The Nightmare of Fukushima 15 Years Later

SCHEERPOST, By Joshua Frank, March 20, 2026

“…………………………………………………………………………………… The Fukushima Daiichi nuclear plant, built by General Electric (GE) in the mid-1960s, was designed to withstand natural disasters, but its creators never foresaw an earthquake like that. When the plant’s sensors detected the quake, its reactors automatically shut down. That emergency shutdown (or scram) halted its fission process, triggering backup power to keep cold seawater flowing through the reactors and spent-fuel containers to prevent overheating. Things at Fukushima were going according to plan until that massive tsunami battered the plant, washing away transmission towers and damaging electrical systems. There were backup generators in the basement, but those, too, had been inundated by waves of seawater, and an already bad situation was about to get far worse.

A power outage at a nuclear power plant is known as a “station blackout.” As you might imagine, it’s one of the worst scenarios any nuclear facility could possibly experience. If all electricity is lost, that means water is no longer being pumped into the reactor’s scalding-hot core to cool it down. And if that core isn’t constantly being cooled, one thing is certain: disaster will ensue. The fission process itself may be complicated, but that’s basic physics. To make matters worse, there were three operating reactors at Fukushima Daiichi. Luckily, three others had already been shut down for maintenance. If power wasn’t restored in short order, that would mean that all three of Fukushima’s reactors were in very big trouble.

We would later learn that no one — not at TEPCO, GE, or among Japanese regulators — had ever considered the possibility that all the reactors might lose electricity at once. They had only drawn up plans for one reactor to go down, in which case the others could keep the plant running. But all of them offline, and every generator out of commission? There was no precedent or playbook for that.

The nuclear industry has a reasonably polite name for a disaster like the one that was rocking Fukushima. They refer to it as a “beyond design-basis accident” because no single nuclear plant design can account for every possible problem it might encounter in its lifetime. The fact that there’s a term for this should make you anxious.

Meltdowns and Fallout

Over the next several days, the emergency at Fukushima Daiichi only worsened. Every effort to restore power to its reactors hit a dead end. On-site radiation-detection equipment, which would have triggered warnings and guided evacuation efforts for those in danger, was no longer functioning. Plans to pump water into the reactors to cool them had faltered. Their cores kept overheating, and the boiling pools of spent fuel were at risk of drying out, potentially triggering a massive fire that would release extreme amounts of radiation.

Within three days, following a series of fires, hydrogen explosions, and panic among those aware of what was happening, Fukushima’s Units 1, 2, and 3 experienced full-scale core meltdowns. Over 150,000 people within an 18-mile radius had already been forced to evacuate, and radiation plumes would take two weeks to spread across the northern hemisphere, although the Japanese government wouldn’t admit publicly that any meltdown had occurred until June 2011, three months later.

The only good news for the 13 million people living 150 miles south in Tokyo was that, during and immediately after the meltdowns, prevailing winds carried much of Fukushima’s radioactive material away from the smoldering reactors and out to sea. It’s estimated that 80% of the fallout from Fukushima ended up in the ocean, meaning most of it headed east rather than toward population centers to the south and west. The other fortunate news was that the spent fuel containers had somehow survived it all. If their water levels in the pools had been drained, far more radiation would have been released.

But Tokyo wasn’t completely spared. After years of research, scientists discovered that cesium-rich microparticles had blanketed the greater Tokyo area, an unpopular discovery that drew backlash and threats of academic censorship. Areas around the Fukushima exclusion zones recorded the highest radiation levels. Japanese government officials continually downplayed the dangers of the accident and were reluctant to even classify the event as a Level 7 nuclear disaster, the highest rating on the International Nuclear Event Scale, which would have placed it on a par with the 1986 Chernobyl nuclear disaster. Japanese officials have also failed to conduct long-term epidemiological studies that would include baseline measurements of cancer rates, which has cast doubt on thyroid screenings that found troubling incidents of cancer far higher than researchers expected.

Radioactive Fish

Prior to the earthquake, the ocean’s cesium-137 levels near Fukushima were 2 Becquerels (a unit of radioactivity) per cubic meter, well below the recommended drinking water threshold of 10,000 Becquerels. Just after March 11, 2011, cesium-137 levels there spiked to fifty million before decreasing as sea currents dispersed the radioactive particles away from the coast. The ocean, however, had been poisoned.

In the years that followed the Fukushima nuclear disaster, researchers documented a frightening, yet predictable trend. Radioactive isotopes in seawater were taken up by marine plants (phytoplankton), which then moved up the food chain into tiny marine animals (zooplankton) and, eventually, to fish.

Cesium-137 consumed by fish can reside in their bodies for months, while Strontium-90 remains in their bones for years. If humans then eat such fish, they will also be exposed to those radioactive particles. The more contaminated fish they eat, the greater the radioactive buildup will be.

In 2023, over a decade after the incident, radiation levels remained sky-high in black rockfish caught off the Fukushima coast. Other bottom-dwelling species have been found to be laden with radioactivity, too, including eel and rock trout. Further concerns have been raised about the treated radioactive water that TEPCO continued to release into the ocean, prompting China to suspend seafood imports from Japan. Aside from those findings, there have been very few studies examining the effects of Fukushima’s radiation on ecosystems or on the people of Japan.

“Japan has clamped down on scientific efforts to study the nuclear catastrophe,” claims pediatrician Alex Rosen of International Physicians for the Prevention of Nuclear War. “There is hardly any literature, any publicized research, on the health effects on humans, and those that are published come from a small group of researchers at Fukushima Medical University.”

Recognizing such levels of radiation, even if confined to the waters near Fukushima, would cast the country’s nuclear industry as a significant threat — not only to Japan but globally. Any admission that Fukushima’s radiation is linked to increased cancer rates would raise broader concerns about nuclear power’s future viability. Radiation exposure is cumulative and, although Fukushima didn’t immediately cause mass casualties, it wasn’t a benign accident either. It took decades before it was accepted that Chernobyl had caused tens of thousands of excess cancer deaths. It may take even longer to completely understand Fukushima’s full effects. In the meantime, the still ongoing cleanup of the burned-out facilities may cost as much as 80 trillion yen ($500 billion).

It’s been 15 years since Fukushima’s reactors experienced those meltdowns and we still don’t fully understand their long-term repercussions. Nuclear power advocates will argue that Fukushima wasn’t a serious incident and that nuclear technology is still safe. They’ll minimize radiation threats, remain optimistic that new reactor designs will never falter, dismiss the fact that there’s simply no permanent solution for radioactive waste, and overlook the inseparable connection between nuclear power and atomic weapons. After all, among other things, we’ll undoubtedly need nuclear energy to help power the artificial intelligence craze, right?………………………………………………………………………………………………………………………………………………………………………. With nine nuclear-armed nations and roughly 12,000 nuclear warheads on this planet, worries about nuclear war are unavoidable. However, the danger of a nuclear disaster at a seemingly “peaceful” nuclear facility is often ignored. The future of atomic energy remains uncertain, but it is our duty to eliminate this hazardous energy source before another Fukushima triggers a war-like catastrophe all its own.mhttps://scheerpost.com/2026/03/20/searching-for-solace-in-a-nuclearized-world/

Joshua Frank, a TomDispatch regular, is co-editor of CounterPunch and co-host of CounterPunch Radio. He is the author of Atomic Days: The Untold Story of the Most Toxic Place in America, and the forthcoming Bad Energy: AI Hucksters, Rogue Lithium Extractors, and Wind Industrialists Who are Selling Off Our Future, both with Haymarket Books.