- I get it.
- How bad is radiation anyway?
- How ‘hot’ is Chernobyl?
- What about Fukushima?
- Evacuation stress has killed more than the radiation would have!
- They’re resettling the 20 mSv zones
- What about the natural radiation at RAMSAR!?
1. I get it.
2. How bad is radiation anyway?
Before we look at the numbers, let’s remember that if it wasn’t for uranium and thorium, life on earth would not exist. They keep the earth’s core hot and spinning which powers the magnetic field that protects the atmosphere from being blown away! If you ever wished uranium did not exist, you just wished away life on earth. Natural uranium breaks down into radon gas that leaks out of the ground and gently irradiates us: just a little. This happens without human interference. This is called natural background radiation and it is all around us.
Because there are 3 types of radiation (alpha, beta and gamma) and they hit the body in different ways, scientists have broken down the effect of radiation on the body into an equivalent unit called Sieverts.
- A Sievert is dangerous
- 8 Sieverts will kill you
- But milliSieverts are used to measure medical procedures that can save your life, and are also used to describe the natural background radiation in units per annum. The average natural dose is 2.4 mSv per year
- MicroSieverts (μSv, or millionths of a Sievert) measure daily exposure levels.
- How much radiation is too much? A handy guide.
- Charles Sturt University’s “Radiation Safety Committee” says that around the world some rare places have 50 milli-Sieverts (50 mSv) a year of natural radiation, with no discernible health impacts.
- 50 mSv per year. Remember that number.
- This means that areas hit by radiation 25 times higher than the average natural background radiation are still relatively harmless.
3. So how ‘hot’ is Chernobyl?
So why did they evacuate Chernobyl? Worldwide, government policy about radiation has been influenced by a few suspicious papers decades ago that simply assumed there was no safe lower level of radiation. It’s an assumption extrapolated mathematically down to very low levels of radiation that is often not verified by empirical science. It’s called the Linear No Threshold model and just assumes there is no safe lower level. Many scientific academies now question whether this old mathematical model survives modern scientific observation. (See my LNT page). But because of some scientific power plays back in the day, it’s the model that informs government policy. It is behind the ‘guesstimate’ that the 1986 Chernobyl disaster will eventually kill 4,000 people. The reality may be far, far lower. As the wiki says:
“The number of potential deaths arising from the Chernobyl disaster is heavily debated. The WHO‘s prediction of 4000 future cancer deaths in surrounding countries is based on the Linear no-threshold model (LNT), which assumes that the damage inflicted by radiation at low doses is directly proportional to the dose. Radiation epidemiologist Roy Shore contends that estimating health effects in a population from the LNT model “is not wise because of the uncertainties”
In comparison, coal kills 2.7 million people a year, or nearly 52,000 people a week! Even by the over-conservative ‘no safe limit’ model, coal kills about 2 Chernobyls every day! But that’s based on the LNT. It turns out the 1,200 ‘babushka’s of Chernobyl’ who returned to live there shorty after being evacuated are outliving those who left! It seems evacuation stress is worse than radiation.
The BBC echoes this view in a piece titled “We should stop running away from radiation.” (March 2011)
And Chernobyl? The latest UN report published on 28 February confirms the known death toll – 28 fatalities among emergency workers, plus 15 fatal cases of child thyroid cancer – which would have been avoided if iodine tablets had been taken (as they have now in Japan). And in each case the numbers are minute compared with the 3,800 at Bhopal in 1984, who died as a result of a leak of chemicals from the Union Carbide pesticide plant….
… A map of Chernobyl in the UN report shows regions shaded according to rate, up to 3,700 kBq per sq m – areas with less than 37 kBq per sq m are not shaded at all. In round terms, this suggests that the radioactive fallout at Fukushima is less than 1% of that at Chernobyl.
The side effects on nature are interesting. Evacuating the Chernobyl area has created an unintended wildlife sanctuary where nature is thriving. It appears nature can endure the presence of a little extra radiation far better than it can if we were there! Studies show biological systems are not perfect in the hottest zones of the ‘red forest’ which should be quarantined. However, Ukraine plans to leave the majority of Chernobyl abandoned for another 200 years, when in reality they could fence of certain regions and move back into the area.
4. What about Fukushima?
So what about Fukushima? As The Financial Times says in “Fukushima nuclear disaster: did the evacuation raise the death toll?” (Marsh 2018)
The result that did not materialise was sickness from radiation. “At present, there are no cases of cancer relating to radiation, and that includes workers at the plant,” says Dr Tanigawa. Among 173 workers exposed to radiation above occupational safety limits, there may eventually be a handful of incidents of cancer, he says. But the maximum dose to Fukushima residents was below those levels. “Statistically speaking, there should be no detectable increase in cancer in the general public.” Anti-nuclear campaigners point to more than 100 diagnoses of thyroid cancer in Fukushima children. But doctors say radiation cannot be the cause, since the disease typically takes four or five years to develop after exposure, and the cancers were found immediately. Rather, the thyroid cases were a result of screening every child in the prefecture using ultrasensitive equipment. Detection rates in Fukushima were similar to those found using the same equipment in other Japanese prefectures. “If we go looking for thyroid cancer then we’ll find it through a screening effect,” Dr Tanigawa says.
Avoiding deaths from radiation was the whole point of the evacuation. The crucial question is how sick people would have been had they stayed. Prof Thomas has published calculations using UN radiation data from Fukushima and standard models of how it translates to disease. He found modest risks. “The sort of dose for even the worst-affected villages was something that was accepted in the nuclear industry 30 years ago,” he says. In the worst-affected towns of Tomioka, Okuma and Futaba he found that evacuees extended their lives by an average of 82, 69 and 49 days respectively, thanks to the radiation they avoided. In Mr Yamauchi’s hometown of Naraha, the decrease in lifespan avoided through evacuation was just a couple of days. In a few places, the figure was negative because people evacuated to areas with higher levels of radiation. Evacuation makes relatively greater sense for the young, who are more sensitive to radiation, and have more length of life to lose.
But purely based on an economic calculation of cost and benefit, the evacuation was not worth it, says Prof Thomas. The expected compensation bill to evacuees is ¥7.9tn ($74bn). Add in the terrible health consequences of disrupting lives “and it becomes many more times not worth doing”. The lifetime risk of death from a 100 millisievert dose of radiation — more than any resident actually received — is about 0.5 per cent.
Let’s crunch the numbers. UNSCEAR estimated the average radiation doses that would have been incurred inside the 20-kilometer evacuation zone in the first year after the accident, had there been no evacuation: the highest was Tomioka township’s 51 millisieverts.8 The Committee also reckoned that 80-year lifetime doses in contaminated areas will be two to three times the first-year dose. (Radiation levels drop quickly because of radioactive decay and weathering.)9From there we can reckon the dose people would have received from fallout had they lived their whole lives in the evacuation zone: about 100-150 mSv in the most contaminated townships, substantially less elsewhere in the zone. Natural background radiation in the United States averages about 2.4 mSv per year, so 150 mSv is about equal to the lifetime background dose of a typical American.
Others estimate about 20 mSv / year. Either way, it’s lower than Charles Sturt’s natural hot spots at 50 mSv / year! Indeed, The Breakthrough Institute says that thyroid cancer rates are lower in Fukushima children than other areas, the seafood is safe to eat, the evacuation zone is mostly habitable, and the Fukushima death toll will be too small to measure.
There were 2,202 disaster-related deaths in Fukushima, according to the government’s Reconstruction Agency, from evacuation stress, interruption to medical care and suicide; so far, there has not been a single case of cancer linked to radiation from the plant. That is prompting a shocking reassessment among some scholars: that the evacuation was an error. The human cost would have been far smaller had people stayed where they were, they argue. The wider death toll from the quake was 15,895, according to the National Police Agency.
5. Evacuation stress has killed more than the radiation would have!
The Breakthrough March 2015 continues…
The mandatory relocations from the Fukushima evacuation zone, which are responsible for much of the accident’s cost and all of its cataclysm, owe more to apocalyptic expectations built into regulatory standards than to objective health hazards from fallout. Those hazards are well within the range of risks we negotiate in ordinary life. It might be time to reconsider policies that require precipitate or long-term relocations, which carry their own risks. Hundreds of people died from the stress of the Fukushima evacuation, and thousands more were uprooted from their homes over radiation doses that would almost certainly never affect their health. Instead of requiring people to leave, it could make more sense to give them the information they need on radiation exposures and likely health risks, and let them make their own decisions.
The Breakthrough March 2015
6. They’re resettling the 20 mSv zones
7. What about the natural radiation at RAMSAR!?
Why haven’t you asked about Ramsar? What terrible nuclear accident happened there? Well, are you in for a mind-bending bit of data. It’s a massive government cover-up involving corporations that don’t want a terrible nuclear accident reported……. ok. I’m being sarcastic.
Ramsar’s radiation is natural. It still comes from uranium decaying in the environment, decaying into radon gas that we can breathe. But because it’s natural, no one has been able to spin a conspiracy theory around covering it up. Dr Helen’s tinfoil Hat brigade cannot rant against nature, can they? Remember Chernobyl’s SCZ was 2.5 mSv / annum, and Fukushima’s between normal 2.5 to 20 mSv /a. So what’s Ramsar got?
The highest background radiation in an inhabited area is found in Ramsar, primarily due to the use of local naturally radioactive limestone as a building material. The 1000 most exposed residents receive an average external effective radiation dose of 6 mSv per year, (0.6 rem/yr,) six times the ICRP recommended limit for exposure to the public from artificial sources. They additionally receive a substantial internal dose from radon. Record radiation levels were found in a house where the effective dose due to ambient radiation fields was 131 mSv/a, (13.1 rem/yr) and the internal committed dose from radon was 72 mSv/a (7.2 rem/yr). This unique case is over 80 times higher than the world average natural human exposure to radiation.
Epidemiological studies are underway to identify health effects associated with the high radiation levels in Ramsar. It is much too early to draw statistically significant conclusions. While so far support for beneficial effects of chronic radiation (like longer lifespan) has not been observed, a protective and adaptive effect is suggested by at least one study whose authors nonetheless caution that data from Ramsar are not yet sufficiently strong to relax existing regulatory dose limits. From the Background radiation wiki
If Helen’s tinfoil hat brigade cannot explain why these people are not dropping like flies, she should publicly retract all her anti-science books and stop making a fool of herself!