Why is Fukushima nuclear crisis so threatening?

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In summary, an accident at a nuclear plant can produce more radioactive fallout than an atmospheric nuclear explosion. No nuclear test has ever triggered panic around the global fearing radioactive dust spread by wind.
  • #1
petergreat
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I don't understand. How can a nuclear plant accident produce more radioactive fallout than an atmospheric nuclear explosion? No nuclear test has ever triggered panic around the global fearing radioactive dust spread by wind.
 
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  • #2
petergreat said:
I don't understand. How can a nuclear plant accident produce more radioactive fallout than an atmospheric nuclear explosion? No nuclear test has ever triggered panic around the global fearing radioactive dust spread by wind.
When was the last atmospheric test of a nuclear weapon? What was the public reaction to that test?

How were more recent tests conducted? What was the public reaction?

How is current research of nuclear detonations conducted in the US?
 
  • #3
I guess atmospheric tests were stopped before word "radiation" became synonym of "panic".
 
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  • #4
Heh - I'm annoyed I didn't think of that. For anti-nuclear activists, equating nuclear weapons and nuclear power has always been a key tactic. It's just that they haven't had anything to raise panic over in more than 20 years.

I would be curious to have a more concrete answer to the question though: how does an accident like this compare to an above-ground test? (which, it is my understanding, hasn't happened since the 1960s)
 
  • #5
russ_watters said:
I would be curious to have a more concrete answer to the question though: how does an accident like this compare to an above-ground test? (which, it is my understanding, hasn't happened since the 1960s)

Interesting question!

A useful statistic in measuring how bad a radiation release is is how many curies of 131I were released. 131I is an efficient carcinogen.

Three Mile Island released 20 Ci of 131I.
Chernobyl released 7x10^6 Ci of 131I
Above-ground nuclear testing in Nevada released about 1.5x10^8 Ci of 131I.

It's likely that nuclear testing caused hundreds of thousands of excess thyroid cancers; Chernobyl thousands; TMI none.

Sources:
http://streaming-online-free.blogspot.com/2011/03/three-mile-island-accident-japan.html [Broken]
http://books.google.com/books?id=tf...="three mile island" chernobyl curies&f=false
http://www.ips-dc.org/articles/nuclear_testing_and_the_rise_of_thyroid_cancers
 
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  • #6
bcrowell said:
A useful statistic in measuring how bad a radiation release is is how many curies of 131I were released. 131I is an efficient carcinogen.

Three Mile Island released 20 Ci of 131I.
Chernobyl released 7x10^6 Ci of 131I
Above-ground nuclear testing in Nevada released about 1.5x10^8 Ci of 131I.

A complication is that nuclear testing is sometimes done on high altitudes (e.g. >4000 m) to reduce fallout, while nuclear plants are all at ground level, though I don't know the exact numbers about how much difference this makes.
 
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  • #7
bcrowell said:
Interesting question!

A useful statistic in measuring how bad a radiation release is is how many curies of 131I were released. 131I is an efficient carcinogen.

Three Mile Island released 20 Ci of 131I.
Chernobyl released 7x10^6 Ci of 131I
Above-ground nuclear testing in Nevada released about 1.5x10^8 Ci of 131I.

It's likely that nuclear testing caused hundreds of thousands of excess thyroid cancers; Chernobyl thousands; TMI none.

Sources:
http://streaming-online-free.blogspot.com/2011/03/three-mile-island-accident-japan.html [Broken]
http://books.google.com/books?id=tf...="three mile island" chernobyl curies&f=false
http://www.ips-dc.org/articles/nuclear_testing_and_the_rise_of_thyroid_cancers
Excellent, that is exactly what I was looking for. Thanks very much.
 
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  • #8
bcrowell said:
It's likely that nuclear testing caused hundreds of thousands of excess thyroid cancers; Chernobyl thousands; TMI none.

Still, from what I remember, there is no Chernobyl effect visible in the epidemiological data - background is high enough to mask it.
 
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  • #9
petergreat said:
A complication is that nuclear testing is sometimes done on high altitudes (e.g. >4000 m) to reduce fallout, while nuclear plants are all at ground level, though I don't know the exact numbers about how much difference this makes.

I had read that one of the best ways to spread radiation over a country would be to detonate a nuclear weapon in the upper-atmosphere so that the wind blows the radiation around.
 
  • #10
petergreat said:
I don't understand. How can a nuclear plant accident produce more radioactive fallout than an atmospheric nuclear explosion? No nuclear test has ever triggered panic around the global fearing radioactive dust spread by wind.

A typical nuclear reactor fissions as many atoms as a nuclear bomb every 4 hours. A bomb is made up of a few kg of fuel, a reactor has as much as 100 tons. There are a lot more fission products in reactor fuel than a bomb explosion.
 
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  • #11
Borek said:
Still, from what I remember, there is no Chernobyl effect visible in the epidemiological data - background is high enough to mask it.
While I would tend to agree, it does depend on who you ask. Not that I'd ever ask them anything, but Greenpeace speaks loudly on the issue and some people listen.
 
  • #12
petergreat said:
I don't understand. How can a nuclear plant accident produce more radioactive fallout than an atmospheric nuclear explosion? No nuclear test has ever triggered panic around the global fearing radioactive dust spread by wind.

Let's look at the Hiroshima bomb, for example. 15 kT of explosive yield, or so. That's equal to 17.43 GWh of thermal energy, if you convert the units.

Let's say a typical large nuclear power reactor has a thermal power output of about 3 GW.

That means it generates one bomb worth of energy - and one Hiroshima bomb worth of fission products - every 6 hours.

That's why the amount of fission products that can potentially be released from a severe reactor accident is, in theory at least, larger than from a bomb - because it has fissioned much more uranium, generated much more energy, and made much more fission products, than the bomb.
 
  • #13
It all depends upon the amount of further contamination of the planet. I do not know what normal background radiation was in 1940, but I am willing to bet that it is higher now than it was then.

Any amount of radiation can cause cancer to start growing in your body. Usually very low doses like a chest X-ray are dismissed as not causative; but, the reality is that your next X-ray could start a cancer growing in your body. We just do not know when the radiation can cause that type of damage. One thing we do know is that if we receive increasing doses, we increase the potential for Cancer to grow.

SO, people have a good reason to be afraid of any additional radioactive pollution to the planet. By being proactive, the life you save may be your Great Great Grandchild's.
 
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  • #14
Atmospheric tests were generally conducted away from places where people lived.
 
  • #15
LIFE EXPECTANCY

US WORLD
1950 69 46

2000 77 66

Obviously, background radiation, atmospheric testing, and nuclear power are major impacts on world health.
 
  • #16
NUCENG:
Obviously going to use the fact that nuclear testing did not manage to nuke away all the impact of advancements in medical science as some sort of point.

petergreat said:
I don't understand. How can a nuclear plant accident produce more radioactive fallout than an atmospheric nuclear explosion?
Easily. Chernobyl has released 890 times the Cs-137 (major medium term pollutant) of the nuclear bomb type dropped on Nagasaki. (albeit the bomb would of released also comparable amount of Sr-90 whereas reactor won't)
Over the time of operation, reactor produces far more energy than such bomb does. The short living isotopes in reactors decay during that time though, so if you compare the short living isotopes you get a smaller reactor:bomb ratio.

The atmospheric nuclear testing has released something on order of 740PBq of Cs-137 according to
http://www.davistownmuseum.org/cbm/Rad8.html
, Chernobyl has released 85 PBq or over one-tenth .

Remember that the typical nuclear power plant is not only a power plant, but also a MASSIVE radwaste repository. Much of the radwaste from the plant is stored on site. There can be 5 core loads stored right next to the reactor in a modern spent fuel pool (re-racked for storage). 4 reactors, and you get 24 cores. Much of the remaining radwaste is also somewhere on the site, in a common spent fuel pool.
The total inventory of Cs-137 at a nuclear plant of several reactors, including the spent fuel pools, can easily exceed by several times the total release from atmospheric nuclear testing. Simply walking away from a nuclear power plant (multiple reactors + radwaste repository) can result in a release exceeding that of all the atmospheric nuclear testing for the medium term pollutants (with half life of several decades).
 
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  • #17
NUCENG said:
LIFE EXPECTANCY

US WORLD
1950 69 46

2000 77 66

Obviously, background radiation, atmospheric testing, and nuclear power are major impacts on world health.

When you start tabulating the ever increasing number of people killed by radiation induced cancer it is obvious that the impact on health is MAJOR, and very sad, because it just does not HAVE to happen.
 
  • #18
Joe Neubarth said:
When you start tabulating the ever increasing number of people killed by radiation induced cancer it is obvious that the impact on health is MAJOR

Do you have data to support this statement?

Note that according to forum rules such data must be published in a peer reviewed magazine.
 
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  • #19
Joe Neubarth said:
When you start tabulating the ever increasing number of people killed by radiation induced cancer it is obvious that the impact on health is MAJOR, and very sad, because it just does not HAVE to happen.

There is no way to determine whether someone's cancer was caused by normal biological causes, carcinogenic chemical, natural background radiation, or man made radiation. There is no statistical evidence that very low levels of radiation induce cancer.

There are not an "ever increasing number of people killed by radiation induced cancer", this statement is purely fabricated and you have presented no evidence to back up your claim.

From http://www.cancer.org/cancer/cancer...icaltreatments/radiation-exposure-and-cancer":
Most studies on radiation and cancer risk have looked at people exposed to very high doses of radiation in the settings above. It is harder to measure the much smaller increase in cancer risk that might come from much lower levels of radiation exposure. Most studies have not been able to detect an increased risk of cancer among people exposed to low levels of radiation. For example, people living at high altitudes, who are exposed to more natural background radiation from cosmic rays than people living at sea level, do not have noticeably higher cancer rates.
 
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  • #20
Joe Neubarth said:
It all depends upon the amount of further contamination of the planet. I do not know what normal background radiation was in 1940, but I am willing to bet that it is higher now than it was then.

Got numbers for that? Or can I just dismiss it as 'invented'?
Any amount of radiation can cause cancer to start growing in your body. Usually very low doses like a chest X-ray are dismissed as not causative; but, the reality is that your next X-ray could start a cancer growing in your body. We just do not know when the radiation can cause that type of damage. One thing we do know is that if we receive increasing doses, we increase the potential for Cancer to grow.

Actually, we have a pretty good idea how much you can take for various stages of damage.

That's how we know things such as lethal dose of radiation.

Of course, any amount could do something, but that doesn't mean we don't understand dosage and effect on the body.
 
  • #21
All atmospheric nuclear tests ever conducted (~500) have a total yield of ~430 megatons. That's roughly 30.000 times Hiroshima (and 90% of the current US operational ICBM and SLBM arsenal).

Based on all the horror stories I have heard in my life about the ecological impact of nuclear weapons, I come inevitably to the conclusion that all of us must've been dead since at least 40 years.

[PLAIN]http://img204.imageshack.us/img204/4784/atomtestsbis1995.jpg [Broken]

[PLAIN]http://img222.imageshack.us/img222/648/megatonnageatomtestsbis.jpg [Broken]

Bulletin of the Atomic Scientists, May 1996I have no evidence, but at the beginning of the Fukushima crisis, german news channels reported, that during the early 1960s background radiation in Europe was three times the number after the Chernobyl disaster.
 
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  • #22
the insane megaton figures come largely from fusion, not fission.
 
  • #23
Dmytry said:
NUCENG:
Obviously going to use the fact that nuclear testing did not manage to nuke away all the impact of advancements in medical science as some sort of point.


Easily. Chernobyl has released 890 times the Cs-137 (major medium term pollutant) of the nuclear bomb type dropped on Nagasaki. (albeit the bomb would of released also comparable amount of Sr-90 whereas reactor won't)
Over the time of operation, reactor produces far more energy than such bomb does. The short living isotopes in reactors decay during that time though, so if you compare the short living isotopes you get a smaller reactor:bomb ratio.

The atmospheric nuclear testing has released something on order of 740PBq of Cs-137 according to
http://www.davistownmuseum.org/cbm/Rad8.html
, Chernobyl has released 85 PBq or over one-tenth .

Remember that the typical nuclear power plant is not only a power plant, but also a
MASSIVE radwaste repository. Much of the radwaste from the plant is stored on site. There can be 5 core loads stored right next to the reactor in a modern spent fuel pool (re-racked for storage). 4 reactors, and you get 24 cores. Much of the remaining radwaste is also somewhere on the site, in a common spent fuel pool.
The total inventory of Cs-137 at a nuclear plant of several reactors, including the spent fuel pools, can easily exceed by several times the total release from atmospheric nuclear testing. Simply walking away from a nuclear power plant (multiple reactors + radwaste repository) can result in a release exceeding that of all the atmospheric nuclear testing for the medium term pollutants (with half life of several decades).

Back to your old tricks. That is your interpretation of what I wrote. I will not allow you and Neubarth to portay this as the end of the world. There is nothing you can do to undo atmospheric testing or reactor accidents. So let's deal in facts:

The average annual background radiation level from cosmic and terrestrial sources pre-1942 was and is about about 2.4 mSv/yr with tremendous variation due to altitude and geology.
Atmospheric testing and the attacks on Hiroshima and Nagasaki in the 1945 to 1963 period added 0.15 mSv to background. Since the atospheric test ban this level has decayed to 0.005mSv.

TMI2 and Chernobyl and Windscale and SL-1 and Torsk and all other releases before Fukushima have resulted in a background radiation average of (you guessed it!) 2.4 mSv/yr.

In areas of Europe outside of the old Soviet Union and nearby countries, the Chernobyl accident reportedly added a total lifetime dose increase of 1 mSv.

Your own numbers that Chernobyl was over 10% of the atmospheric release of radiocesium from atmospheric testing was bad. Fukushima releases are bad, but may be 10% of Chernobyl so far by some estimates (I agree that is highly uncertain).

You throw out numbers like PBq and 890 times worse that an A-bomb to make a it sound bad. Unless you put those numbers in context with consequences and comparison to other sources of risk, you are being alarmist, not informative.

Honestly I think we need to go back to atmosphic testing. It would take a nuclear flash to brighten your day. (For the humorless, that's a joke, sun.)
 
  • #24
I tried to find papers to link but all were subject to a fee. This was the best source I could spot in the time I had. It was put out by the IAEA.

The Chernobyl Forum:
Major Findings and Recommendations
Mikhail BALONOV Scientific Secretary

...Radiation-induced effects on plants and animals
•Irradiation caused numerous acute adverse effects on the plants and animals living up to 10-30 kilometres from the release point.
•The following effects caused by radiation-induced cell death have been observed in biota:
Increased mortality of coniferous plants, soil invertebrates andmammals; and
Reproductive losses in plants and animals.
•A few years were needed for recovery from major radiation-induced adverse effects in populations of plants and animals.
•Due to removal of human activities, the Exclusion Zone has paradoxically become a unique sanctuary for biodiversity.
•There is nothing that can be done to remedy the radiological conditions for plants and animals residing in the Exclusion Zone that wouldnot have an adverse impact on plants and animals.
http://www.sfrp.asso.fr/IMG/pdf/5-Balonov.pdf [Broken]
 
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  • #25
Dmytry said:
the insane megaton figures come largely from fusion, not fission.

Which doesn't produce less fallout than fission. At least those days. Google "Castle Bravo".
 
  • #26
Dmytry said:
the insane megaton figures come largely from fusion, not fission.

The large megaton bombs created huge amounts of fallout from fission. A 10 MT H-bomb may be 90% fusion, but that is still 1 MT worth of fission, which is ~40 times more than fat man/little boy. The extra neutrons generated by fusion were normally used to boost the bomb's output by fissioning a uranium tamper. The first H-bomb test was only ~75% fusion. Tsar Bomba was around 95% fusion but at over 50 MT, that is still 2.5 MT of fission.
 
  • #27
Joe Neubarth said:
It all depends upon the amount of further contamination of the planet. I do not know what normal background radiation was in 1940, but I am willing to bet that it is higher now than it was then.

Any amount of radiation can cause cancer to start growing in your body. Usually very low doses like a chest X-ray are dismissed as not causative; but, the reality is that your next X-ray could start a cancer growing in your body. We just do not know when the radiation can cause that type of damage. One thing we do know is that if we receive increasing doses, we increase the potential for Cancer to grow.

SO, people have a good reason to be afraid of any additional radioactive pollution to the planet. By being proactive, the life you save may be your Great Great Grandchild's.

You would lose that bet. background radiation due to cosmic and natural terrestrial sources is and has been 2.4 mSv/yr. BTW. the largest man made source of radiation release is not atmospheric testing, medical, or nuclear power. It is fly ash from coal-fired plants
 
  • #28
JaredJames said:
Got numbers for that? Or can I just dismiss it as 'invented'?Actually, we have a pretty good idea how much you can take for various stages of damage.

That's how we know things such as lethal dose of radiation.

Of course, any amount could do something, but that doesn't mean we don't understand dosage and effect on the body.

Come on Jared, you are trying to be humorous. When I say I'd be "willing to bet" means that it is a guess in the first place. It was vague and intended to be so because there are no numbers.

Now, for your edification, we could take the tremendous increase in radiation in Washington and other areas were radioactive processing has taken place (if you get the breast cancer charts for the United States per ratio of population you can see all the sites where fuel was processed or reactors have been in operation). Witness Eastern Idaho where there is a very high rate of breast cancer. The Winds usually (not always) blow from the west there.

So what was in Central Idaho or Western Idaho that caused this contamination that is killing thousands of women?

The answer, of course is Arco, Idaho where there were several nuclear accidents. At one nuclear site a control rod had an operator pinned to the ceiling after the dufus went to the top of the experimental reactor and pulled on the rod to free it because it was hung up on something. He created a super critical reactor and it exploded (Shades of Fukushima!) and launched him fifty feet into the air and pinned him on the ceiling for all to see and say. "Damn that fool was stupid!"

There was some debate as to whether or not they should take his body down. Some wanted to leave it up there as a warning to future generations about improper reactor operation. They eventually had to take his body down as his wife wanted it. They sealed it in a lead lined coffin so the family would not be irradiated during the religious services for his burial. There were other releases out there at that US Government site in central Idaho. In Idaho Falls and Pocotello Idaho they wonder why they have such a high incidence of breast cancer. The US government will not tell them, but I know.

All across America the breast cancer rates point to nuclear sites. And if you test with radiation meters, the increase in background is clear but small. San Onofre in Southern California is famous for the half million women who have died from breast cancer withing fifty miles of the plant and for 100 miles to the east of it. (The wind again is usually from the west.) The background radiation is only slightly elevated over background, but the cancer rate is very high. What have they been doing at San Onofre to kill all those poor women? The nuclear insustry will tell you they are not at fault. Something like mass psychosis is causing all of these women to get sick and die.
 
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  • #29
Joe Neubarth said:
but I know.

And those are the only words that I take note of.

The rest would be interesting if you backed it up, but you finish with what stinks of conspiracy theory and so it loses all impact.

No comment on the veracity of what you say, but without something to substantiate it, there's really nothing in there to make me believe it.

EDIT: Your edit is noted, you really need to start posting sources to back up your claims or it will get you into trouble.
 
  • #32
QuantumPion said:
The large megaton bombs created huge amounts of fallout from fission. A 10 MT H-bomb may be 90% fusion, but that is still 1 MT worth of fission, which is ~40 times more than fat man/little boy. The extra neutrons generated by fusion were normally used to boost the bomb's output by fissioning a uranium tamper. The first H-bomb test was only ~75% fusion. Tsar Bomba was around 95% fusion but at over 50 MT, that is still 2.5 MT of fission.
yes, that is true, but my point is, you can't just multiply total yield by the ratio from fatman. There's been some really dirty tests, and some relatively clean ones. E.g. same Tsar Bomba, in full yield configuration, would have been about 100MT, of them 52 from fission (of u-238 by fast neutrons from fusion). That's what, 20x difference almost.
For fusion fallout also greatly depends to where it explodes. at ground level it can neutron-activate some dirt, in the air it would only neutron-activate the air, which doesn't make anything long living.
everyone else:
So much typical pro nuclear crap here - LNT as mere precaution (or even not knowing what LNT is to start with), improvement in life expectancy from healthcare = radiation is harmless, calculating the fallout from yield alone, etc etc. It's a little wonder nobody promoted hormesis and low grade uranium ore as healing stones yet.
 
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  • #33
Joe Neubarth said:
Come on Jared, you are trying to be humorous. When I say I'd be "willing to bet" means that it is a guess in the first place. It was vague and intended to be so because there are no numbers.

Now, for your edification, we could take the tremendous increase in radiation in Washington and other areas were radioactive processing has taken place (if you get the breast cancer charts for the United States per ratio of population you can see all the sites where fuel was processed or reactors have been in operation). Witness Eastern Idaho where there is a very high rate of breast cancer. The Winds usually (not always) blow from the west there.

So what was in Central Idaho or Western Idaho that caused this contamination that is killing thousands of women?

The answer, of course is Arco, Idaho where there were several nuclear accidents. At one nuclear site a control rod had an operator pinned to the ceiling after the dufus went to the top of the experimental reactor and pulled on the rod to free it because it was hung up on something. He created a super critical reactor and it exploded (Shades of Fukushima!) and launched him fifty feet into the air and pinned him on the ceiling for all to see and say. "Damn that fool was stupid!"

There was some debate as to whether or not they should take his body down. Some wanted to leave it up there as a warning to future generations about improper reactor operation. They eventually had to take his body down as his wife wanted it. They sealed it in a lead lined coffin so the family would not be irradiated during the religious services for his burial. There were other releases out there at that US Government site in central Idaho. In Idaho Falls and Pocotello Idaho they wonder why they have such a high incidence of breast cancer. The US government will not tell them, but I know.

All across America the breast cancer rates point to nuclear sites. And if you test with radiation meters, the increase in background is clear but small. San Onofre in Southern California is famous for the half million women who have died from breast cancer withing fifty miles of the plant and for 100 miles to the east of it. (The wind again is usually from the west.) The background radiation is only slightly elevated over background, but the cancer rate is very high. What have they been doing at San Onofre to kill all those poor women? The nuclear insustry will tell you they are not at fault. Something like mass psychosis is causing all of these women to get sick and die.

Geiger Counters have been around since 1908. Radiation was known since the Curies. Scientific inquiry and the concept of proving one's hypotheses goes back to the ancient greeks. But we can dispense with all that because Joe Neubarth is here. "The US government will not tell them, but I know." Hypothesis: San Onofre is causing breast cancer."
Proof is not required because Joe Knows. There is no need to consider smoking or California tans. No need to worry about atmospheric quality, or obesity, or any other genetic or environmental causes like radon or petroleum or chemicals, or consumption of Twinkies.

Next he'll trot out the Tooth Fairy Project. Joe knows. The little green men told him so. Tell us it ain't so Joe, BTW why do you all still live in such a dangerous place?
 
  • #34
clancy688 said:
All atmospheric nuclear tests ever conducted (~500) have a total yield of ~430 megatons. That's roughly 30.000 times Hiroshima (and 90% of the current US operational ICBM and SLBM arsenal).

Based on all the horror stories I have heard in my life about the ecological impact of nuclear weapons, I come inevitably to the conclusion that all of us must've been dead since at least 40 years.

[PLAIN]http://img204.imageshack.us/img204/4784/atomtestsbis1995.jpg [Broken]

[PLAIN]http://img222.imageshack.us/img222/648/megatonnageatomtestsbis.jpg [Broken]

Bulletin of the Atomic Scientists, May 1996I have no evidence, but at the beginning of the Fukushima crisis, german news channels reported, that during the early 1960s background radiation in Europe was three times the number after the Chernobyl disaster.

So you throw a lot of big numbers around to go wondering why it isn't a zero sum game ...

At which I could reply that your 430 megatonnes is but 10 seconds worth of rays from that other fusion generator high up above.

http://www.wolframalpha.com/input/?i=430+megatons&a=UnitClash_*megatons.*MegatonsOfTNT--

You are saying that you are not impressed ... neither am I .

But some say that to save one life is to save all of humanity ...
 
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  • #35
well there's the source.
http://envirocancer.cornell.edu/factsheet/physical/fs52.radiation.cfm [Broken]
for proving the hypothesis: the history is such that anything is presumed harmless until some large number of people are absolutely certainly harmed by it - e.g. see radium dial painters [being told that this stuff is actually good for them, so they keep pointing the paintbrushes with their lips - what the hell?], see quack radium medicines of first half of 20th century, see all the needless nuclear testing in USA (almost twice the testing that soviets did).

Fortunately, now, instead that proving that new drug or medicine is harmful, it has to be proved it is harmless. Fortunately now, before entire factory will be licking paintbrushes with paint on them, the paint has to be proven harmless (unless the factory is in china, of course, but maybe even there). Still, people don't change; they see it as their right to make us ingest and inhale random stuff until it is proven beyond any slightest doubt whatsoever that it is harmful.
 
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<h2>1. Why is the Fukushima nuclear crisis considered a threat?</h2><p>The Fukushima nuclear crisis is considered a threat because it involves a damaged nuclear power plant that is releasing radioactive materials into the environment. These radioactive materials can have harmful effects on human health and the environment, and the situation is still ongoing with no clear end in sight.</p><h2>2. What caused the Fukushima nuclear crisis?</h2><p>The Fukushima nuclear crisis was caused by a massive earthquake and subsequent tsunami that struck Japan in 2011. The natural disasters damaged the power supply and cooling systems at the Fukushima Daiichi nuclear power plant, leading to a series of explosions and meltdowns in the reactors.</p><h2>3. How is the Fukushima nuclear crisis being managed?</h2><p>The Fukushima nuclear crisis is being managed through a combination of measures, including stabilizing the damaged reactors, containing and treating contaminated water, and decontaminating the surrounding area. The Japanese government and the plant's operator, Tokyo Electric Power Company (TEPCO), are also working to monitor and assess the situation to determine the best course of action.</p><h2>4. What are the potential long-term effects of the Fukushima nuclear crisis?</h2><p>The potential long-term effects of the Fukushima nuclear crisis include environmental contamination, health risks for the local population, and economic impacts. The radioactive materials released from the damaged reactors can have long-lasting effects on the environment and can also cause health problems such as cancer. The economic impacts include the cost of cleanup and compensation for those affected.</p><h2>5. What is being done to prevent future nuclear crises like Fukushima?</h2><p>Since the Fukushima nuclear crisis, there have been increased safety regulations and measures put in place to prevent future nuclear disasters. These include improved emergency response plans, stricter safety standards for nuclear power plants, and better disaster preparedness. Additionally, there has been a shift towards renewable energy sources to reduce reliance on nuclear power.</p>

1. Why is the Fukushima nuclear crisis considered a threat?

The Fukushima nuclear crisis is considered a threat because it involves a damaged nuclear power plant that is releasing radioactive materials into the environment. These radioactive materials can have harmful effects on human health and the environment, and the situation is still ongoing with no clear end in sight.

2. What caused the Fukushima nuclear crisis?

The Fukushima nuclear crisis was caused by a massive earthquake and subsequent tsunami that struck Japan in 2011. The natural disasters damaged the power supply and cooling systems at the Fukushima Daiichi nuclear power plant, leading to a series of explosions and meltdowns in the reactors.

3. How is the Fukushima nuclear crisis being managed?

The Fukushima nuclear crisis is being managed through a combination of measures, including stabilizing the damaged reactors, containing and treating contaminated water, and decontaminating the surrounding area. The Japanese government and the plant's operator, Tokyo Electric Power Company (TEPCO), are also working to monitor and assess the situation to determine the best course of action.

4. What are the potential long-term effects of the Fukushima nuclear crisis?

The potential long-term effects of the Fukushima nuclear crisis include environmental contamination, health risks for the local population, and economic impacts. The radioactive materials released from the damaged reactors can have long-lasting effects on the environment and can also cause health problems such as cancer. The economic impacts include the cost of cleanup and compensation for those affected.

5. What is being done to prevent future nuclear crises like Fukushima?

Since the Fukushima nuclear crisis, there have been increased safety regulations and measures put in place to prevent future nuclear disasters. These include improved emergency response plans, stricter safety standards for nuclear power plants, and better disaster preparedness. Additionally, there has been a shift towards renewable energy sources to reduce reliance on nuclear power.

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