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  • Recoletta Cemetery, Buenos Aires
    ARG_110109_041_x.jpg
  • A human skull, bones, and clothing dumped by a grave in  Champoton, Yucatan, Mexico.
    MEX_040_xs.jpg
  • Aged wine in bottles at R. Lopez Heredia winery, Haro. The aging cellars are not dusted and the older sections have a tremendous buildup of mold, dust, and cobwebs that give the cellars the look of a horror movie La Rioja, Spain.
    SPA_031_xs.jpg
  • Aged wine in bottles at R. Lopez Heredia winery, Haro. The aging cellars are not dusted and the older sections have a tremendous buildup of mold, dust, and cobwebs that give the cellars the look of a horror movie set.  La Rioja, Spain.
    SPA_030_xs.jpg
  • Sheep skeleton near Lough Inagh, West Ireland (Connemara).
    IRE_03_xs.jpg
  • Young boy in Doksany. Prague, Czech Republic.
    CZE_38_xs.jpg
  • Siem Reap, Cambodia. A pile of human skulls marking one of the Killing Fields memorials.
    CAM_12_xs.jpg
  • Poor people living on the sidewalk near Nariman Point; Bombay, India.
    IND_003_xs.jpg
  • A one-legged human skeleton left behind in Mogadishu, the war-torn capital of Somalia where 30,000 people were killed between November 1991 and March 1992. March 1992.
    SOM_31_xs.jpg
  • Saint Prisca, the Cathedral in Taxco, a colonial silver mining town in central Mexico.
    MEX_019_xs.jpg
  • The Cathedral in Merida, Yucatan, Mexico.
    MEX_018_xs.jpg
  • The National Cathedral in the Zocalo, the main central Square, Mexico City, Mexico. Construction was ordered by Cortez after destroying the Aztec temples which once occupied the site. It is now tilted as it sinks slowly into the lake bed Mexico City is built on.
    MEX_015_xs.jpg
  • Decomposing body in the streets of Mogadishu, war-torn capital of Somalia, where 30,000 died between November 1991 and March 1992.
    SOM_25_xs.jpg
  • Alien. Head and torso of a replica alien on an autopsy table as an exhibit at the International UFO Museum and Research Center in Roswell, USA. The town has tourist attractions around the theme of UFO's. It was near Roswell on 2 July 1947 that UFO sightings were reported during a thunderstorm. Strange wreckage was found in a field and when the impact site was located, a UFO craft and alien bodies were allegedly found and an autopsy conducted. On 8 July 1947, the Roswell Daily Record announced the capture of a flying saucer. The official explanation was that it was a crashed weather balloon. Many Roswell inhabitants, however, believe that aliens had arrived. (1997)
    USA_SCI_UFO_24_xs.jpg
  • Replica of an alien body (a movie prop donated to the museum) in the International UFO Museum and Research Center, 114 N. Main St., in downtown Roswell, New Mexico. Museum visitors begin their tour with a short talk by Dennis Balthaser, a "certified MUFON UFO-ologist" (Mutual UFO Network). The Roswell incident started on 2 July 1947 when UFO sightings were reported during a thunderstorm. Next morning a rancher, Mac Brazel, discovered strange wreckage in a field. When the impact site was located, a UFO craft and alien bodies were allegedly found. On 8 July 1947, the Roswell Daily Record announced the capture of a flying saucer. (1997).
    USA_SCI_UFO_23_xs.jpg
  • La Boca, Buenos Aires, Argentina
    ARG_110108_196_x.jpg
  • View of Taxco, a colonial silver mining hill town in Mexico, with a patio in the foreground.
    MEX_022_xs.jpg
  • The neo-classical Metropolitan Cathedral in Guadalajara, Mexico.
    MEX_017_xs.jpg
  • Alien autopsy. Retired mortician, Glenn Dennis, with a replica of an alien body at the International UFO Museum and Research Center in Roswell, USA. The town has tourist attractions around the theme of UFO's. It was near Roswell on 2 July 1947 that many UFO sightings were reported during a thunderstorm. Strange wreckage was found in a field and when the impact site was located, a UFO craft and alien bodies were allegedly found and an autopsy conducted. On 8 July 1947, the Roswell Daily Record announced the capture of a flying saucer. Many Roswell inhabitants, however, believe aliens had arrived. Model Released (1997)
    USA_SCI_UFO_25_xs.jpg
  • Replica of an alien body (a movie prop donated to the museum) in the International UFO Museum and Research Center, 114 N. Main St., in downtown Roswell, New Mexico. Museum visitors begin their tour with a short talk by Dennis Balthaser, a "certified MUFON UFO-ologist" (Mutual UFO Network). The Roswell incident started on 2 July 1947 when UFO sightings were reported during a thunderstorm. Next morning a rancher, Mac Brazel, discovered strange wreckage in a field. When the impact site was located, a UFO craft and alien bodies were allegedly found. On 8 July 1947, the Roswell Daily Record announced the capture of a flying saucer. (1997).
    USA_SCI_UFO_22_xs.jpg
  • Retired mortician Glenn Dennis who was on duty in Roswell, New Mexico, the night of the purported crash of a UFO outside of the nearby town of Corona peers at the replica of an alien body (a movie prop) in a local museum. Dennis, whose wife doesn't allow the discussion of UFO's in their home, is president of the International UFO Museum and Research Center, in Roswell. Stories about the crash spread and some called the incident a government cover up hiding the existence of alien life forms. Officials said it was a weather balloon. Model Released (1997) .
    USA_SCI_UFO_21_xs.jpg
  • Aerial of the neo-classical Metropolitan Cathedral and Degollado Theater in Guadalajara, Mexico.
    MEX_016_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter. A technician checking Perspex plates at the IMB Proton Decay Experiment site. The IMB Project is named after the sponsoring institutions, University of California at Irvine, University of Michigan and the Brookhaven National Laboratory. The experiment consists of a 60-foot deep tank filled with 8,000 tons of purified water, dug into the Morton-Thiokol salt mine at Painesville, Ohio, some 2,000 feet underground. The proton decay event will be detected by an array of 2,048 photomultipliers that line the tank. Proton decay is essential in most Grand Unified Theories of the fundamental forces, but to date no firm evidence of the decay has been found.
    USA_SCI_PHY_34_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter..Proton decay. A technician [works with] a 20" (50cm) photomultiplier tube used in the search for proton decay. Hundreds of such tubes line a tank containing 9000 tons of water some 1000 meters underground in a zinc mine in Japan. Tokyo University's Kamiokande experiment was designed to look for decaying protons. If a proton decays, the charged particles it generates move through the water faster than light, and so generate blue 'Cerenkov' radiation. It is this that the photomultipliers detect. Computers then decide whether the event was a decay, or a collision with a solar neutrino. Japan. (1985)
    Japan_JAP_SCI_PHY_02_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter. .Dr. Oscar Saavedra outside the door to the tunnel experiment with traffic streaming by. Oscar Saavedra, experimenter in the Mont Blanc Proton Decay group. The experiment consists of a 150-ton cube of iron sheets, interleaved with Geiger counter tubes. The cube has to be large enough to provide a mass of protons that will bring the probability of a decay event occurring within practical bounds, made difficult by the half life of the proton being 10 to the power 34 years.  (1985).
    FRA_SCI_PHY_01_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter..View of the entrance of Tokyo University's Proton Decay Experiment. 1,000 50-centimeter photomultiplier tubes line the 12-meter deep tank of water form the experiment. The water contains enough protons to provide an average of one decay event per year, an event that may be detected by these tubes as the particles from the decay cause a visible light phenomenon known as Cerenkov radiation. The experiment is taking place 914 meters underground in a zinc mine below Mt. Ikenoyama to minimize the effects of cosmic rays. Japan. (1985).
    Japan_JAP_SCI_PHY_04_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter..The iron stack, which forms the proton decay experiment at Frejus, France. The stack consists of iron bars interspersed with Geiger tubes, and is designed to provide enough protons to bring the probability of observing a decay event into realistic proportions, made difficult by the half- life of the proton being ten to the power 34 years. (1985)
    FRA_SCI_PHY_03_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter. Dr. Masatoshi Koshiba, director of Tokyo University's Proton Decay Experiment. Dr. Koshiba is seen holding one of the 1,000 50 centimeter photomultiplier tubes that line the 12-meter deep tank of water that forms the experiment. The water contains enough protons to provide an average of one decay event per year, an event that may be detected by these tubes as the particles from the decay cause a visible light phenomenon known as Cerenkov radiation. The experiment is taking place 914 meters underground in a zinc mine below Mt. Ikenoyama to minimize the effects of cosmic rays..Japan. MODEL RELEASED (1985)
    Japan_JAP_SCI_PHY_03_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter..Entrance of the gold mine at Kolar, site of India's proton decay experiment. The experiment consists of 150 tons of iron tube arranged in a cubic layout 6000 feet (1828 meters) below ground. Each tube is converted to act like a large Geiger counter, and is designed to detect the products from the decay of a proton. The half- life of the proton is estimated at 10 to the power 34 years, so the experiment has to contain as many protons as possible for the probability of an event occurring to be realistic. India. (1985)
    IND_SCI_PHY_05_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter..Mine workers passing the entrance to the Kolar proton decay experiment, 6,000 feet underground in a gold mine in India. The experiment consists of 150 tons of iron tube arranged in a cubic layout. Each tube is converted to act like a large Geiger counter, and is designed to detect the products from the decay of a proton. The half-life of the proton is estimated at 10 to the power 34 years, so the experiment has to contain as many protons as possible for the probability of an event occurring to be realistic. India. (1985)
    IND_SCI_PHY_03_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter. Dr. Narasimham. Gold mine at Kolar, site of India's proton decay experiment. The experiment consists of 150 tons of iron tube arranged in a cubic layout 6000 feet (1828 meters) below ground. Each tube is converted to act like a large Geiger counter, and is designed to detect the products from the decay of a proton. The half- life of the proton is estimated at 10 to the power 34 years, so the experiment has to contain as many protons as possible for the probability of an event occurring to be realistic. India. MODEL RELEASED (1985)
    IND_SCI_PHY_01_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter. View of the entrance to the French side of the Mont Blanc tunnel, inside which is located the NUSEX proton decay experiment. The tunnel runs between France & Italy under Mont Blanc. NUSEX is located several kilometers inside the tunnel, on the French side of the border, in one of the garage areas dug out of the rock at regular intervals along the tunnel. .View of the NUSEX (Nucleon Stability Experiment) proton decay detector located in a garage area off the Mont Blanc tunnel under some 5000 meters of rock which shields it from most cosmic radiation. (1985)
    FRA_SCI_PHY_04_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter. .Proton decay. A technician holding a 20" (50cm) photomultiplier tube used in the search for proton decay. Hundreds of such tubes line a tank containing 9000 tons of water some 1000 meters underground in a zinc mine in Japan. Japan. (1985)
    Japan_JAP_SCI_PHY_01_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter..The tubular iron detector of the Kolar proton decay experiment, 6,000 feet underground in a gold mine in India. The experiment consists of 150 tons of iron tube arranged in a cubic layout. Each tube is converted to act like a large Geiger counter, and is designed to detect the products from the decay of a proton. The half-life of the proton is estimated at 10 to the power 34 years, so the experiment has to contain as many protons as possible for the probability of an event occurring to be realistic.   India. (1985)
    IND_SCI_PHY_04_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter. Dr. Narasimham. Gold mine at Kolar, site of India's proton decay experiment. The experiment consists of 150 tons of iron tube arranged in a cubic layout 6000 feet (1828 meters) below ground. Each tube is converted to act like a large Geiger counter, and is designed to detect the products from the decay of a proton. The half- life of the proton is estimated at 10 to the power 34 years, so the experiment has to contain as many protons as possible for the probability of an event occurring to be realistic.  India. MODEL RELEASED (1985)
    IND_SCI_PHY_02_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter..Physics: Proton Decay. Ohio, Morton Salt Mine (1985). Proton decay detector located 600 meters underground in the Morton salt mine near Cleveland, Ohio.which consists of a massive tank containing 21 cubic meters of ultra pure water, its walls lined with photomultiplier tubes, which detect faint flashes of Cerenkov light emitted by the passage of charged particles
    USA_SCI_PHY_36_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter..Physics: Proton Decay. Ohio, Morton Salt Mine (1985). Proton decay detector located 600 meters underground in the Morton salt mine near Cleveland, Ohio.which consists of a massive tank containing 21 cubic meters of ultra pure water, its walls lined with photomultiplier tubes, which detect faint flashes of Cerenkov light emitted by the passage of charged particles.
    USA_SCI_PHY_35_xs.jpg
  • Proton decay experiment to determine the ultimate stability of matter. View of the NUSEX (Nucleon Stability Experiment) proton decay detector located in a garage area off the Mont Blanc tunnel under some 5000 meters of rock which shields it from most cosmic radiation. (1985)
    FRA_SCI_PHY_02_xs.jpg
  • Physics: Proton Decay. Ohio, Morton Salt Mine 1985. Proton decay detector located 600 meters underground in the Morton salt mine near Cleveland, Ohio, which consists of a massive tank containing 21 cubic meters of ultra pure water, its walls lined with photomultiplier tubes, which detect faint flashes of Cerenkov light emitted by the passage of charged particles. MODEL RELEASED
    USA_SCI_PHY_28_xs.jpg
  • Physics: Proton Decay control room. Cleveland, Ohio, Morton Salt Mine proton decay detector located 600 meters underground in the Morton salt mine near Cleveland, Ohio, which consists of a massive tank containing 21 cubic meters of ultra pure water, its walls lined with photomultiplier tubes, which detect faint flashes of Cerenkov light emitted by the passage of charged particles. [1985]
    USA_SCI_PHY_24_xs.jpg
  • Alan Weinstein from the Stanford Linear Collider (SLC) experiment, seen with a computer-simulated collision event between an electron and a positron. The SLC produces Z-zero particles by this collision process, which takes place at energies high enough for the electron and positron to annihilate one another, the Z-zero left decaying rapidly into another electron/positron pair or a quark/anti-quark pair. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was discovered at CERN in 1983. The first Z-zero seen at SLC was detected on 11 April 1989. MODEL RELEASED [1988] Menlo Park, California.
    USA_SCI_PHY_06_xs.jpg
  • Matthew Jones, wearing 3-D glasses to view computer simulations, from the Stanford Linear Collider (SLC) experiment, seen with a computer-simulated collision event between an electron and a positron. The SLC produces Z-zero particles by this collision process, which takes place at extremely high energies. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was discovered at CERN in 1983. The scientist is seen wearing special glasses that enable viewing of computer- generated stereoscopic images of the particle tracks following the collision inside the Large Detector. The first Z-zero seen at SLC was detected on 11 April 1989. MODEL RELEASED [1988]
    USA_SCI_PHY_08_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC) Helen Quinn, theoretician. Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. MODEL RELEASED [1986].
    USA_SCI_PHY_05_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC). Main complex. (1986) 3. 2 km (2 mile) long linear accelerator at the Stanford Linear Accel- erator Center (SLAC), California. The end at which the electrons start their journey is in the distance; the experimental areas where the accelerated electrons are smashed into targets, or used for further acceleration in electron-positron Colliders, is in the group of buildings seen here. The giant red- roofed building in the experimental area is End Station A, where the first evidence of quarks was discovered in 1968-72. .Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989.
    USA_SCI_PHY_37_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC), Menlo Park, California. Control Room [1988]. Instrumentation displays inside the control room of the Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989.
    USA_SCI_PHY_29_xs.jpg
  • Physics: Aligning Magnets in the 3 km tunnel of the Stanford Linear Accelerator Center (SLAC), Menlo Park, California.  Reverse Bend SLC Experiment, [1986].Technicians making final alignment checks in the tunnel of the Stanford Linear Collider (SLC). The SLC was built from the 3km linear accelerator at Stanford, California. In the SLC, electrons and positrons are accelerated to energies of 50 giga electron volts (GeV) before being forced to collide. In this collision, a Z-nought particle may be produced. The Z-nought is the mediator of the electroweak nuclear force, the force behind radioactive decay. The first Z-nought was detected at SLC on 11 April 1989, six years after its discovery at the European LEP accelerator ring, near Geneva..
    USA_SCI_PHY_25_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC), Menlo Park, California. Control Room..Instrumentation displays inside the control room of the Stanford Linear Collider (SLC) experiment, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]
    USA_SCI_PHY_22_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC). Electronics Trailer. J. Chapman checks myriad connections..Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]
    USA_SCI_PHY_19_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC). Rafe Schindler and Iris Abt with detector insert. Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]
    USA_SCI_PHY_18_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC). Large Detector construction: sorting through the tens of thousands of fittings. Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]
    USA_SCI_PHY_15_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC) Martin Perl, Physicist at SLAC..Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. MODEL RELEASED [1988]
    USA_SCI_PHY_10_xs.jpg
  • Matthew Jones, wearing 3-D glasses to view computer simulations, from the Stanford Linear Collider (SLC) experiment, seen with a computer-simulated collision event between an electron and a positron. The SLC produces Z-zero particles by this collision process, which takes place at extremely high energies. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was discovered at CERN in 1983. The scientist is seen wearing special glasses that enable viewing of computer- generated stereoscopic images of the particle tracks following the collision inside the Large Detector. The first Z-zero seen at SLC was detected on 11 April 1989. MODEL RELEASED [1988]
    USA_SCI_PHY_07_xs.jpg
  • The Calabay Sicay family sisters at home in San Antonio Palopo Village on Lake Aititlan, Guatemala. Smiles show tooth decay.
    GUA_10_xs.jpg
  • Physics: Stanford Linear Accelerator Center (SLAC), Menlo Park, California. Large Detector Control Room. Instrumentation displays inside the control room of the Stanford Linear Collider (SLC) experiment, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. [1988]
    USA_SCI_PHY_26_xs.jpg
  • Physics: Pat Burchat, with a computer simulation reflected in her glasses at the Stanford Linear Accelerator Center (SLAC) Large Detector. Computer Simulated Event. Stanford Linear Collider (SLC) experiment, Menlo Park, California. With a length of 3km, the Stanford Linear Accelerator is the largest of its kind in the world. The accelerator is used to produce streams of electrons and positrons, which collide at a combined energy of 100 GeV (Giga electron Volts). This massive energy is sufficient to produce Z-zero particles in the collision. The Z-zero is one of the mediators of the weak nuclear force, the force behind radioactive decay, and was first discovered at CERN, Geneva, in 1983. The first Z-zero at SLC was produced on 11 April 1989. MODEL RELEASED [1988]
    USA_SCI_PHY_09_xs.jpg
  • A betel nut vendor takes a drink of water between customers in Varanasi, India. Betel nut is a mildly narcotic seed eaten with lime paste and a green leaf. Over time it decays the teeth and dyes the mouth of the user red. Although its not considered a food, it is a plant item chewed by many all over Asia, and kept in the mouth like chewing tobacco. (From a photographic gallery of street images, in Hungry Planet: What the World Eats, p. 131).
    IND04_0008_xxf1.jpg
  • Betel nuts for sale at the Sunday market in Wangdi Phodrang, Bhutan, a two-hour walk from Shingkhey village. Betel nut is a mildly narcotic seed eaten with lime paste and a green leaf. Over time it decays the teeth and dyes the mouth of the user red. Although it's not considered a food, it is a plant item chewed by many all over Asia, and kept in the mouth like chewing tobacco. (Supporting image from the project Hungry Planet: What the World Eats.)
    BHU01_0026_xf1bs.jpg
  • Betel nut vendor takes a drink of water between customers in Varanasi, India. Betel nut is a mildly narcotic seed eaten with lime paste and a green leaf. Over time it decays the teeth and dyes the mouth of the user red. Although it's not considered a food, it is a plant item chewed by many all over Asia, and kept in the mouth like chewing tobacco. (From a photographic gallery of street images, in Hungry Planet: What the World Eats, p. 131).
    IND04_0008_xxf1.jpg
  • The spit-out remains of a chewed-up betel nut, found at the Sunday market in Wangdi Phodrang, Bhutan. Betel nut is a mildly narcotic seed eaten with lime paste and a green leaf. Over time it decays the teeth and dyes the mouth of the user red. Although it's not considered a food, it is a plant item chewed by many all over Asia, and kept in the mouth like chewing tobacco. (Supporting image from the project Hungry Planet: What the World Eats.)
    BHU01_0027_xf1bs.jpg

Peter Menzel Photography

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