The Big Problem That Happened After We Nuked Space

In 1945, the US dropped two nuclear bombs  on Japan which changed the course of the Second World War. 17 years later,  another nuclear explosion changed the course of the Cold War. Except  this explosion happened in space.

The explosion of Starfish Prime  was a pivotal moment in the space race that reshaped our perception  of nuclear warfare. This story is crucial for understanding how we  arrived at today’s space policies, and why it’s imperative no nation is  allowed to place nuclear weapons in orbit. I’m Alex McColgan, and you’re watching Astrum. 

Join me today as we discuss what Starfish Prime was, the critical lessons it taught us, and  why we don’t send nukes into space anymore. In the early 1960s, the US launched  a series of five nuclear tests in outer space. Known as Operation Fishbowl,  their aim was both military and scientific.

The military wanted to study the effectiveness  of nukes as anti-ballistic missile measures, and how a space-based blast might interfere  with electronics, communication, and military operations on the ground. Scientists wanted  to know how a space explosion would impact the Earth’s magnetosphere, and what kind  of electromagnetic pulse it would generate. Starfish Prime was the first successful blast  of the bunch.

On July 9th 1962, almost 1,500 kilometres west-southwest of Hawaii, a Thor rocket  carrying a 1. 4 megaton thermonuclear warhead launched for the stars. That’s 500 times more  powerful than the one that destroyed Hiroshima.

27 smaller missiles loaded with scientific  instruments were fired up alongside it to gather data on the blast and its subsequent  effects. As the Thor rocket raced upwards, the nuke finally exploded at an altitude of 400 kilometres - about the height of the  international space station today. What a sight it must’ve been.

Ionized particles from the explosion collided  with molecules in the Earth’s atmosphere, creating widespread auroras visible across the  Pacific, even as far away as New Zealand. Just below the explosion, the cloudy night sky of  Honolulu was lit up for a full six minutes. It was as though another sun had emerged at 11pm. 

Radio stations wavered, a siren was set off, and streetlights across Hawaii were even knocked  out. The historical context of Starfish Prime is important. The early 1960s marked one of  the most tense periods of the Cold War, with the US and the Soviet Union locked in a fierce  struggle for global dominance.

Both superpowers sought to outdo each other in military strength,  political influence, and technological prowess. The space race became a key battleground  and by 1961, the Soviets had the upper hand. They successfully sent the first rocket  into space in 1957, and four years later, Yuri Gagarin became the first human in space. 

Pressure on the US intensified, as it began to fear the Soviets might develop space-based  military power before them. With tensions escalating after incidents like the Berlin Crisis,  both nations saw the militarization of space as a way to gain a strategic advantage in the Cold  War. This sparked a race to develop nuclear weapons, missile defense systems, and other  technologies that could be deployed in space.

Military planners were concerned about how these  nuclear weapons could be used in space, and what effects the detonation of such weapons might have  on global military strategy. More specifically, they were worried about the electromagnetic pulse,  or EMP, that would follow such an explosion. An electromagnetic pulse is a burst of  electromagnetic radiation produced by a nuclear explosion, especially high-altitude  or space-based detonations.

This pulse can generate powerful electric and magnetic fields  capable of disabling electrical circuits, disrupting communications, and causing widespread  damage to infrastructure like power grids, satellites, and radio systems. Back in the  early 1960s, scientists knew that nuclear blasts produce EMPs, but the full scale  and potential damage of such EMPs was not well understood. Operation Fishbowl was a  chance to study these effects more closely.

Launched from Johnston Atoll, Operation Fishbowl  was a series of five high-altitude tests conducted by the US in the early 1960s.  Three months after Starfish Prime, the US launched the remaining four  tests in a span of just two weeks. The second test, eerily named  “Checkmate”, launched on October 20th, 1962.

The 20 kiloton bomb, similar in size to  the one dropped on Hiroshima, detonated at an altitude of 147 km. This was rapidly followed  by Bluegill Triple Prime on the 26th of October, Kingfish on November 1st, and finally  Tightrope on November 4th, 1962. Bluegill Triple Prime and Tightrope were both  smaller explosions that detonated at 48 and 23 km altitudes respectively.

Bluegill Triple Prime  was aimed at understanding lower atmospheric effects of such explosions in the mesosphere,  while Tightrope was conducted as an anti-missile test in the stratosphere. NASA defines space as  starting at an altitude of 80km, so I suppose these nuke tests weren’t strictly carried  out in space. Kingfish was.

Its 0. 41 megatons detonated 95 km above sea level. But these paled  in comparison to the explosion of Starfish Prime.

The immediate impact of Starfish Prime struck awe  into those who saw it—auroras stretching thousands of miles, a fireball over Hawaii, all happening  in total silence. Unlike explosions on the ground, when a nuclear detonation happens in space, you  can’t feel a shock wave or hear a sound. There is no mushroom cloud or double flash.

There’s just a  bright ball of plasma, which changes colours like a lava lamp, as charged particles are pushed  down into the atmosphere by Earth’s magnetic field. These colourful auroras give high-altitude  nuclear explosions the nickname “rainbow bombs. ” But the lasting effects of such an explosion are far from sunshine and rainbows.

Starfish  Prime impacted the Earth in two big ways. In 1958, US space mission Explorer 1 discovered  that the Earth is surrounded by two donut-shaped regions of intense radiation. Today, we call  them Van Allen belts, after the scientist who discovered them.

These belts are made up of  charged particles, mainly protons and electrons, trapped by Earth's magnetic field. They act as a  protective shield against harmful solar radiation and cosmic rays, capturing high-energy  particles from the Sun's solar wind. The Starfish Prime explosion released such  a quantity of charged particles into Earth’s magnetosphere, that it altered the composition  and intensity of the natural Van Allen belts, and even created artificial radiation belts that  were stronger and longer than the originals.

These persisted for up to a decade, shortened  the lifespans of several satellite systems, and interfered with telecommunications. They  also destroyed two early satellites—the Ariel-1, Britains’ first satellite—and the first  TV broadcasting satellite, Telstar-1. But that’s not all Starfish Prime did. 

Remember the electromagnetic pulses I told you about earlier? Scientists  knew the blast would emit them, but no one could have guessed  just how intense they would be. Nuclear detonations emit gamma rays in all  directions, also known as a Compton current.

When they interact with Earth's atmosphere, they ionise  air molecules and liberate high-energy electrons. Since Starfish Prime detonated at an altitude of  400 kilometres, these gamma rays collided with atoms in the upper atmosphere creating a cascade  of free electrons. Accelerated by Earth’s magnetic field, these electrons produced a rapid and  intense oscillation of electromagnetic fields.

At high altitudes where the atmosphere is thinner,  this pulse is able to spread much further than it would in a lower-altitude explosion. The EMP from  Starfish Prime spanned thousands of kilometres, damaging electrical systems far from the  detonation site. Almost 1,500 kilometres away in Hawaii, street lights went out, telephone  lines were disrupted, and radio communications were affected, showing how vulnerable  civilian infrastructure is to such an event.

Starfish Prime made the world realise  just how destructive an EMP can be. It revealed how vulnerable electrical  grids, communications, and satellites would be to a nuclear EMP attack. If added to the  strategic arsenal, it would give any military the capacity to cripple enemy infrastructure  without direct contact or bloodshed.

Starfish Prime also released an isotope  called Cadmium-109 on explosion, which was used to track the fallout and measure  resulting contamination. While ground tests normally leave behind a characteristic localised  fallout pattern, the effects of space testing were global. New Zealand rainwater was found  to be contaminated with Cd-109, which a 1966 Nature article attributed to Starfish Prime.

These  kinds of reports raised significant environmental concerns about the long-term impact of space-based  detonations on Earth’s atmosphere and environment. And imagine - Starfish Prime wasn’t even the  biggest bomb the US had ever detonated in space. That prize goes to TEAK, from Operation Hardtack  in 1958.

At 3. 88 megatons, it was over twice as big as Starfish Prime, and detonated at an  altitude of 76. 8 km.

It turned night into day, and cut many trans-Pacific high-frequency  communications circuits. According to the Defense Nuclear Agency report on Operation  Hardtack, it “destroyed the ability of the normally ionized layers of the upper atmosphere  to bend radio waves back to the Earth. ” The Soviets were also busy testing  high-altitude nuclear explosions, detonating seven space bombs over Kazakhstan  between 1961-62.

Known as Project K, their aims and effects were much the same as  the US tests. Detonated at altitudes ranging between 40 and 300 km, none were quite as  big as the American bombs. They ranged in size from 1.

2 to 300 kilotons, about five times  smaller than Starfish Prime. On October 22nd, 1962, a 300 kiloton missile-warhead known as  Test #184 detonated near Dzhezkazgan at an altitude of 290 km. The EMPs generated started a  fire that burned down the Karaganda power plant, and blew over 1,000 km of shallow-buried  power cables between Tselinograd and Alma-Ata.

These learnings had serious Cold War  implications, highlighting the need for international agreements to prevent nuclear  testing in space. The unforeseen consequences of Starfish Prime eventually led both superpowers  to reconsider space-based nuclear strategies. One year later in 1963, the Limited Nuclear  Test Ban Treaty was signed by the US, UK, and USSR.

It prohibited nuclear weapon  tests in the atmosphere, outer space, and underwater to reduce radioactive fallout  and curb environmental contamination. The Outer Space Treaty followed in  1967, which banned the placement of nuclear weapons or any other weapons  of mass destruction in outer space. It also forbade nuclear explosions  in space or on celestial bodies, ensuring space remains a domain for peaceful  exploration and not military confrontation.

Our modern world relies heavily on space-based  infrastructure. Satellites underpin global navigation, communications, the internet, GPS,  and more. A nuclear explosion in space would spell chaos for us below.

Global commerce  and trade routes would crash and grind to a halt. Our electronics and power grids  would be fried, bringing critical services to their knees. Hospital equipment would stop  working, millions of tonnes of food would go to waste without proper preservation,  and financial markets would collapse.

The effects of a nuclear EMP would be far more  devastating today than they were in the 1960s, as our vital global systems and everyday lives rely  much more on electronics than they did back then. We’ve established that various  international treaties are in place today to ban further nuclear  space explosions. But could such catastrophic events caused by an  EMP still occur in some form today?

In 1859, the world’s largest-ever recorded  geomagnetic storm, the Carrington Event, caused some pretty wacky things to happen. Northern lights were reported as far south  as Cuba and Honolulu, and were so bright, people in the north of the US could read  newspapers just by the light of the aurora. It threw sparks from telegraph equipment  across the US—some strong enough to set fires.

If a solar flare of similar  magnitude were to occur in our direction, it could hit us with similar  devastating effects as Starfish Prime. Fortunately, the chances of  that happening are very slim. The more likely risk is a geopolitical one. 

Earlier this year, Russia made headlines for vetoing a UN resolution against putting nuclear  weapons in space. Several news outlets have since speculated that Russia is planning on  placing a nuclear warhead in low-Earth orbit. According to John Plumb, assistant  defence secretary for US space policy, Russia is developing a “concerning anti-satellite  capability — a new satellite carrying a nuclear device that Russia is developing.

This capability  could pose a threat to all satellites operated by countries and companies around the globe, as  well as to the vital communications, scientific, meteorological, agricultural, commercial, and  national security services we all depend upon. ” This is in direct violation of  the 1967 Outer Space Treaty, which though still in effect, sadly doesn’t  come with any formal enforcement mechanisms. These international agreements exist to prevent  space from becoming a battleground for nuclear weapons.

They must be respected to ensure all  of our safety and wellbeing. As space becomes increasingly important for modern life, the  lessons of the past are more relevant than ever. Starfish Prime showed us the devastating reality  of weaponizing space.

The electromagnetic pulses crippled infrastructure, unleashing  waves of radiation that lingered in our atmosphere for years, destroying satellites  and contaminating the space around our planet. This experiment was a turning point. From it  emerged one of the most important lessons of the nuclear and space age; space could be weaponized  in ways that affect not just individual nations, but all of humanity.

This is why international  treaties now ban the use of nuclear weapons in space. These agreements are promises to  future generations, pledges that space will remain a place for discovery and  peace, not for conflict and destruction. This is why responsible, peaceful space  exploration is so important – so we can continue to unravel the mysteries of  the universe, and make discoveries that inspire and unite humanity, without the  lingering shadow of total annihilation.

Thanks for watching! If you liked this video, you may like my others about space history.  Have you heard of the time Zambia entered the Space Race, and tried to go to  Mars?

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