Show Navigation
Environment All Galleries

Nukes

175 images Created 30 Jan 2013

Loading ()...

  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab bore hole at dawn. The bore hole has seismic monitoring equipment in it. (1987]
    KAZ_SCI_NUKE_01_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Staff at the Karkarlinsk Field lab bore hole seismic monitor. (1987]
    KAZ_SCI_NUKE_02_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab in frozen February. (1987]
    KAZ_SCI_NUKE_03_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab. (1987]
    KAZ_SCI_NUKE_04_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab bore hole at dawn. Jet from Altna Ata to Moscow. (1987]
    KAZ_SCI_NUKE_05_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab bore hole seismic monitor. Jon Berger (left], with a technician checks the wiring as a heavy booted Soviet scientist descends the stairs. (1987]
    KAZ_SCI_NUKE_06_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Seismic monitor station at Karkarlinsk, Kazakhstan. Frozen landscape: -26F in February. (1987]
    KAZ_SCI_NUKE_07_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Americans and Soviets gather for a group portrait at the Karkarlinsk Field lab. (1987]
    KAZ_SCI_NUKE_08_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab. Early morning party in Soviet dorm with Americans and Soviets. (1987]
    KAZ_SCI_NUKE_10_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. American scientists check wiring as a heavy booted Soviet scientist descends the frozen stairs at the Karkarlinsk Field lab seismic monitors surrounding a borehole. (1987]
    KAZ_SCI_NUKE_09_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab. Jon Berger and Stolrov pass the time playing a game of chess (American vs. Soviet]. MODEL RELEASED (1987]
    KAZ_SCI_NUKE_11_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab. Workers pass the time playing a game of chess (American, Jon Berger vs. Soviet, Stolyrov]. MODEL RELEASED (1987]
    KAZ_SCI_NUKE_12_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk sauna: American and Soviet scientists and workers relax in the local sauna. (1987]
    KAZ_SCI_NUKE_13_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk sauna: American and Soviet scientists and workers relax after a local sauna. (1987]
    KAZ_SCI_NUKE_14_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Town Hall in Karaganda, Republic of Kazakhstan (former USSR]. (1987]
    KAZ_SCI_NUKE_16_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Jon Berger at the Karkarlinsk Field lab. MODEL RELEASED (1987]
    KAZ_SCI_NUKE_17_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Seismic monitor station at Karkarlinsk, Kazakhstan. Ice crystals at dawn in the frozen landscape: -26F (1987]
    KAZ_SCI_NUKE_15_xs.jpg
  • The Natural Resources Defense Council (NRDC]: Seismic Monitor Nuclear test project in The Republic of Kazakhstan. In 1986 the USSR Academy of Sciences allowed the NRDC to install seismic monitoring instruments within a few hundred kilometers of their nuclear test site to verify that the USSR was not testing nuclear weapons underground during the nuclear test ban. By allowing this monitoring on their soil and by monitoring near the Nevada test site in the USA, mutual trust was built that facilitated the end of the Cold War. Karkarlinsk Field lab. Soviet worker making a call from the camp phone. (1987]
    KAZ_SCI_NUKE_18_xs.jpg
  • A Defense Department specialist in a radiation suit on the Nuclear Test Site in the Nevada desert outside Las Vegas holds a Geiger counter during a simulated nuclear weapons accident test. In the "Broken Arrow" (any accident involving a nuclear weapon) exercise, the Defense Department and the Department of Energy simulated the crash of a helicopter carrying nuclear weapons. Various agencies and departments then practiced coordinating their responses in an effort to find and clean up the mess. Real radioactive material was spread around the desert and a large number of soldiers simulated the angry residents of a nearby town..1981
    USA_SCI_NUKE_01_xs.jpg
  • Defense Department specialists in radiation suits on the Nuclear Test Site in the Nevada desert outside Las Vegas hold Geiger counters during a simulated nuclear weapons accident test. In the "Broken Arrow" (any accident involving a nuclear weapon) exercise, the Defense Department and the Department of Energy simulated the crash of a helicopter carrying nuclear weapons. Various agencies and departments then practiced coordinating their responses in an effort to find and clean up the mess. Real radioactive material was spread around the desert and a large number of soldiers simulated the angry residents of a nearby town..1981
    USA_SCI_NUKE_02_xs.jpg
  • Site Trinity ground zero, the still radioactive piece of desert in the White Sands Missile Range, which was witness to the world's first nuclear explosion on August 6, 1945. Each year the site is open to the public for one day. Visitors to ground zero listen to a Manhattan Project scientist reminisce while standing next to an original Fat Man bomb casing, on loan from the nearby Atomic Museum in Albuquerque, New Mexico.
    USA_SCI_NUKE_03_xs.jpg
  • New Mexico, First atomic bomb test site: Site Trinity ground zero, the still radioactive piece of desert in the White Sands Missile Range, which was witness to the world's first nuclear explosion on August 6, 1945. Each year the site is open to the public for one day. Visitors to ground zero listen to a Manhattan Project scientist reminisce while standing next to an original Fat Man bomb casing, on loan from the nearby Atomic Museum in Albuquerque, New Mexico.
    USA_SCI_NUKE_04_xs.jpg
  • New Mexico, .First atomic bomb test site: Site Trinity, visitors lined up to enter the McDonald farmhouse, restored by the National Park Service. The world's first atomic bomb was assembled here before it was hoisted onto a tower for the detonation that ushered in the nuclear age. (1984).
    USA_SCI_NUKE_05_xs.jpg
  • First atomic bomb test site: Site Trinity ground zero, the still radioactive piece of desert in the White Sands Missile Range, which was witness to the world's first nuclear explosion on August 6, 1945. Each year the site is open to the public for one day. Visitors to ground zero listen to a Manhattan Project scientist reminisce while standing next to an original Fat Man bomb casing, on loan from the nearby Atomic Museum in Albuquerque, New Mexico. .Test site of the first atomic bomb, part of the Manhattan Project. Trinity was detonated at 5:29am on 16th July 1945 at the Los Alamos site in New Mexico, USA.  (1984)
    USA_SCI_NUKE_06_xs.jpg
  • Nevada Nuclear Test site: crater created by Project Sedan nuclear blast in 1969 is 320 feet deep by 1289 feet in diameter. (1988)
    USA_SCI_NUKE_07_xs.jpg
  • First atomic bomb test site: Site Trinity ground zero, the still radioactive piece of desert in the White Sands Missile Range was witness to the world's first nuclear explosion on August 6, 1945. Each year the site is open to the public for one day. An exorcism is performed by a Catholic Priest, here sprinkling holy water, as visitors to ground zero mill around an original Fat Man bomb casing, on loan from the nearby Atomic Museum in Albuquerque, New Mexico. 1986.
    USA_SCI_NUKE_08_xs.jpg
  • View of the Diablo Canyon Nuclear Power Plant in California. The plant has two reactor units, which combined have a net power capacity of nearly 1200 megawatts. The plant, operated by the Pacific Gas and Electric company, became commercially operational in 1977.
    USA_SCI_NUKE_09_xs.jpg
  • Wild flower and trinitite. Trinitite is a metamorphic rock found in New Mexico. It was formed during the explosion of the world's first nuclear bomb, code-named Trinity, on 16 July 1945. Trinitite is an altered silicate resembling rough green glass. The extreme temperatures of the nuclear explosion melted the native sandstone soil. As the material cooled it formed a glassy structure. The greenish color comes from iron in the sand - the same iron, which as an oxide gave the original sand its reddish color. Most of the original radioactivity of the trinitite has gone in the last decades. First atomic bomb test site. (1984).
    USA_SCI_NUKE_10_xs.jpg
  • Washington, DC: 4-year, 24-hour nuclear weapons vigil-protest in front of white house. (1984)
    USA_SCI_NUKE_11_xs.jpg
  • Underground storage of radioactive wastes. Measuring ceiling-floor movement. This is one of the chambers of the Waste Isolation Pilot Project (WIPP), 700 meters below ground. WIPP is a research project to determine the suitability of the local salt rocks as a storage site for highly radioactive transuranic waste from nuclear power stations. Such waste materials may have radioactive half-lives of thousands of years, and so must be isolated in a geologically stable environment. On the left is an experiment testing the design of containers carrying vitrified waste. The mine is located near Carlsbad, New Mexico, USA. (1998)
    USA_SCI_NUKE_13_xs.jpg
  • Safety tour at underground storage of radioactive wastes. This is one of the chambers of the Waste Isolation Pilot Project (WIPP), 700 meters below ground. WIPP is a research project to determine the suitability of the local salt rocks as a storage site for highly- radioactive transuranic waste from nuclear power stations. Such waste materials may have radioactive half-lives of thousands of years, and so must be isolated in a geologically stable environment. On the left is an experiment testing the design of containers carrying vitrified waste. The mine is located near Carlsbad, New Mexico, USA. (1998)
    USA_SCI_NUKE_14_xs.jpg
  • First atomic bomb test site: Site Trinity ground zero, the still radioactive piece of desert in the White Sands Missile Range was witness to the world's first nuclear explosion on August 6, 1945. Each year the site is open to the public for one day. An exorcism is performed by a Catholic Priest, here sprinkling holy water, as visitors to ground zero mill around an original Fat Man bomb casing, on loan from the nearby Atomic Museum in Albuquerque, New Mexico. 1986.
    USA_SCI_NUKE_12_xs.jpg
  • Salt tailing pile in foreground of an above ground view of underground storage of radioactive wastes for the Waste Isolation Pilot Project (WIPP), 700 meters below ground. WIPP is a research project to determine the suitability of the local salt rocks as a storage site for highly- radioactive transuranic waste from atomic power stations. Such waste materials may have radioactive half-lives of thousands of years, and so must be isolated in a geologically stable environment. On the left is an experiment testing the design of containers carrying vitrified waste. The mine is located near Carlsbad, New Mexico, USA. (1998)
    USA_SCI_NUKE_16_xs.jpg
  • Los Alamos National Lab, New Mexico. Richard Mah seen with A3 Uranium Projectile research. The uranium projectile is very dense and is used for armor piercing weapons. MODEL RELEASED (1998)
    USA_SCI_NUKE_17_xs.jpg
  • Above ground view of underground storage of radioactive wastes for the Waste Isolation Pilot Project (WIPP), 700 meters below ground. WIPP is a research project to determine the suitability of the local salt rocks as a storage site for highly- radioactive transuranic waste from nuclear power stations. Such waste materials may have radioactive half-lives of thousands of years, and so must be isolated in a geologically stable environment. On the left is an experiment testing the design of containers carrying vitrified waste. The mine is located near Carlsbad, New Mexico, USA. (1998)
    USA_SCI_NUKE_15_xs.jpg
  • Road to underground storage of radioactive wastes for the Waste Isolation Pilot Project (WIPP), 700 meters below ground (salt pond in foreground). WIPP is a research project to determine the suitability of the local salt rocks as a storage site for highly- radioactive transuranic waste from atomic power stations. Such waste materials may have radioactive half-lives of thousands of years, and so must be isolated in a geologically stable environment. On the left is an experiment testing the design of containers carrying vitrified waste. The mine is located near Carlsbad, New Mexico, USA. (1988)
    USA_SCI_NUKE_18_xs.jpg
  • Nevada Nuclear Test site- Used drill bits in the drilling storage yard for underground nuclear tests. (1988)
    USA_SCI_NUKE_19_xs.jpg
  • Above ground view of underground storage of radioactive wastes for the Waste Isolation Pilot Project (WIPP), 700 meters below ground. WIPP is a research project to determine the suitability of the local salt rocks as a storage site for highly- radioactive transuranic waste from nuclear power stations. Such waste materials may have radioactive half-lives of thousands of years, and so must be isolated in a geologically stable environment. On the left is an experiment testing the design of containers carrying vitrified waste. The mine is located near Carlsbad, New Mexico, USA. 1998.
    USA_SCI_NUKE_20_xs.jpg
  • Nuclear Winter test fire: brown smoke rises from smoldering brush fires, deliberately started to study the potential climatic effects of a nuclear war. The nuclear winter theory predicts that smoke from fires burning after a nuclear war would block sunlight, causing a rapid drop in temperature that would trigger serious ecological disturbance. The test burn took place in December 1986 on 500 acres of brush in Lodi Canyon, Los Angeles. Dripping napalm from a helicopter ignited the fire. Ground-based temperature sensors were used to study soil erosion. Various airborne experiments included smoke sampling & high-altitude infrared imaging from a converted U-2 spy plane.
    USA_SCI_NUKE_21_xs.jpg
  • Nuclear Winter test fire: brown smoke rises from smoldering brush fires, deliberately started to study the potential climatic effects of a nuclear war. The nuclear winter theory predicts that smoke from fires burning after a nuclear war would block sunlight, causing a rapid drop in temperature that would trigger serious ecological disturbance. The test burn took place in December 1986 on 500 acres of brush in Lodi Canyon, Los Angeles. Dripping napalm from a helicopter ignited the fire. Ground-based temperature sensors were used to study soil erosion. Various airborne experiments included smoke sampling & high-altitude infrared imaging from a converted U-2 spy plane.
    USA_SCI_NUKE_22_xs.jpg
  • Nuclear Winter test fire: fire crews rest while monitoring the brown smoke rising from smoldering brush fires, deliberately started to study the potential climatic effects of a nuclear war. The nuclear winter theory predicts that smoke from fires burning after a nuclear war would block sunlight, causing a rapid drop in temperature that would trigger serious ecological disturbance. The test burn took place in December 1986 on 500 acres of brush in Lodi Canyon, Los Angeles. Dripping napalm from a helicopter ignited the fire. Ground-based temperature sensors were used to study soil erosion. Various airborne experiments included smoke sampling & high-altitude infrared imaging from a converted U-2 spy plane.
    USA_SCI_NUKE_23_xs.jpg
  • Nuclear Winter test fire: brush fires deliberately started to study the potential climatic effects of a nuclear war. The nuclear winter theory predicts that smoke from fires burning after a nuclear war would block sunlight, causing a rapid drop in temperature that would trigger serious ecological disturbance. The test burn took place in December 1986 on 500 acres of brush in Lodi Canyon, Los Angeles. Dripping napalm from a helicopter ignited the fire. Ground-based temperature sensors were used to study soil erosion. Various airborne experiments included smoke sampling & high-altitude infrared imaging from a converted U-2 spy plane.
    USA_SCI_NUKE_24_xs.jpg
  • Scientist Richard Turco and Carl Sagan were on the scientific team that devised the concept of nuclear winter. Turco is seen here at the Nuclear Winter test fire: where a canyon outside Los Angeles was deliberately set on fire to study the potential climatic effects of a nuclear war. The nuclear winter theory predicts that smoke from fires burning after a nuclear war would block sunlight, causing a rapid drop in temperature that would trigger serious ecological disturbance. The test burn took place in December 1986 on 500 acres of brush in Lodi Canyon, Los Angeles. Dripping napalm from a helicopter ignited the fire. Ground-based temperature sensors were used to study soil erosion. Various airborne experiments included smoke sampling & high-altitude infrared imaging from a converted U-2 spy plane.
    USA_SCI_NUKE_25_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. MODEL RELEASED (1988).
    USA_SCI_NUKE_26_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. MODEL RELEASED (1988).
    USA_SCI_NUKE_27_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. MODEL RELEASED (1988).
    USA_SCI_NUKE_28_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. MODEL RELEASED (1988).
    USA_SCI_NUKE_29_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. (1988). Seen here "The Last S.A.L.T. Talks" sculpture group. (1988)
    USA_SCI_NUKE_30_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. (1988). Seen here "The Last S.A.L.T. Talks" sculpture group. (1988)
    USA_SCI_NUKE_31_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. (1988). Seen here "The Last S.A.L.T. Talks" sculpture group. (1988)
    USA_SCI_NUKE_32_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. 24 is a "Radioactive Crucifix" with an afternoon rainbow. (1988).
    USA_SCI_NUKE_33_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. 24 is a "Radioactive Crucifix" with an afternoon rainbow. (1988).
    USA_SCI_NUKE_34_xs.jpg
  • An "atomic sculpture" made from Los Alamos National Laboratory scraps, by Tony Price (1937-2000), of Santa Fe, New Mexico. Tony Price, bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. (1988).
    USA_SCI_NUKE_35_xs.jpg
  • Tony Price (1937-2000), bought scrap from the nearby Los Alamos National Lab weekly public auctions, and built sculptures which convey anti-nuclear themes and messages. MODEL RELEASED (1988).
    USA_SCI_NUKE_36_xs.jpg
  • Tony Price (1937-2000), here with his family, created sculptures from scrap metal bought at the salvage yard at the Los Alamos National Lab and built sculptures which convey anti-nuclear themes and messages. Santa Fe, New Mexico MODEL RELEASED (1988)
    USA_SCI_NUKE_37_xs.jpg
  • Titan Missile Museum, Green Valley, Arizona. When the SALT Treaty called for the de-activation of the 18 Titan missile silos that ring Tucson, volunteers at the Pima Air Museum asked if one could be retained for public tours. After much negotiation, including additional talks with SALT officials, the Green Valley complex of the 390th Strategic Missile Wing was opened to the public. Deep in the ground, behind a couple of 6,000 pound blast doors is the silo itself. The 110 foot tall missile weighed 170 tons when it was fueled and ready to fly. Seen here empty on its launch pad.
    USA_SCI_NUKE_38_xs.jpg
  • Titan Missile Museum, Green Valley, Arizona. When the SALT Treaty called for the de-activation of the 18 Titan missile silos that ring Tucson, volunteers at the Pima Air Museum asked if one could be retained for public tours. After much negotiation, including additional talks with SALT officials, the Green Valley complex of the 390th Strategic Missile Wing was opened to the public. Deep in the ground, behind a couple of 6,000 pound blast doors is the silo itself. The 110 foot tall missile weighed 170 tons when it was fueled and ready to fly. Seen here empty on its launch pad.
    USA_SCI_NUKE_39_xs.jpg
  • Control Center of the Titan Missile Museum, Green Valley, Arizona. When the SALT Treaty called for the de-activation of the 18 Titan missile silos that ring Tucson, volunteers at the Pima Air Museum asked if one could be retained for public tours. After much negotiation, including additional talks with SALT officials, the Green Valley complex of the 390th Strategic Missile Wing was opened to the public. On display is a 110 foot tall missile, which weighed 170 tons when it was fueled and ready to fly.
    USA_SCI_NUKE_40_xs.jpg
  • At Los Alamos, New Mexico, on the grounds of the Los Alamos National Lab, the Bradbury Science Center puts a positive spin on the development of nuclear weapons with historical displays. Here a plaster Robert Oppenheimer is frozen in time watching an endless-loop video of the mushroom clouds of atomic bomb tests. Other exhibits have sanitized versions of nuclear weapons casings and hand-on nuclear weapons design stations. Los Alamos, New Mexico.
    USA_SCI_NUKE_41_xs.jpg
  • At Los Alamos, New Mexico, on the grounds of the Los Alamos National Lab, the Bradbury Science Center puts a positive spin on the development of nuclear weapons with historical displays. Exhibits have sanitized versions of nuclear weapons casings and hand-on nuclear weapons design stations.
    USA_SCI_NUKE_42_xs.jpg
  • Operated by the Department of Energy (DOE), the National Atomic Museum contains a large collection of declassified nuclear technology. Since its opening in 1969, the objective of the National Atomic museum has been to provide a readily accessible repository of educational materials, and information on the Atomic Age. In addition, the museum's goal is to preserve, interpret, and exhibit to the public memorabilia of this Age. In late 1991 the museum was chartered by Congress as the United States' only official Atomic museum. Los Alamos, New Mexico. (1984)
    USA_SCI_NUKE_43_xs.jpg
  • Operated by the Department of Energy (DOE), the National Atomic Museum contains a large collection of declassified nuclear technology. Since its opening in 1969, the objective of the National Atomic museum has been to provide a readily accessible repository of educational materials, and information on the Atomic Age. In addition, the museum's goal is to preserve, interpret, and exhibit to the public memorabilia of this Age. In late 1991 the museum was chartered by Congress as the United States' only official Atomic museum. Museum Director posing by Little Boy and Fat Man, the atomic bombs dropped on Japan. There were two of each built in case the first one failed to explode. Los Alamos, New Mexico. MODEL RELEASED (1984)
    USA_SCI_NUKE_44_xs.jpg
  • Operated by the Department of Energy (DOE), the National Atomic Museum contains a large collection of declassified nuclear technology. Since its opening in 1969, the objective of the National Atomic museum has been to provide a readily accessible repository of educational materials, and information on the Atomic Age. In addition, the museum's goal is to preserve, interpret, and exhibit to the public memorabilia of this Age. In late 1991 the museum was chartered by Congress as the United States' only official Atomic museum. A family inspects Little Boy and Fat Man, the atomic bombs dropped on Japan. There were two of each built in case the first one failed to explode. Los Alamos, New Mexico. MODEL RELEASED (1984)
    USA_SCI_NUKE_45_xs.jpg
  • At Los Alamos, New Mexico, on the grounds of the Los Alamos National Lab, the Bradbury Science Center puts a positive spin on the development of nuclear weapons with historical displays. Exhibits have sanitized versions of nuclear weapons casings and hand-on nuclear weapons design stations. Los Alamos, New Mexico. (1984)
    USA_SCI_NUKE_47_xs.jpg
  • Street signs of two of the most famous names in the history of Nuclear bombs; Los Alamos, New Mexico. (Site) Trinity Drive and Oppenheimer Drive. (1985)
    USA_SCI_NUKE_48_xs.jpg
  • Operated by the Department of Energy (DOE), the National Atomic Museum contains a large collection of declassified nuclear technology. Since its opening in 1969, the objective of the National Atomic museum has been to provide a readily accessible repository of educational materials, and information on the Atomic Age. In addition, the museum's goal is to preserve, interpret, and exhibit to the public memorabilia of this Age. In late 1991 the museum was chartered by Congress as the United States' only official Atomic museum. A family inspects Little Boy and Fat Man, the atomic bombs dropped on Japan. There were two of each built in case the first one failed to explode. Los Alamos, New Mexico MODEL RELEASED (1984)
    USA_SCI_NUKE_46_xs.jpg
  • Star Wars research: neutral particle beam accelerator at Los Alamos National Laboratory. The accelerator was part of the Reagan White House project for a space-based accelerator that could produce a high-energy, uncharged particle beam that might examine, disarm, & even destroy distant objects (such as ballistic missiles), as part of America's Strategic Defense Initiative (SDI) - the "Star Wars" program. Neutral (uncharged) particle beams are necessary because the influence of the Earth's magnetic field on electrically charged particles would cause them to travel in spirals. Los Alamos, New Mexico. (1988)
    USA_SCI_NUKE_50_xs.jpg
  • Star Wars research: neutral particle beam accelerator at Los Alamos National Laboratory. The accelerator was part of the Reagan White House project for a space-based accelerator that could produce a high-energy, uncharged particle beam that might examine, disarm, & even destroy distant objects (such as ballistic missiles), as part of America's Strategic Defense Initiative (SDI) - the "Star Wars" program. Neutral (uncharged) particle beams are necessary because the influence of the Earth's magnetic field on electrically charged particles would cause them to travel in spirals. Los Alamos, New Mexico. (1988)
    USA_SCI_NUKE_49_xs.jpg
  • Hungarian-born American physicist Edward Teller, who is best known as "the father of the hydrogen bomb". Seen here at his home in Stanford, California. Born in 1908, he obtained his Ph.D. at the University of Leipzig. He left Europe in the 1930s because of the Nazi threat. During World War II he worked at Los Alamos on the development of the atom bomb. In the late 1940s & early 1950s he championed development of the H-bomb & achieved the crucial technical breakthrough that made the bomb possible. The first H-bomb was exploded in the South Pacific in 1952. MODEL RELEASED.Teller died in Stanford, California on September 9, 2003. (Photograph, 1988)
    USA_SCI_NUKE_51_xs.jpg
  • The road to Los Alamos, New Mexico, with a full moon above a dangerous curve. (1988)
    USA_SCI_NUKE_53_xs.jpg
  • Hungarian-born American physicist Edward Teller, who is best known as "the father of the hydrogen bomb". Seen here at his home in Stanford, California. Born in 1908, he obtained his Ph.D. at the University of Leipzig. He left Europe in the 1930s because of the Nazi threat. During World War II he worked at Los Alamos on the development of the atom bomb. In the late 1940s & early 1950s he championed development of the H-bomb & achieved the crucial technical breakthrough that made the bomb possible. The first H-bomb was exploded in the South Pacific in 1952. MODEL RELEASED.Teller died in Stanford, California on September 9, 2003. (Photograph, 1988)
    USA_SCI_NUKE_52_xs.jpg
  • Operated by the Department of Energy (DOE), the National Atomic Museum contains a large collection of declassified nuclear technology. Since its opening in 1969, the objective of the National Atomic museum has been to provide a readily accessible repository of educational materials, and information on the Atomic Age. In addition, the museum's goal is to preserve, interpret, and exhibit to the public memorabilia of this Age. In late 1991 the museum was chartered by Congress, as the United States' only official Atomic museum. Nuclear Missiles: Shark, Mace, Matador (left to right). Los Alamos, New Mexico. 1992.
    USA_SCI_NUKE_54_xs.jpg
  • Hungarian-born American physicist Edward Teller, who is best known as "the father of the hydrogen bomb". Seen here at his home in Stanford, California with his wife in their living room. Born in 1908, he obtained his Ph.D. at the University of Leipzig. He left Europe in the 1930s because of the Nazi threat. During World War II he worked at Los Alamos on the development of the atom bomb. In the late 1940s & early 1950s he championed development of the H-bomb & achieved the crucial technical breakthrough that made the bomb possible. The first H-bomb was exploded in the South Pacific in 1952. MODEL RELEASED.Teller died in Stanford, California on September 9, 2003.
    USA_SCI_NUKE_55_xs.jpg
  • Hungarian-born American physicist Edward Teller, who is best known as "the father of the hydrogen bomb". Seen here at his home in Stanford, California. Born in 1908, he obtained his Ph.D. at the University of Leipzig. He left Europe in the 1930s because of the Nazi threat. During World War II he worked at Los Alamos on the development of the atom bomb. In the late 1940s & early 1950s he championed development of the H-bomb & achieved the crucial technical breakthrough that made the bomb possible. The first H-bomb was exploded in the South Pacific in 1952. MODEL RELEASED.Teller died in Stanford, California on September 9, 2003.
    USA_SCI_NUKE_56_xs.jpg
  • John Manley - assistant to Oppenheimer for the Manhattan Project. Photographed in one of the original boy's camp lodges in Los Alamos, New Mexico, (1988) The Manhattan Project refers to the effort during World War II by the United States, in collaboration with the United Kingdom, Canada, and other European physicists, to develop the first nuclear weapons. Formally designated as the Manhattan Engineering District (MED), it refers specifically to the period of the project from 1942-1946 under the control of the U.S. Army Corps of Engineers, under the administration of General Leslie R. Groves, with its scientific research directed by the American physicist J. Robert Oppenheimer. The project succeeded in developing and detonating three nuclear weapons in 1945. MODEL RELEASED
    USA_SCI_NUKE_58_xs.jpg
  • Operated by the Department of Energy (DOE), the National Atomic Museum contains a large collection of declassified nuclear technology. Since its opening in 1969, the objective of the National Atomic museum has been to provide a readily accessible repository of educational materials, and information on the Atomic Age. In addition, the museum's goal is to preserve, interpret, and exhibit to the public memorabilia of this Age. In late 1991 the museum was chartered by Congress as the United States' only official Atomic museum. Los Alamos, New Mexico. (1984)
    USA_SCI_NUKE_57_xs.jpg
  • Particle Beam Fusion Accelerator used to test weapon components at Sandia National Laboratory site at Albuquerque, New Mexico USA. Sandia was established in 1945 as a weapons stockpiling site. Since then, Sandia has diversified to study a variety of science applications. These include research and development in fossil, solar, geothermal and nuclear energy production, nuclear waste management and environmental research. Sandia is also responsible for the design and development of non- nuclear components for atomic weapons. (1984)
    USA_SCI_NUKE_59_xs.jpg
  • Particle Beam Fusion Accelerator used to test weapon components at Sandia National Laboratory site at Albuquerque, New Mexico USA. Sandia was established in 1945 as a weapons stockpiling site. Since then, Sandia has diversified to study a variety of science applications. These include research and development in fossil, solar, geothermal and nuclear energy production, nuclear waste management and environmental research. Sandia is also responsible for the design and development of non- nuclear components for atomic weapons. (1984)
    USA_SCI_NUKE_60_xs.jpg
  • Operated by the Department of Energy (DOE), the National Atomic Museum contains a large collection of declassified nuclear technology. Since its opening in 1969, the objective of the National Atomic museum has been to provide a readily accessible repository of educational materials, and information on the Atomic Age. In addition, the museum's goal is to preserve, interpret, and exhibit to the public memorabilia of this Age. In late 1991 the museum was chartered by Congress as the United States' only official Atomic museum. A family inspects Little Boy and Fat Man, the atomic bombs dropped on Japan. There were two of each built in case the first one failed to explode. Los Alamos, New Mexico. (1984).Information about the National Atomic Museum from .http://www.atomicmuseum.com/ [moved from lot 4]
    USA_SCI_NUKE_61_xs.jpg
  • Physics: Raychem Corporation's CEO Paul Cook in electron accelerator radiation chamber (plastic pipe irradiation) MODEL RELEASED [1987]
    USA_SCI_PHY_13_xs.jpg
  • Physics: Electron beam accelerator operator at RayChem Corp. Uriel Lopez, beam operator. MODEL RELEASED
    USA_SCI_PHY_27_xs.jpg
  • Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII.
    USA_101002_274_x.jpg
  • Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII.
    USA_101002_277_x.jpg
  • Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII.
    USA_101002_272_x.jpg
  • Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII.
    USA_101002_281_x.jpg
  • Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII.
    USA_101002_284_x.jpg
  • Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII.
    USA_101002_283_x.jpg
  • Evan Menzel at the Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII. MODEL RELEASED.
    USA_101002_295_x.jpg
  • Evan Menzel at the Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII. MODEL RELEASED.
    USA_101002_298_x.jpg
  • Peter Menzel at the Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII. MODEL RELEASED.
    USA_101002_302_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_338_x.jpg
  • Peter Menzel at the Bradbury Science Museum, Los Alamos, NM. Displays of Manhatten Project that developed the world's first atomic bombs during WWII. MODEL RELEASED.
    USA_101002_307_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_342_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_341_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_344_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_348_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_354_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_349_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_355_x.jpg
  • National Museum of Nuclear Sciece and History, Albuquerque, NM
    USA_101003_356_x.jpg
Next
View: 100 | All

Peter Menzel Photography

  • Home
  • Legal & Copyright
  • About Us
  • Image Archive
  • Search the Archive
  • Exhibit List
  • Lecture List
  • Agencies
  • Contact Us: Licensing & Inquiries