Those Who Witnessed Castle Bravo Looked Into Armageddon
America’s most powerful nuke caused our worst radiological disaster
by PAUL HUARD
Sixty-one years ago on an island in the South Pacific, scientists and military officers, fishermen and Marshall Islands natives observed first-hand what Armageddon would be like.
And it almost killed them all. The Atomic Energy Commission code-named the nuclear test Castle Bravo.
The March 1, 1954 experiment was the first thermonuclear explosion based on practical technology that would lead to a deliverable H-bomb for the Air Force’s Strategic Air Command—part of the Operation Castle series of tests needed to manufacture the high-yield weapons.
Bravo was the worst radiological disaster in American atomic testing history—but the test provided information that led to a lightweight, high-yield megaton bomb that would fit inside a SAC bomber.
Widespread contamination sickened and exiled Pacific Islanders and killed a Japanese citizen. The United States had to admit it possessed the ability to make deliverable H-bombs—an information windfall for the Soviet Union, and the catalyst for serious consideration of a ban on atmospheric nuclear tests.
Bravo’s fallout even inspired the creation of a science fiction screen legend Godzilla. In the 1954 Japanese movie of the same name, atomic testing resurrects the “King of Monsters”—a symbol for the new terror felt in the only nation ever attacked with nuclear weapons.
Perhaps most importantly, Bravo forced many scientists and military officers to concede how deadly nuclear weapons really were—not just in their immediate effects such as blast and intense heat, but the lingering effects of high-energy radiation.
“I think the most important message we might take away from the Castle Bravo shot is the amount of hubris it represents,” Alex Wellerstein, a historian at the Stevens Institute of Technology and blogger, told War Is Boring.
“The scientists and military assured the politicians and Marshallese people that it was a safe experiment, that they had things under control, that they understood what would happen. And they were very wrong.”
The Bravo shot in 1954 was not the first test at Bikini Atoll, part of the 140,000-square-mile Pacific Proving Grounds. Nor would it be the last—from 1946 to 1958, the U.S. government held 67 atmospheric tests there.
Only two years earlier, the Ivy Mike shot demonstrated the first true thermonuclear reaction. It produced a 10-megaton yield, but the device relied on cryogenic liquid hydrogen isotopes that were bulky, required refrigeration equipment that weighed tons and was almost impossible to store in a weapon.
A prototype “wet fuel” bomb based on the Ivy Mike test was 24 feet long, five feet wide and weighed 30 tons. It was more like a railroad box car than a deliverable weapon. But Bravo used lithium deuteride “dry fuel,” which is solid and lightweight at room temperature.
Scientists estimated the device would have a yield of about five megatons. They based many of their safety precautions — such as the location of various observation posts and ships, a safety “exclusion zone” in the Pacific Ocean surrounding Bikini and estimates of fallout dispersal — on a five-megaton yield.
Zero hour for Bravo was at 6:45 a.m. local time on March 1. From the moment the device detonated, many of the observers knew something had gone spectacularly wrong.
The flash from the nuclear explosion was overwhelming, even by the standards of nuclear explosions. Men saw their bones appear as shadows through their living flesh. Streams of blinding light shone through the smallest cracks and pinholes in secured doors and hatches.
Bravo’s thermal radiation was far more intense than expected. More than 30 miles away from Ground Zero on Bikini Atoll, sailors on board Navy ships said the heat was like having a blowtorch applied to their bodies.
The shock wave destroyed buildings supposedly outside of the calculated damage zone. It nearly knocked observation aircraft out of the sky, and caused some men inadvertently trapped in a forward observation bunker to wonder if the explosion ripped their concrete and steel shelter from its foundations and flung it into the sea.
Then there was the fireball.
It was four miles in diameter and hotter than the surface of the sun. The Bravo fireball rose at the rate of 1,000 feet per second, and created a mushroom cloud that eventually topped 130,000 feet above sea level.
“In mere seconds the sailors sensed that something unspeakably wrong was occurring … Battle-hardened men who had served in World War II went to their knees and prayed,” wrote L. Douglas Keeney in 15 Minutes: General Curtis LeMay and the Countdown to Nuclear Annihilation.
“We soon found ourselves under a large black and orange cloud that seemed to be dropping bright red balls of fire all over the ocean around us,” one sailor recounted. “I think many of us expected that we were witnessing the end of the world.”
Later, scientists calculated that Castle Bravo’s yield was actually 15 megatons.
The reason? A “tritium bonus” occurred during the thermonuclear reaction. Cascading neutrons transformed the lithium-7 isotope—that comprised most of the “dry fuel”—into tritium and helium.
Tritium causes extremely energetic fusion.
It was the thermonuclear equivalent of throwing gasoline on a small blaze and producing an instant conflagration.
Bravo’s yield was 1,000 times greater than the Hiroshima bomb, far bigger than the scientists had planned. To make matters worse, meteorological forecasts predicted that high-altitude winds would blow the radioactive fallout away from inhabited areas.
Instead, the wind blew the radioactive cloud toward them.
Fallout from Bravo rained down on ships and sailors. Ships’ captains ordered entire crews below decks, and sealed their vessels for days in an effort to escape contamination. Fallout dusted U.S. service members stationed on nearby Rongerik Island.
The plume blanketed Marshall Islanders on Rongelap, Ailinginae and Utirik atolls downwind from Ground Zero. Unaware of the danger, children played in the radioactive dust, while other islanders licked it off their hands and arms because they thought it was snow.
And if things weren’t bad enough, fallout contaminated the Japanese fishing boat Fukuryu Maru, exposing the 23-man crew to high levels of radiation. One crewman died from radiation exposure, which provoked international outrage and a diplomatic crisis between the U.S. and Japan.
After the Fukuryu Maru incident became known, the U.S. Navy expanded the exclusion zone around the Pacific Proving Grounds to 570,000 square miles. However, the proving grounds and exclusion zone were so huge, it caused serious problems for the Japanese fishing industry.
The U.S. and Japan eventually resolved their diplomatic differences, and the U.S. agreed to pay more than $15 million in compensation to the Fukuryu Maru survivors.
The Marshall Islanders hit by fallout experienced numerous health problems for decades after the Bravo shot, including birth defects and thyroid cancer.
Eventually, natives evacuated from the contaminated islands, returned briefly, and then evacuated again because of concerns about lingering radiation. The natives are still in exile.
“We are sadly more akin to the Children of Israel when they left Egypt and wandered through the desert for 40 years,” Bikinian representative Tomaki Juda said during a media conference in 2014 commemorating the 60th anniversary of Bravo. “We left Bikini and have wandered through the ocean for 32 years and we will never return to our Promised Land.”
In 1990, Congress passed the Radiation Exposure Compensation Act. The Justice Department can make a one-time payment of $75,000 to an “atomic veteran” for a nuclear testing-related illness. However, government records indicate that fewer than three percent of atomic veterans have made a claim.
In 1963, the United States signed the Limited Test Ban Treaty that prohibited atmospheric testing of nuclear weapons.
“I think we should also make sure not to let short-term national security fears keep us from being methodical and careful about our thinking and actions,” Wellerstein said. “The reason Bravo got so far wrong is because small errors in understanding, under certain circumstances, can get magnified greatly.”