, loftiness, and its needles which lend themselves to a high electrical discharge during a thunderstorm.

Trees are natural lightning conductors, and are known to provide protection against lightning damages to the nearby buildings. Tall trees with high biomass for the root system provide good lightning protection. An example is the teak tree (Tectona grandis), which grows to a height of 45 metres (147.6 ft). It has a spread root system with a spread of 5 m and a biomass of 4 times that of the trunk; its penetration into the soil is 1.25 metres (4.10 ft) and has no tap root. When planted near a building, its height helps in catching the oncoming lightning leader, and the high biomass of the root system helps in dissipation of the lightning charges.^[58]

Lightning currents have a very fast risetime, on the order of 40 kA per microsecond. Hence, conductors of such currents exhibit marked skin effect, causing most of the currents to flow through the conductor skin.^[59] The effective resistance of the conductor is consequently very high and therefore, the conductor skin gets heated up much more than the conductor core. When a tree acts as a natural lightning conductor, due to skin effect most of the lightning currents flow through the skin of the tree and the sap wood. As a result, the skin gets burnt and may even peel off. The moisture in the skin and the sap wood evaporates instantaneously and may get split. If the tree struck by lightning is a teak tree (single stemmed with branches) it may not be completely destroyed since only the tree skin and a branch may be affected; the major parts of the tree may be saved from complete destruction due to lightning currents. But if the tree involved is a coconut tree it may be completely destroyed by the lightning currents.^{[citation needed]}

Lightning-induced magnetism

The movement of electrical charges produces a magnetic field (see Electromagnetism). The intense currents of a lightning discharge create a fleeting but very strong magnetic field. Where the lightning current path passes through rock, soil, or metal these materials can become permanently magnetized. This effect is known as lightning-induced remanent magnetism, or LIRM. These currents follow the least resistive path, often horizontally near the surface^[60] but sometimes vertically, where faults, ore bodies, or ground water offers a less resistive path.^[61] Lightning-induced Magnetic anomalies can be mapped in the ground,^[62] and analysis of magnetized materials can provide an estimate of the peak current of the lightning discharge.^[63]

Records and locations

On average, lightning strikes the earth about 100 times every second. For most landmasses, lightning strikes most often during the summer, limiting the strike numbers. This is not the case in equatorial Africa, where summer is year-round, and lightning is a way of life. The spot with the most lightning lies deep in the mountains of eastern Democratic Republic of the Congo, near the small village of Kifuka which has an elevation of 3,200 feet (975 m). Thunderbolts pelt this land, and each year on average, 158 bolts occur over each square kilometer (equivalent to 10 city-blocks square).^[64] Singapore has one of the highest rates of lightning activity in the world.^[65] The city of Teresina in northern Brazil has the third-highest rate of occurrences of lightning strikes in the world. The surrounding region is referred to as the Chapada do Corisco ("Flash Lightning Flatlands").^[66] In the US, Central Florida sees more lightning than any other area. For example, in what is called "Lightning Alley", an area from Tampa, to Orlando, there are as many as 50 strikes per square mile (about 20 per km²) per year.^[67][68] The Empire State Building is struck by lightning on average 23 times each year, and was once struck 8 times in 24 minutes.^[69]

Roy Sullivan held a Guinness World Record after surviving 7 different lightning strikes across 35 years.^[70]

In July 2007, lightning killed up to 30 people when it struck a remote mountain village Ushari Dara in northwestern Pakistan.^[71] Also, in Deerfield Beach, Florida lightning struck a diver's air tank as he surfaced off Florida's Atlantic coast, killing him. He surfaced about 10 metres (32.8 ft) from the boat, when lightning struck his tank.^[72]

Lightning can also strike indoor pools, directed into the pump by electrical circuits from outdoor power poles. Such strikes could potentially kill people who are swimming or walking on wet floors around a pool. In 2000, lightning killed two boys in an outdoor pool in Florida.^[73]

A single lightning strike can have a potential of a billion volts and deliver 100,000 amperes of current. If a bolt directly hits a marine animal swimming on the surface, it will undoubtedly hurt or kill the animal. Lightning strikes have killed or injured people on the surface more than 30 yards away.^[74]

Lightning rarely strikes the open ocean, although some sea regions are lightning "hot spots." Winter storms passing off the east coast of the United States often erupt with electrical activity when they cross the warm waters of the Gulf Stream.^[75]The Gulf Stream, for example, has roughly as many lightning strikes as the southern plains of the USA.

Lightning detection

Lightning discharges generate a wide range of electromagnetic radiations, including radio-frequency pulses. The times at which a pulse from a given lightning discharge arrive at several receivers can be used to locate the source of the discharge. The United States federal government has constructed a nation-wide grid of such lightning detectors, allowing lightning discharges to be tracked in real time throughout the continental U.S.^[76][77]

In addition to ground-based lightning detection, several instruments aboard satellites have been constructed to observe lightning distribution. These include the Optical Transient Detector (OTD) and the subsequent Lightning Imaging Sensor (LIS).^[78][79][80]

For more information, see Lightning safety § Safety mechanisms.

In culture

As expressions and symbols

The expression "Lightning never strikes twice [in the same place]" is similar to "Opportunity never knocks twice" in the vein of a "Once in a lifetime" opportunity, i.e., something that is generally considered improbable. Lightning occurs frequently and more so in specific areas. Since various factors alter the probability of strikes at any given location, repeat lightning strikes have a very low probability (but are not impossible).^[69][81] Similarly, "A bolt from the blue" refers to something totally unexpected.

In French and Italian, the expression for "Love at first sight" is Coup de foudre and Colpo di fulmine, respectively, which literally translated means "Bolt of lightning". Some European languages have a separate word for lightning which strikes the ground (as opposed to lightning in general); often it is a cognate of the English word "rays". The name of New Zealand's most celebrated thoroughbred horse, Phar Lap, derives from the shared Zhuang and Thai word for lightning.^{[citation needed]}

The bolt of lightning in heraldry is called a thunderbolt and is shown as a zigzag with non-pointed ends. This symbol usually represents power and speed; and thus has been used to represent the Greek god Zeus, as well as many advertisements which use such symbol to describe their product. It is also distinguished from the "fork of lightning". The lightning bolt shape was a symbol of male humans among the Native Americans such as the Apache in the American Old West.^{[citation needed]}

Media

Hugo Danner, the super-powered protagonist of Philip Gordon Wylie's 1930 novel Gladiator and the inspiration for Superman,^[82] was ultimately killed by a lightning bolt as he stood on a mountain top challenging God's power.^[83]

See also

• Heat lightning
• Lightning safety
• Lightning rod
• Keraunomedicine (the medical study of lightning casualties.)
• Runaway breakdown
• Radio atmospheric
• Whistler (radio)
• Robert Krampf, "Mr. Electricity"

References

1. NGDC - NOAA. "Volcanic Lightning". National Geophysical Data Center - NOAA. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
2. Munoz, Rene (2003). "Factsheet: Lightning". University Corporation for Atmospheric Research. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
3. Rakov, Vladimir A. (1999). "Lightning Makes Glass". University of Florida, Gainesville. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
4. USGS (1998). "Bench collapse sparks lightning, roiling clouds". United States Geological Society. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
5. Micah Fink for PBS. "How Lightning Forms". Public Broadcasting System. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
6. National Weather Service (2007). "Lightning Safety". National Weather Service. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
7. April Holladay (2007). "Not so hot lightning". WeatherQuesting. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
8. Skinny lightning bolts
9. NASA (2005). "Flashes in the Sky: Lightning Zaps Space Radiation Surrounding Earth". NASA. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
10. Robert Roy Britt (1999). "Lightning Interacts with Space, Electrons Rain Down". Space.com. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
11. Demirkol, M. K. (December 1999). (abstract) "Ionospheric effects of relativistic electron enhancement events". Geophysical Research Letters. Vol. 26 (No. 23): pages 3557-3560. {{cite journal}}: |issue= has extra text (help); |pages= has extra text (help); |volume= has extra text (help); Check |url= value (help); Unknown parameter |coauthors= ignored (|author= suggested) (help)
12. "Electric Ice". NASA. Retrieved 2007-07-05. {{cite web}}: Cite has empty unknown parameters: |accessdaymonth=, |month=, |accessyear=, |accessmonthday=, and |coauthors= (help)
13. What causes lightning?
14. Frazier, Alicia (December 12 2005). "THEORIES OF LIGHTNING FORMATION". Department of Atmospheric and Oceanic Sciences, University of Colorado, Boulder. Retrieved 2007-07-29. {{cite web}}: Check date values in: |date= (help)
15. Martin A. Uman (1986). All About Lightning. Dover Publications, Inc. pp. pages 103-110. ISBN 0-486-25237-X. {{cite book}}: |pages= has extra text (help) Cite error: The named reference "uman" was defined multiple times with different content (see the help page).
16. Gurevich (2003-12-04), "How Lightning Works Is Still A Mystery", The Economist
17. Dwyer, Joseph R., "A bolt out of the blue," Scientific American, vol. 292, no. 5, pages 64-71 (May 2005)
18. Shrope, Mark (September 9 2004). "Lightning research: The bolt catchers". Nature. 431: 120–121. doi:10.1038/431120a. Retrieved 2007-07-27. {{cite journal}}: Check date values in: |date= (help)
19. U.S. Inan, S.C. Reising, G.J. Fishman, and J.M. Horack. On the association of terrestrial gamma-ray bursts with lightning and implications for sprites. Geophysical Research Letters, 23(9):1017-20, May 1996. As quoted by http://elf.gi.alaska.edu/spr20010406.html#InanUS:theatg Retrieved 2007-03-06.
20. Skinny lightning bolts
21. "NWS JetStream - The Positive and Negative Side of Lightning". NOAA. Retrieved 2007-09-25.
22. Boccippio, D. J.; et al. (August 1995). "Sprites, ELF Transients, and Positive Ground Strokes". Science. 269: 1088–1091. {{cite journal}}: Explicit use of et al. in: |first= (help)
23. "Air Accidents Investigation Branch (AAIB) Bulletins 1999 December: Schleicher ASK 21 two seat glider".
24. "A Lightning Primer from the GHCC: Types of Lightning Discharges".
25. Lawrence, David. "Bolt from the Blue". National Oceanic and Atmospheric Administration. Retrieved 2007-07-05.
26. "Definition of Rocket Lightning, AMS Glossary of Meteorology". Retrieved 2007-07-05.
27. Hopkins, Albert Allis; Bond, Alexander Russell (1914), Scientific American Reference Book, New York: Munn & Co.Page 508
28. "Beaded Lightning". Glossary of Meteorology, 2nd edition. American Meteorological Society (AMS). 2000. Retrieved 2007-07-31.
29. Uman (1986) Chapter 16, pages 139-143
30. Kirthi Tennakone (2007). "Ball Lightning". Georgia State University. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
31. "Electrical World and Engineer". 1904-03-05. {{cite journal}}: Cite journal requires |journal= (help)
32. Singer, Stanley (1971). The Nature of Ball Lightning. New York: Plenum Press. ISBN 0306304945.
33. The scientist Coleman was the first to propose this theory in 1993 in Weather, a publication of the Royal Meteorological Society.
34. "Lightning balls created in the lab". New Scientist. Retrieved 2007-12-08.
35. Sterling D. Allen - Pure Energy Systems News (2005). "BLAM-O!! Power from Lightning". Pure Energy Systems. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
36. Holoscience.com. "Image of lightning types and altitudes" (.jpg). Holoscience.com. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
37. Stenbaek-Nielsen, H. C.; McHarg, M.G.; Kanmae, T.; Sentman, D.D. (June 6), ""Observed emission rates in sprite streamer heads"", Geophys. Res. Lett., 34 (11), doi:10.1029/2007GL029881, L11105 {{citation}}: Check date values in: |date= and |year= / |date= mismatch (help)
38. H. C. Stenbaek-Nielsen (2007). "Observed emission rates in sprite streamer heads". Geophysical Institute, University of Alaska, Fairbanks, Alaska, USA. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help) Cite error: The named reference "agu" was defined multiple times with different content (see the help page).
39. Dave Mosher (2007). "Video Reveals "Sprite" Lightning Secrets". Live Science. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
40. Tom Clarke (2002). "Blue jets connect Earth's electric circuit". Nature.com. {{cite web}}: Unknown parameter |accessmonthay= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
41. April Holladay (2005). "Blue jet stabs high into stormy sky". Weather Questing. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
42. Penn State College of Engineering (2002). "Researchers capture unusual sprite-like blue jet". Penn State College of Engineering. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
43. W. Wayt Gibbs for Scientific American. "Lightning's strange cousins flicker faster than light itself". Scientific American. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
44. "An empirical study of the nuclear explosion-induced lightning seen on IVY-MIKE", Journal of Geophysical Research, vol. 92, no. D5, pp. 5696–5712, 1987
45. Chris Kridler (2002). "July 25, 2002 - Triggered lightning video" (video). requires QuickTime. Chris Kridler's Sky Diary. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
46. Uman (1986), chapter 4, pages 26-34
47. Pliny the Younger. "Pliny the Younger's Observations". Retrieved 2007-07-05. Behind us were frightening dark clouds, rent by lightning twisted and hurled, opening to reveal huge figures of flame. {{cite web}}: Cite has empty unknown parameters: |accessdaymonth=, |accessyear=, |month=, |accessmonthday=, and |coauthors= (help)
48. "UNM researchers use lasers to guide lightning". Campus News, The University of New Mexico. January 29 2001. Retrieved 2007-07-28. {{cite web}}: Check date values in: |date= (help)
49. Nasrullah Khan, Norman Mariun, Ishak Aris and J Yeak (2002). "Laser-triggered lightning discharge". New Journal of Physics. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
50. P. Rambo, J. Biegert, , J. Schwarz, A. Bernstein; et al. (1999). "Laboratory tests of laser-induced lightning discharge". Vol. 66, Issue 3, pp. 194-. Journal of Optical Technology. {{cite web}}: Explicit use of et al. in: |author= (help); Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
51. R. Ackermann, J. P. Wolf, L. Wöste; et al. (2004). "Triggering and guiding of megavolt discharges by laser-induced filaments under rain conditions". Applied Physics Letters. {{cite web}}: Explicit use of et al. in: |author= (help); Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
52. Z.I. Kawasaki, T. Kanao, K. Matsuura, M. Nakano; et al. (1991). "The electric field changes and UHF radiations caused by the lightning in Japan". Abstract. Geophysical Research Letters. {{cite web}}: Explicit use of et al. in: |author= (help); Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
53. Lippert, J. R. (1977). "A laser-induced lightning concept experiment". Air Force Flight Dynamics Lab., Wright-Patterson AFB. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
54. Robert J. Strangeway - Institute of Geophysics and Planetary Physics UCLA (1994). "Plasma Wave Evidence for Lightning on Venus". Journal of Atmospheric and Terrestrial Physics. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
55. National Oceanic & Atmospheric Administration. "Image of lightning hitting a tree" (.jpg). National Oceanic & Atmospheric Administration. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
56. Ribert E. Cripe. "Lightning protection for trees and related property" (pdf). Journal of Arboriculture. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
57. Olympia Forestry Sciences Laboratory (2004). "Silviculture and Forest Models Team - Oak Root Research". USDA Forest Service. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
58. Gopalan (2005-11-1). "Lightning protection of airport runway". ASCE Journal of Performance of Constructed Facilities. 19 (4). {{cite journal}}: Check date values in: |date= (help); Cite has empty unknown parameters: |laydate=, |quotes=, |laysource=, |laysummary=, |coauthors=, and |month= (help)
59. Nair, Zinnia (May 1, 2005). "Failure of 220 kV double circuit transmission line tower due to lightning". Journal of Performance of Constructed Facilities. Vol.19 (No.2). {{cite journal}}: |issue= has extra text (help); |volume= has extra text (help); Unknown parameter |coauthors= ignored (|author= suggested) (help)
60. Graham KWT. 1961. The Re-magnetization of a Surface Outcrop by Lightning Currents. Geophys. J. Roy. Astron Soc., 6, p.85-102; Cox A. 1961. Anomalous Remanent Magnetization of Basalt. U.S. Geological Survey Bulletin 1038-E, p. 131-160.
61. Bevan B. 1995. Magnetic Surveys and Lightning. Near Surface Views (newsletter of the Near Surface Geophysics section of the Society of Exploration Geophysics. October 1995, p.7-8.
62. Sakai HS, Sunada, S, Sakurano H. 1998. Study of Lightning Current by Remanent Magnetization. Electrical Engineering in Japan, Vol. 123, No. 4. p.41-47; http://www.archaeophysics.com/pubs/LIRM.html
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66. Paesi Online. "Teresina: Vacations and Tourism". Paesi Online. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
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69. Uman (1986), chapter 6, page 47
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71. "Lightning kills 30 people in Pakistan's north". Reuters. July 20 2007. Retrieved 2007-07-27. {{cite news}}: Check date values in: |date= (help)
72. "Diver dies after lightning hits air tank near Deerfield Beach", The Jacksonville Times-Union, July 23, 2007 {{citation}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
73. Everybody out of the pool!
74. Lightning strikes fish
75. Lightning strikes fish
76. Lightning Detection Systems, retrieved 2007-07-27 NOAA page on how the U.S. national lightning detection system operates
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80. NASA (2007). "NASA OTD Images". NASA. {{cite web}}: Unknown parameter |accessmonthday= ignored (help); Unknown parameter |accessyear= ignored (|access-date= suggested) (help)
81. "Jesus actor struck by lightning". BBC News International Version. October 23, 2003. Retrieved 2007-08-19.
82. Jones, Gerard. Men of Tomorrow: Geeks, Gangsters, and the Birth of the Comic Book. New York: Basic Books, 2004 (ISBN 0465036562), pg. 80
83. Wylie, Philip. Gladiator. New York: Shakespeare House. 1951, pg. 187

Sources

• My Very Close Encounters With Florida Lightning Bolts By Thomas F. Giella, Retired Meteorologist & Space Plasma Physicist
• Alex Larsen (1905). "Photographing Lightning With a Moving Camera". Annual Report Smithsonian Institute. 60 (1): 119–127.
• André Anders (2003). "Tracking Down the Origin of Arc Plasma Science I. Early Pulsed and Oscillating Discharges". IEEE Transactions on Plasma Science. 31 (4): 1052–1059. This is also available at [1]
• Anna Gosline (May 2005). "Thunderbolts from space". New Scientist. 186 (2498): 30–34.
• Martin A. Uman (1986). All About Lightning. Dover Publications, Inc. ISBN 0-486-25237-X. This book is written for the layman.
• V. A. Rakov (2003). Lightning, physics and effects. Cambridge University Press. ISBN 0-521-58327-6. {{cite book}}: Unknown parameter |coauthors= ignored (|author= suggested) (help) Sample, in .pdf form, consisting of all of the book through page 20.
• The Mirror of Literature, Amusement, and Instruction, Vol. 12, Issue 323, July 19, 1828 The Project Gutenberg eBook (early lightning research)

External links

• Central Florida's "Lightning Stalker" photography
• How Lightning Works at HowStuffWorks
• My Very Close Encounters With Florida Lightning Bolts By Thomas F. Giella, KN4LF Retired Meteorologist & Space Plasma Physicist
• Positive lightning photography from Florida
• Severe Weather UK
• Impressive lightning photography More than 200 Lightning-Pictures
• Video of a heavy thunderstorm Source: German Weather Chronicles
• "1.21 Gigawatts!" Lightning safety and first-aid in the backcountry
• dmoz: Thunderstorms and Lightning
• Lightning Safety Page - National Weather Service Pueblo Colorado Citat: "...This is known as a "side flash". Many people who are "struck" by lightning are not hit directly by the main lightning channel, but are affected by the side flash..."
• Lightning Facts
• Laser Beam Triggers Lightning Strike During Japanese Experiment
• Colorado Lightning Resource Center
• Webarchive: April 25, 1997 Sandia-led research may zap old beliefs about lightning protection at critical facilities; Triggered lightning tests leading to safer storage bunkers
• 2003-11-06, ScienceDaily: Thunderstorm Research Shocks Conventional Theories; Florida Tech Physicist Throws Open Debate On Lightning's Cause
• Huge oak tree destroyed by lightning, by Igor Chudov
• Austrian Lightning Detection and Information System
• European Cooperation for Lightning Detection
• How to Photograph Lightning A page with both brief and verbose instructions on taking lightning photos.
• Positive Lightning Strike Photo of a nearby positive lightning strike that nearly kills the Australian photographer
• Petrified lightning (fulgurites) from Central Florida
• United States Precision Lightning Network - Live lightning data map
• NASA Finds Lightning Clears Safe Zone in Earth's Radiation Belt
• AMS Glossary: Dart Leader
• NOAA: What is Lightning?
• Lucky snapshot: lightning strikes chemical mill in Germany
• Lightning over Luxembourg
• Lightning detection system shows lightning activity in the Tampa Bay, Florida area
• Lightning Test
• National Geographic Lightning Simulator
• Live storm data and sferics for southern England generated by data recorded by a weather station at Newport, Isle of Wight, UK [2]
• Lightning risk assessment application according European IEC 62305-2 norm.
• Lighting strike on Menaggio, Lake Como, Italy September 2007
• Huge Lighting strike on Chicago Sears tower, October 2007

Jets, sprites & elves

• Homepage of the Eurosprite campaign, itself part of the CAL (Coupled Atmospheric Layers) research group
• March 2, 1999, University of Houston: UH Physicists Pursue Lightning-Like Mysteries Quote: "...Red sprites and blue jets are brief but powerful lightning-like flashes that appear at altitudes of 40-100 km (25-60 miles) above thunderstorms..."
• Ground and Balloon-Borne Observations of Sprites and Jets
• Barrington-Leigh, C. P., "Elves : Ionospheric Heating By the Electromagnetic Pulses from Lightning (A primer)". Space Science Lab, Berkeley.
• "Darwin Sprites '97". Space Physics Group, University of Otago.
• Barrington-Leigh, Christopher, "VLF Research at Palmer Station".
• Sprites, jets and TLE pictures and articles

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