Episodios

  • Explorer 1 Discovers Van Allen Radiation Belts

    Explorer 1 Discovers Van Allen Radiation Belts
    Jan 31 2026
    # The Day Explorer 1 Opened America's Eyes to Space (January 31, 1958)

    On January 31, 1958, at 10:48 PM EST, a modified Jupiter-C rocket roared to life at Cape Canaveral, Florida, carrying America's first satellite into orbit. After the humiliation of watching the Soviet Union launch Sputnik 1 and Sputnik 2 the previous fall, the United States desperately needed a win in the rapidly escalating Space Race. Explorer 1 delivered—and then some.

    The satellite itself was surprisingly modest: a sleek, pencil-shaped cylinder just 80 inches long and 6.25 inches in diameter, weighing a mere 30.66 pounds. But what it lacked in size, it made up for in scientific ambition. Designed by a team led by rocket pioneer Wernher von Braun and instrumented by physicist James Van Allen from the University of Iowa, Explorer 1 carried a cosmic ray detection package that would make the first major scientific discovery of the Space Age.

    The launch came after a nail-biting series of delays and one spectacular failure. The Navy's Vanguard rocket had exploded on the launch pad just two months earlier in a disaster the press cruelly dubbed "Kaputnik." The pressure was intense. When Explorer 1 finally achieved orbit, von Braun and his team at the Jet Propulsion Laboratory anxiously waited for confirmation. Due to a calculation error, they expected the satellite's signal much earlier than it actually appeared, leading to agonizing minutes of uncertainty before receiving the joyous confirmation: "We're in!"

    But Explorer 1's real legacy wasn't just getting America into space—it was what the satellite discovered up there. Van Allen's instruments detected something unexpected: regions of intense radiation trapped by Earth's magnetic field, belts of charged particles surrounding our planet like invisible donuts. These became known as the Van Allen radiation belts, and their discovery fundamentally changed our understanding of Earth's interaction with the solar wind and cosmic radiation.

    The radiation readings were so intense at certain altitudes that Van Allen initially thought his instruments had malfunctioned. The Geiger counters were actually saturating—being overwhelmed by radiation levels far higher than anticipated. It took data from subsequent Explorer missions to confirm that these were real radiation zones, not instrument errors.

    Explorer 1 continued transmitting data until May 23, 1958, though its batteries died and it remained in orbit as a silent sentinel until finally burning up in Earth's atmosphere on March 31, 1970—after more than 58,000 orbits spanning twelve years.

    The success transformed America's space program from embarrassed also-ran to serious contender. It led directly to the creation of NASA later that year and helped establish the principle that American space efforts would prioritize scientific discovery, not just Cold War showmanship.

    Today, understanding the Van Allen belts remains crucial for protecting satellites and astronauts from radiation. Every spacecraft venturing beyond low Earth orbit must account for these zones that Explorer 1 first revealed. Not bad for a satellite smaller than most people and lighter than a large dog!

    The tiny Explorer 1 proved that in the space race, it wasn't just about getting there first—it was about what you discovered when you arrived.


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  • Hitler's Rise Sparked History's Greatest Scientific Brain Drain

    Hitler's Rise Sparked History's Greatest Scientific Brain Drain
    Jan 30 2026
    # January 30, 1933: Adolf Hitler Becomes Chancellor — Launching Science into Its Darkest Chapter

    On January 30, 1933, an event occurred that would create one of the most catastrophic brain drains in scientific history. Adolf Hitler was appointed Chancellor of Germany, and within months, the Nazi regime began systematically purging Jewish scientists and intellectuals from German universities and research institutions.

    What makes this date so pivotal for science history is the sheer magnitude of genius that would soon flee Germany. In the early 1930s, Germany was the undisputed world leader in physics and chemistry. German universities in Göttingen, Berlin, and Munich were where the quantum revolution was happening in real-time. The country had produced more Nobel Prize winners than any other nation.

    Then came the Law for the Restoration of the Professional Civil Service in April 1933, which removed Jewish employees from government positions, including universities. The effect was immediate and devastating.

    **The Exodus of Giants:**

    Albert Einstein, already touring abroad, wisely never returned to Germany. He settled at Princeton's Institute for Advanced Study. Max Born, who would win the Nobel Prize for his fundamental work in quantum mechanics, fled to Britain. James Franck resigned his position in protest even before being forced out. Lise Meitner, who would co-discover nuclear fission, eventually escaped to Sweden in 1938. Hans Bethe, future Nobel laureate who would unlock the secret of how stars shine, moved to America.

    The list goes on: Edward Teller, Eugene Wigner, John von Neumann, Leo Szilard, Erwin Schrödinger (who left in protest), and countless others. Approximately 1,600 scholars were dismissed in the first wave alone.

    **The Beneficiaries:**

    America and Britain became the unexpected winners. The Institute for Advanced Study in Princeton became a haven for displaced European intellectuals. Universities like Berkeley, Columbia, and Chicago suddenly had access to the finest minds in physics. Britain's universities absorbed many refugees who enriched their scientific establishments immeasurably.

    **The Ultimate Irony:**

    Many of these exiled scientists would contribute to the Manhattan Project, the very weapon that helped defeat Nazi Germany. The regime that expelled them because of racial ideology essentially handed the Allies their most powerful weapon. Hitler's Germany, meanwhile, never developed an atomic bomb, partly because they'd expelled or driven away the expertise needed to build one.

    The brain drain extended beyond physics into mathematics, chemistry, biology, and medicine. Germany's loss was calculated not just in individual brilliance but in the collaborative networks that made German science so productive. When you remove a quarter to a third of your top scientists, you don't just lose those individuals—you destroy the ecosystem of seminars, collaborations, and mentorships that produce future generations.

    This single political event on January 30, 1933, shifted the center of scientific gravity from Central Europe to America, where it remains today. It stands as perhaps history's greatest example of how political ideology can destroy scientific enterprise and how the free movement of people and ideas is essential for scientific progress.

    The lesson endures: science thrives on diversity, openness, and the free exchange of ideas across borders. When nationalism and prejudice interfere, everyone loses—except perhaps the societies wise enough to welcome those who are forced to flee.


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  • Death Valley's Sailing Stones Mystery Finally Solved

    Death Valley's Sailing Stones Mystery Finally Solved
    Jan 29 2026
    # The Racetrack Playa Mystery Gets Solved! (January 29, 2014)

    On January 29, 2014, scientists finally cracked one of geology's most delightful and perplexing mysteries: **the sailing stones of Death Valley's Racetrack Playa**!

    For decades, researchers had been utterly baffled by a bizarre phenomenon in one of Earth's most inhospitable locations. At Racetrack Playa, a dry lakebed in California's Death Valley, heavy rocks—some weighing up to 700 pounds—mysteriously moved across the flat desert floor, leaving long trails behind them in the cracked mud. These weren't pebbles being blown by wind; these were massive boulders apparently gliding across the landscape all by themselves, sometimes traveling over 1,500 feet and leaving perfectly etched grooves in their wake.

    The sailing stones had inspired wild speculation since the 1940s. Theories ranged from hurricane-force winds to magnetic fields to dust devils to ice sheets to (naturally) aliens. Scientists had studied the phenomenon for over 60 years, setting up time-lapse cameras and GPS trackers, but the rocks stubbornly refused to move when anyone was watching. It was like trying to catch the Tooth Fairy in action.

    Enter Richard Norris, a paleobiologist from Scripps Institution of Oceanography, and his cousin James Norris, an engineer. In 2011, they installed a weather station and GPS units on several rocks, then waited. And waited. The playa is one of the flattest places on Earth and one of the driest, receiving only about 2 inches of rain per year.

    Then, on January 29, 2014, magic happened—or rather, science happened! The researchers witnessed the rocks moving for the first time in scientific history. The answer? A perfect storm of rare conditions: During winter, the playa occasionally floods with a few inches of water. When temperatures drop at night, the water freezes into thin sheets of "windowpane" ice. As the sun rises and the ice begins to melt and break apart, light winds (just 10 mph!) push these floating ice sheets against the rocks. The ice acts like a giant frozen conveyor belt, slowly shoving the rocks across the slick muddy surface beneath.

    What made this discovery so charming was that the mechanism was simultaneously mundane and magical—no aliens required, but the precise conditions happened so rarely that nobody had ever caught it in action. The rocks moved at a glacial pace (pun intended) of about 2-6 meters per minute, and only when this Goldilocks combination of water, ice, wind, and temperature occurred.

    The team published their findings later that year in the journal PLOS ONE, complete with GPS data, time-lapse photography, and video evidence of rocks in motion. After 70+ years of scientific head-scratching, the mystery was solved by patient observation and good old-fashioned luck in being there at the right moment.

    The sailing stones remind us that Earth still holds mysteries in plain sight, and that sometimes the most obvious explanations elude us simply because we're not there at the precise moment when rare conditions align. It's a beautiful example of how persistence, clever instrumentation, and being in the right place at the right time can unlock nature's secrets—even ones hiding in one of the most visible, studied, and desolate places on the planet.


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  • 73 Seconds: The Challenger Disaster

    73 Seconds: The Challenger Disaster
    Jan 28 2026
    # The Challenger Disaster: January 28, 1986

    On January 28, 1986, at 11:38 a.m. EST, the Space Shuttle Challenger broke apart just 73 seconds after liftoff, killing all seven crew members aboard and becoming one of the most traumatic events in the history of space exploration.

    The mission, designated STS-51-L, was particularly notable because it carried Christa McAuliffe, a high school social studies teacher from Concord, New Hampshire, selected from over 11,000 applicants to be the first participant in NASA's Teacher in Space Project. Her presence meant that millions of schoolchildren across America were watching the launch live in their classrooms, making the disaster even more devastating to the nation's psyche.

    The crew also included Commander Francis "Dick" Scobee, Pilot Michael Smith, Mission Specialists Judith Resnik, Ellison Onizuka, and Ronald McNair, and Payload Specialist Gregory Jarvis. Resnik was one of America's first female astronauts, while Onizuka and McNair were trailblazers as Asian American and African American astronauts respectively.

    The launch had been delayed multiple times due to weather and technical issues. The night before, temperatures at Kennedy Space Center had dropped to near freezing—well below the acceptable range for shuttle launches. Engineers at Morton Thiokol, the company that manufactured the solid rocket boosters, expressed serious concerns about the O-rings, rubber seals designed to prevent hot gases from escaping the joints of the rocket boosters. These O-rings had never been tested at such low temperatures, and engineers warned they might lose their flexibility and fail to seal properly.

    Despite these warnings, NASA management, facing pressure from previous delays and eager to maintain the shuttle program's ambitious schedule, decided to proceed with the launch.

    The engineers' worst fears were realized. At liftoff, puffs of gray smoke were visible from the aft field joint of the right solid rocket booster—evidence that the cold had indeed compromised the O-ring's ability to seal. Hot gases began escaping and eventually burned through the external fuel tank, causing a catastrophic structural failure.

    The shuttle didn't explode in the traditional sense; rather, it broke apart due to aerodynamic forces. The crew cabin remained largely intact and continued upward before falling back to the Atlantic Ocean. Evidence suggests that at least some crew members survived the initial breakup and may have remained conscious during the fall.

    The disaster led to a 32-month suspension of the shuttle program. President Reagan appointed a special commission, known as the Rogers Commission, to investigate. Physicist Richard Feynman became famous for his simple but dramatic demonstration during the hearings—he dropped an O-ring into ice water to show how it lost resilience in cold temperatures, illustrating the fundamental flaw that NASA had ignored.

    The investigation revealed troubling patterns of organizational failure within NASA: normalizing deviance (accepting increasingly risky conditions as normal), communication breakdowns between engineers and management, and a flawed decision-making culture where schedule pressures overrode safety concerns.

    The Challenger disaster profoundly changed NASA. The agency implemented major safety reforms, redesigned the solid rocket boosters, and restructured its management approach. The tragedy remains a cautionary tale studied in engineering schools, business programs, and organizational psychology courses worldwide as a prime example of how groupthink, organizational pressure, and communication failures can lead to catastrophic results.

    Today, the crew is remembered at the Space Mirror Memorial at Kennedy Space Center and through various scholarships, schools, and facilities named in their honor. The Challenger's loss reminds us that exploration carries inherent risks and that the courage of those who venture into space deserves our utmost commitment to their safety.


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  • Edison Patents His Practical Incandescent Light Bulb

    Edison Patents His Practical Incandescent Light Bulb
    Jan 27 2026
    # January 27, 1880: Thomas Edison Receives Patent for His Electric Incandescent Lamp

    On this day in 1880, Thomas Alva Edison received U.S. Patent No. 223,898 for his electric incandescent lamp—a moment that would quite literally illuminate the future of human civilization!

    Now, here's where the story gets deliciously complicated: Edison didn't actually *invent* the light bulb. In fact, over twenty other inventors had created various forms of electric lighting before him. British inventor Joseph Swan had a working bulb, and scientists like Humphry Davy had demonstrated electric light decades earlier. So what made Edison's patent so significant?

    Edison's genius wasn't in the initial concept—it was in making the darn thing *practical*. Previous incandescent lamps had major problems: they burned out quickly (sometimes in minutes), required too much electric current, used platinum filaments that were prohibitively expensive, or needed vacuum pumps that didn't exist in most places.

    Edison and his team at Menlo Park, New Jersey, conducted thousands of experiments testing different filament materials. The legend says they tried everything from fishing line to beard hair (yes, really). They eventually discovered that a carbonized cotton thread, and later bamboo fiber, could glow for over 1,200 hours. But the filament was only part of the puzzle.

    Edison also perfected the vacuum inside the bulb (removing oxygen prevented the filament from burning up), developed a higher-resistance filament that required less current (making it economically viable), designed the screw base we still use today, and—perhaps most importantly—created an entire electrical distribution system to power his bulbs. He understood that a light bulb without accessible electricity was just an expensive paperweight.

    The patent granted on January 27, 1880, covered his specific improvements: a carbon filament of high resistance in a near-perfect vacuum. This wasn't just a scientific achievement; it was the cornerstone of a commercial empire. Edison would go on to found Edison Electric Light Company, which eventually became General Electric.

    The impact was staggering. Gas lighting had dominated for decades, but it was dangerous (explosions and fires), produced toxic fumes, and provided dim, flickering light. Edison's system changed everything: factories could operate around the clock, cities became safer and more vibrant at night, and reading after sunset became easier (revolutionizing education and literacy).

    Interestingly, Edison's relationship with Joseph Swan ended up in court over patent disputes in Britain, eventually leading to a merger of their companies. Edison was not only a brilliant inventor but also a shrewd—some would say ruthless—businessman who understood patents as weapons in commercial warfare.

    This patent also marked the beginning of the "War of the Currents" that would pit Edison's direct current (DC) system against George Westinghouse and Nikola Tesla's alternating current (AC) system, but that's another gloriously dramatic story for another day.

    Today, while we've moved on to LEDs and other technologies, that screw-base design from Edison's patent remains standard in billions of sockets worldwide. Every time you flip a light switch, you're benefiting from the work that culminated in that patent granted 146 years ago today—proof that sometimes the most revolutionary inventions aren't completely new ideas, but rather the perfection and systematization of existing ones.


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  • The Cullinan Diamond Discovery Changes History Forever

    The Cullinan Diamond Discovery Changes History Forever
    Jan 26 2026
    # January 26, 1905: The Cullinan Diamond is Discovered

    On January 26, 1905, Frederick Wells, the surface manager of the Premier Mine in South Africa, was making his routine inspection rounds when something extraordinary caught his eye. Protruding from the mine wall, about 18 feet below the surface, was a glint that would turn out to be the largest gem-quality rough diamond ever discovered.

    At first, Wells couldn't believe what he was seeing. The crystal was so enormous—roughly the size of a human fist—that he initially thought it might be a large piece of glass someone had planted as a practical joke. But this was no joke. What Wells had stumbled upon was a colossal 3,106.75-carat diamond, later named the Cullinan Diamond after Sir Thomas Cullinan, the mine's owner.

    To put this in perspective, imagine holding three-quarters of a pound of pure crystallized carbon in your hand. The diamond measured approximately 10 cm long, 6.5 cm wide, and 5 cm deep. It was so large that experts believed it was actually a fragment of an even larger crystal that had broken apart—a theory supported by the stone having one notably smooth, flat side, as if it had been cleaved from something even more massive. Geologists have fantasized for over a century about the other half of this crystal, which has never been found.

    The discovery sparked immediate sensation. The Transvaal Colony government purchased the diamond for £150,000 (roughly equivalent to $20 million today) and presented it to King Edward VII of Britain as a birthday gift in 1907. But there was one significant problem: how do you transport the world's most valuable object across 6,000 miles of ocean without it being stolen?

    The solution was brilliantly deceptive. While a decoy package traveled to England on a steamship under heavy guard—complete with armed detectives and deliberate publicity—the real Cullinan traveled via registered parcel post in a plain box. The audacious simplicity worked perfectly.

    Once in London, the question became: what do you do with such a monster? The legendary Amsterdam diamond cutter Joseph Asscher was chosen for the monumental task of cleaving the stone. Before making the first cut, Asscher studied the diamond for months, examining every flaw and inclusion. On February 10, 1908, with doctors standing by (in case he fainted from the pressure), Asscher placed his specially designed cleaver blade against the marked line and struck it with a steel rod. The blade broke. On the second attempt, the diamond split perfectly along the cleavage plane. According to legend, Asscher then promptly fainted—though this story may be apocryphal.

    The Cullinan was ultimately cut into nine major stones and 96 smaller brilliants. The two largest pieces became the Great Star of Africa (530.2 carats), now mounted in the British Royal Sceptre, and the Second Star of Africa (317.4 carats), set in the Imperial State Crown. These remain among the most famous diamonds in existence, on display in the Tower of London as part of the Crown Jewels.

    The discovery of the Cullinan Diamond represented more than just finding a big rock—it was a geological marvel that pushed our understanding of how diamonds form under extreme pressure and heat deep within Earth's mantle. It sparked scientific discussions about diamond crystallization that continue today, and raised questions about mega-crystals that still intrigue mineralogists.

    So on this date in 1905, one man's routine inspection turned into a moment that would literally crown the British monarchy with unprecedented brilliance.


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  • Wilson Bentley Captures First Snowflake Photograph in 1885

    Wilson Bentley Captures First Snowflake Photograph in 1885
    Jan 25 2026
    # The Birth of the Snowflake Whisperer: Wilson Bentley (January 25, 1885)

    On January 25, 1885, something magical happened in the frigid Vermont winter that would forever change how we see those delicate ice crystals falling from the sky. No, a snowflake didn't suddenly become sentient (that we know of), but something almost as remarkable occurred: Wilson Alwyn Bentley successfully photographed a single snow crystal for the first time in history.

    Picture this: a 19-year-old farm boy in Jericho, Vermont, hunched over a bellows camera attached to a microscope in a freezing shed, his breath carefully controlled so as not to melt his precious subject. After two winters of failed attempts and frozen fingers, Bentley finally captured an image that would launch him on a lifelong obsession with snowflakes.

    Using a technique that required the patience of a saint and the precision of a surgeon, Bentley would catch snowflakes on a blackboard, quickly select the most promising specimens with a wooden splint, and transfer them to a glass slide. Then came the race against time and his own body heat. He had to focus his microscope, adjust the exposure, and photograph the crystal before it melted—all while working in an unheated workspace to preserve his subjects.

    What makes this achievement even more impressive is the technology of the era. This was 1885—no digital cameras, no auto-focus, no instant results. Bentley was working with glass plates and long exposure times, photographing objects that could vanish in seconds from the slightest temperature change or errant breath.

    Over his lifetime, "Snowflake Bentley," as he became known, would photograph more than 5,000 snowflakes, never finding two that were identical. His work provided the first scientific evidence for the popular saying that "no two snowflakes are alike," though he preferred to call them "tiny miracles of beauty" and "ice flowers."

    But Bentley was more than just a photographer—he was a self-taught scientist whose meticulous observations contributed to meteorology and crystallography. He discovered that snowflake formations were related to atmospheric conditions, and his detailed records helped scientists understand precipitation patterns. The scientific establishment initially dismissed this farmer with no formal education, but his photographic evidence was undeniable.

    His 1931 book, "Snow Crystals," containing 2,453 of his photographs, remains a classic reference work. Tragically, Bentley died just weeks after its publication, from pneumonia he contracted after walking six miles home through a blizzard—killed, in a sense, by the very phenomenon he loved.

    Today, Bentley's pioneering technique laid the groundwork for all snow crystal photography and microscopy. His images have inspired artists, scientists, and winter-lovers for over a century. Every intricate snowflake design you see on holiday decorations or winter apparel can trace its accuracy back to this Vermont farmer who spent frigid winter days capturing frozen fractals.

    So the next time you see a snowflake, remember Wilson Bentley—the man who taught the world to see the extraordinary mathematics and beauty in something we might otherwise let melt unnoticed on our sleeves. He proved that groundbreaking science doesn't always require a laboratory or a PhD; sometimes it just requires curiosity, persistence, and a willingness to work with numb fingers in a freezing shed.


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  • Voyager 2 Reaches Uranus: First Ice Giant Flyby

    Voyager 2 Reaches Uranus: First Ice Giant Flyby
    Jan 24 2026
    # January 24, 1986: Voyager 2's Historic Encounter with Uranus

    Exactly forty years ago today, NASA's Voyager 2 spacecraft made history by becoming the first—and still the only—spacecraft to visit Uranus, the mysterious ice giant of our solar system. On January 24, 1986, Voyager 2 swooped within 50,600 miles (81,500 kilometers) of Uranus's cloud tops, revealing a world that had been little more than a fuzzy greenish dot through even the most powerful telescopes.

    The encounter was nothing short of spectacular. In a matter of hours, Voyager 2 transformed our understanding of this distant world, discovering ten new moons, two new rings, and measuring a magnetic field that was completely unexpected—tilted at a bizarre 60-degree angle from the planet's axis of rotation. Scientists were stunned to find that Uranus's magnetic field wasn't even centered on the planet but offset by about one-third of the planet's radius. This odd configuration generates a wildly asymmetrical magnetosphere unlike anything seen elsewhere in the solar system.

    Voyager 2's cameras captured haunting images of Uranus as an almost featureless pale blue-green sphere, earning it the reputation as the solar system's blandest planet. But this apparent tranquility was deceptive. The spacecraft revealed that Uranus rotates on its side, with its axis tilted 98 degrees—essentially rolling around the Sun like a ball rather than spinning like a top. This extreme tilt likely resulted from a massive collision with an Earth-sized object billions of years ago.

    The newly discovered moons—named after Shakespearean characters like Cordelia, Ophelia, Bianca, and Desdemona—were found shepherding Uranus's rings, keeping them in their narrow bands. The spacecraft also studied the five major moons known before the flyby, including Miranda, whose surface proved to be one of the most geologically bizarre landscapes in the solar system, featuring enormous canyons, terraced layers, and mismatched terrain that looked like a cosmic jigsaw puzzle.

    Perhaps most intriguing was Voyager 2's detection of Uranus's frigid atmosphere, where temperatures plunge to -224°C (-371°F), making it the coldest planetary atmosphere in the solar system—even colder than Neptune, despite being closer to the Sun. The spacecraft revealed that Uranus emits almost no internal heat, another unexplained mystery that continues to puzzle scientists today.

    The timing of this encounter was particularly poignant as it occurred just four days after the Challenger Space Shuttle disaster, providing a bittersweet moment of triumph during a time of profound tragedy for NASA and the nation.

    Voyager 2's Grand Tour of the outer planets—visiting Jupiter, Saturn, Uranus, and later Neptune—was made possible by a rare planetary alignment that occurs only once every 176 years. The spacecraft used gravity assists from each planet to slingshot itself to the next destination, a technique that saved decades of travel time.

    Today, Voyager 2 continues its journey into interstellar space, having crossed the heliopause in 2018. But its flyby of Uranus remains one of humanity's greatest exploratory achievements—a single spacecraft, launched in 1977 with less computing power than a modern smartphone, revealing an entirely alien world in exquisite detail during a few precious hours on January 24, 1986.

    No spacecraft has returned to Uranus since, making those images and measurements from forty years ago still the best data we have about this enigmatic ice giant. However, NASA is now planning a return mission, hoping to finally solve the mysteries that Voyager 2 first unveiled on this day four decades ago.


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