It should be evident to anybody following the situation closely that the official story is full of holes or painted very optimistically.

At least one core and/or spent fuel pool is hosed so that it is leaking very high radioactive material either via the burning process and/or via the water leakage pathways.

Reasons to support this reasoning:

- workers who got beta burns were in the Turbine hall next to reactor 3 hall, not even the reactor 3 hall itself

- if you get beta burns, that means that primary fuel has escaped the fuel rods

- there is zirconium alloy in the seawater according to the Japanese media. Again a sign that the zircalloy fuel rod cladding has broken down somewhere (core or pool)

- the water into which the beta burn victims stepped, supposedly had 10 000 times the amount of radiation as the water inside the reactor normally has. This means two things: 1) fuel rods are badly damaged. 2) the material from fuel either via water pumping or burning, has escaped/is escaping the core. The alternative is the spent fuel pool. Just by reasoning from temps and thermal content in each, I'd put my bet on the reactor. The Japanese officials have now finally admitted to the possibility of this, because they can't deny it anymore

- Situation in 1,2 is still not stable, as shown by the evacuation, high radiation readings, slowness of doing anything inside those reactor buildings and the fluctuation in temp/pressure data.

- The idea that the workers didn't believe their dosimeters and kept working because they thought they were all wrong is, imho, laughable. If you look at the interviews of the firemen breaking down crying and apologizing for the families of the men who had to go inside and the coverage of the beta burn victims you pretty much get an idea of how dire the situation is down there. And that's just the turbine hall. It's a level up from there once you try and enter the the actual reactor hall 3.

This will be upgraded to INES 6 soon and they will try and keep the victims out of the spotlight and gag everybody, but more cracks will show.

Even though the thermal power drops in log fashion, if there's no cooling, there's still plenty of thermal power to do more damage.

Of course there's very little they can do about things already done and happened, but I would have thought that they would have learned form the Chernobyl accident two things: 1) don't cover up the bad stuff, even if you want to avoid panic. 2) don't do hieararchical slow top-down-command and wait for things to settle down.

To me, judging from outside and giving a lot of credit to the efforts people in Fukushima have done to contain this, I think they may have also repeated the both mistakes of Chernobyl.

And no, I'm not comparing the Fukushima incident to Chernobyl in other ways.

I just thought that by now, after TMI, Cherno and others, we would have learned the lessons about how to do these things.

Apparently not.

EDIT: I'm not anti-nuclear. But I am anti-cover-up and anti-lying.

Unless JAIF changes it's status of the containment vessel integrity for Reactor #3 back to "Damage Suspected," I think we can pretty much write off this source as unreliable. Nearly every press account, and the Nuclear and Industrial Safety Agency (NISA) of Japan have all indicated concerns with the Reactor #3 containment vessel integrity following exposure of workers to very highly contaminated water in the turbine building of this reactor.

Alan, with your prescribed remedy, please explain how you would resolve the radioactive material melting through the bottom of the reactor vessel into the surrounding water table(which is directly on the coastline at sea level). I would love to hear the technicals of your proposal, as would the readers of Seeking Alpha and ZeroHedge.

Well, that's a more creative idea than just entombing everything in concrete, I'll give the one who suggested it that. The reactor buildings are over 50' high though; to build a berm around them the usual rule of thumb is double the width for the desired height. A berm like that would need to be at least 100' wide, meaning the turbine buildings would need to be demolished. The turbine buildings have direct links to the reactors anyway via pipes and ducts, and since radioactivity is present in them as well something has to be done with them too.

The amount of residual heat that is given off keeps declining as time goes by - usually after a year or two the waste is cool enough that dry cask storage can be used, and that reduces a lot of the ongoing maintenance.

Just a WAG broad brush comment.

For years, decades, not much happens. The fuel rods (presumably sealed in concrete or lead casks or similar) quietly corrode and eventually start releasing their isotopes and plutonium into the sea water, which is slowly dispersed to very low levels by deep sea currents over vast ranges.

Over a period of decades and centuries, some of the biologically active isotopes are incorporated at low levels into the food chain, and as generations pass, the levels build up and up in the top level predators until they occur at harmful concentrations.

Assuming that by this time we humans have not already fished all the higher predators to extinction, one of two things happen.

Either we start catching these fish, and build up levels in our bodies until we start suffering, or (if we have stopped fishing) they stay in the predators, and eventually reach the levels where they become sufficiently sick to lose out to competing species and become extinct.

This continues for many thousands of years, until the levels in the sea water fall due to radioactive decay, or the contamination is trapped in deep sea sediments.

High-level radiation suspected to be leaking from No. 3 reactor's core
http://mdn.mainichi.jp/mdnnews/news/20110325p2g00m0dm028000c.html

But no data, such as on the pressure level, have suggested the reactor vessel has been cracked or damaged, agency spokesman Hidehiko Nishiyama emphasized at an afternoon press conference, backing down from his previous remark that there is a good chance that the reactor has been damaged. It remains uncertain how the leakage happened, he added.

Bruce, in my opinion you're out of your depth here. Like you I thought they'd pretty much get the Macondo situation under control as soon as they tried the obvious (attach something that didn't have a hole in it).

This is way different and they are just hanging on and no more. They could completely lose this at any time. The worst possible outcomes are still very real but almost unthinkable in scope for Japan and the world. Latest quote from the Japanese prime-minister is that he is not optimistic but that they are trying everything they can.

Shouting at us with multiple exclamation marks doesn't make it all right.

It seems you are unfamiliar with Kabuki theater. http://en.wikipedia.org/wiki/Kabuki

A jōruri play may sacrifice the details of sets, puppets, or action in favor of the chanter, while kabuki is known to sacrifice drama and even the plot to highlight an actor's talents. It was not uncommon in kabuki to insert or remove individual scenes from a day's schedule in order to cater to the talents or desires of an individual actor—scenes he was famed for, or that featured him, would be inserted into a program without regard to plot continuity

What once took one American water cannon, then took 6 of Tokyo's ace fire fighting teams now takes 19 fire trucks! The Fukushima 50 has grown to the Fukushima 500 on its way to become the Fukushima 5000 (Hey it will one day be a great way to get laid! "I faced the radiation but had to be withdrawn due to extreme radiation levels.")

You are being played.

Edit Want proof? Watch the video of the two workers with radiation burned feet walk out before the cameras behind a blue tarp. Boy do they have tough coaches in Japan, "Just walk it off!"

It happens. Writers here are unpaid and try to get best info out in timely fashion. Its possible the source of that image was unavailable at the time of posting. If you email the editors inbox with appropriate reference/credentials, Ill see they are added to the image. Thx.

Someone will likely get useful information from this data and if they can use it to a greater good you needn't worry about copyright infringement.

I think the graph is showing a thermal diffusion controlled decay from a wide range of half-life times. It looks like it goes as 1/(1+a*t^k) where k=1/3 due to the random walk of thermal diffusion. (I would think it goes as k=1/2 but the reference data fits better for 1/3)

This is a problem because the heat initially comes down very fast but then starts to really slow down as the slower decay rates take over.

edit:: it is likely that the distribution of radioactive energies goes as 1/E^(2/3) which would match the fat-tailed fall-off. A very wide dispersion in emitting energies leads to fatter tails. Thermal diffusion is less important here,

There's a lot of out of spec stuff going on. Thermal shock, expansion/contraction, unplanned for chemical reactions; all of this on top of a 9.0 and explosions. Vulnerable areas would be welds (notorious for pre-existing anomalies and faults), flange seals, etc. The manifold/tubing interfaces in the condensers are fairly complex and vulnerable. There's plenty that could have gone wrong at this point. Once these faults present themselves they generally get worse over time, eventually failing catastrophically. Dumping cold water onto/into overheated reactor components is about the worse thing they could do. Seems they've had no choice.

"I guess the piping is stainles and the structural carbon?"

Yes on stainless piping, I suspect a HSLA steel instead of SA-516-70. That would be cutting it too tight. 2.25-cr 1Mo steel is rated to 1200 F, so you'd have a decent margin to work without making the vessel ridiculously thick, which makes other problems.

if they were using 304 stainless piping, and then soaked them in boiling seawater; it's just plain bad.

Chlorides; check
Oxygen, came with the seawater, check
Austenitic stainless steel; check (304, 316, 321,347, 309, 310, it doesn't matter.)
Stress, preferably tensile; after an earthquake and various explosions, yeah, check;
Temperature; oh yeah baby; check.

Yup, they are screwed. Chloride stress corrosion cracking.

I see from the status report for March 26 in this link, that they now have "fresh water" being injected into Units 1 and 3 (Three cheers!):

http://www.nisa.meti.go.jp/english/files/en20110326-2-2.pdf

However, the Richard T. Lahey Jr. report of 57,000 to 99,000 pounds of salt previously deposited by boiling seawater means, that in the near term the chloride concentrations in the boiling water are going to be near sodium chloride saturation (391 grams /liter at 100C)- more than a ten fold chloride increase above just seawater(35 grams/liter). This is even more corrosive than just sea water . In addition to stress corrosion cracking, pitting corrosion also occurs which can punch small holes in the piping leading to local leaks.

The temperature and pressures for unit 3 suggests the system is boiling near sodium chloride saturation. The boiling point of saturated brine at atmospheric pressure is 226F= 107.7C. The NISA link above reports the feedwater nozzle temperature is 107C and bottom head of RPV (reactor pressure vessel) = 100C. about right for saturated brine boiling point.

Unit 1 is hotter at 195.3C and that temperature is not consistent with a pressure of 0.477MPa. The vapor pressure of water at 200C is 1.55 MPa. Thus to maintain a water phase at 195C, the pressure has to be higher than 0.477 MPa. I am speculating, but either the system is not at equilibrium, the measurements are wrong, there is no liquid water in Unit 1, or a piping break is releasing steam pressure. Perhaps others could look at this too. Here is the link I used for water vapor pressures, but my steam calculations are rusty from disuse. Others are free to comment!

http://hyperphysics.phy-astr.gsu.edu/hbase/kinetic/watvap.html

The prediction of the time to failure from chloride stress corrosion cracking is notoriously variable since it depends on metallurgical structure as well as tensile stress and environmental conditions. This quote from a NRC report NUREG-1061 Volume 3 indicates that piping leaks are more likely than large breaks::

http://pbadupws.nrc.gov/docs/ML0931/ML093170485.pdf

From :Report of the U.S. Nuclear Regulatory Commission
Piping Review Committee

Evaluation of Potential for Pipe Breaks

BWRs pose a different problem because of intergranular stress corrosion cracking (IGSCC). The incidence of IGSCC is far higher than all other failure mechanisms in large piping; however, the toughness of the austenite alloy leads to an anticipation of leak-before-break controlling rather than large break.

After additional review,it is realized that in certain systems and for certain materials, thermal fatigue and stress corrosion cracking cannot be absolutely excluded from piping operation, nor can steam or water hammer. It may also never be possible to specify precise "acceptable levels" of thermal fatigue and stress corrosion cracking, nor to assure analytically that these levels would not be exceeded. However, if these unanticipated severe conditions were to occur, the break would most likely be located at the terminal ends, at the connections to components, and at other locations which introduce higher stress concentration or that exceed the stated threshold limits in SRP 3.6.2.

I hope they are allowed to bring all their stuff. It could be a couple years before some of them can return home...and by that time I doubt they will really want whatever they left behind.

Also fromy your linked NY Times article

Concerns about Reactor No. 3 have surfaced before. Japanese officials said nine days ago that the reactor vessel may have been damaged.

A senior nuclear executive who insisted on anonymity but has broad contacts in Japan said that there was a long vertical crack running down the side of the reactor vessel itself. The crack runs down below the water level in the reactor and has been leaking fluids and gases, he said.

The part in italics is clearly the editor's opinion and not anything the officials may have said. Had they done so it would have been quoted. The explanation I heard, that asking people to stay indefinitely in their homes is unrealistic, is much more plausible.

It's come up here before and TEPCO were instructed to prevent re-criticality in fuel pool 4 at one point. No instruction has appeared in print regarding re-criticality at other locations but I'm surprised they published anything at all.

At the latest TEPCO press conference it was stated that the concentrations of iodine-131 and caesium-140/141 (can't be sure which and have not seen a repeat but he didn't say 137) suggested the water contamination could only have come from the reactor. These caesium isotopes have half lives of roughly 60 and 30 secs.

One aspect that I can't find any information about is the salt accumulation and what, if any, its impact would be on a scenario like this. I realize that it was not likely ever considered when these plant designs were first conceived, so likely no published studies, but I wonder. Aside from the corrosion, and reducing cooling efficiency, what else can the salt do? Does it act as a better moderator than water? Can it hinder or promote a reaction? I'm having a hard time finding any discussion of this.

I understand that they are mixing in boron as well, to absorb neutrons; this makes me wonder about corrosion of the reactor vessel - will the seawater plus boron be worse than water alone. If I'm not mistaken, boric acid was a primary cause of the corrosion issue on the reactor head at Davis-Besse.

...Offen said in addition to any threat to a crew's health, radioactive contamination of a container ship and its load were not covered by insurance.

I am still waiting for a credible offer to insure 68 acres of Iowa farmland against a crop loss due to radiological contamination. I have heard nothing.

Until insurance underwriters (or governments) will underwrite policies for shipping and farming losses, Nuclear energy is absolutely, conclusively, and positively dead. I will further argue that anyone seriously advocating nuclear energy while failing to indemnify farming & shipping is committing crimes against humanity. I would advise anyone in the nuclear industry to consider potential civil and criminal liability that will arise in the next few years as what is currently being hidden is disclosed.

Get insurance now, or get the hell out of the industry.

This is a good example of the economic losses spreading from this accident. When calculating the cost per kilowatt from nuclear power, surely we must consider all of these costs as well. In that case, the cost of nuclear is a lot higher than the few cents typically claimed.

Everything I have is held together with tape and glue these days.

I agree they likely have no idea what the true state of the equipment is. They are leaking cooling water everywhere it seems.

I bet no one knows what happens with stainless steel under a nuclear heat load with salt water. This would be what we call n = 1 science. Trial and error, perhaps, is the more colloquial expression.

"the nuclear regulatory agency ordered the utility known as TEPCO to improve radiation management at the power station"

This is just another indication that they have no competence in dealing with this situation. The nuclear industry and regulatory authorities have for too long been allowed to spend a peaceful complacent existence. Accidents have been rare and small in scale. There is no experience - or even anticipation for anything like this. I'm sure their meetings for safety planning have run through all kinds of scenarios - but the most radical ones have been deemed too impossible to warrant any deeper thinking or wasting time and money on.

I can Imagine what their 'Safety Procedure Manual' on page 'Plant Emergency Scenario no. 999 says': "In the event that you loose all power for a week in all reactors, three of the reactor buildings blow to pieces, taking with them containment, cooling and control and monitoring systems". Followed by a blank page.

As they say in the comedy biz "timing is everything".

Tangently related to MSM brown outs. Maybe it's just me but... these sensors took a very interesting time to 'malfunction'.

Glitches hamper radiation warning system in California

The federal government's radiation alert network in California is not fully functional, leaving the stretch of coast between Los Angeles and San Francisco without the crucial real-time warning system in the event of a nuclear emergency.

Six of the Environmental Protection Agency's 12 California sensors — including the three closest to the Diablo Canyon nuclear power plant near San Luis Obispo — are sending data with "anomalies" to the agency's laboratory in Montgomery, Ala., said Mike Bandrowski, manager of the EPA's radiation program.

Kinda reminds me of the funny tricks the stock exchange numbers did during Sept-Oct of 2008. Nah. Probably nothing.

ITS NOT RADIATION that we should be talking about but CONTAMINATION

Very few reporters have made that distinction, alas.

Dr Helen Caldicott discusses that issue with Alex Smith in the latest Radio Ecoshock Podcast:

http://www.ecoshock.info/2011/03/nuclear-nightmare-continues.html

You have pointed out the key issue in the long run, and the most underrated currently. Contamination is the key to the long term effects of this disaster.

I have a few questions that seem not to be addressed well yet:
1. How large an area has been contaminated to the point that it is going to be an "involuntary park"? What shape?
2. What ultimately can be done with the reactors? The sarcophagus option seems more and more likely. Disassembly?
3. What will be done about the massive amounts of melted down fuel, both in the reactors and in the ponds? Leave it there? (this one is decently discussed in this thread, actually)
4. What about the other nuclear sites in Japan, and the future of Japanese power production? Fukushima II (dai-ni) is within the danger area, so should it be taken offline as well, or like with Chernobyl will it continue to be used by workers that commute in and out of the danger zone?

All of these are very serious issues. If a 50 mile zone was to be evacuated, that would cover some pretty heavily populated areas - literally hundreds of thousands of people. If a 30 km zone is settled on it will be much less severe. Still, that means many towns and much land left to return to wilderness, and it will mean routing around the area, so the coastal highways and such would no longer be useable (or rather, would remain in the whatever ruined state they may be in due to the earthquake and tsunami). If containment long term is decided to occur on-site, that means they will either have to build a new containment building nearby, go the sarcophagus route, or both (sarcophogus for reactors themselves, and new containment for spent fuel and other fuel?). If not, where will they put it?

As for nuclear as a whole in Japan, I can't imagine what is being built to be finished. If new nuclear is not put in, then on top of the already lost capacity you have to deal with what to do in the future. Wind, hydro (already built up very heavily in Japan), and geothermal, perhaps? Can Japan transition? What about the massive amounts of existing nuclear? Decommission or extend and hope this doesn't happen twice? It appears that people are learning to do without electric advertising and with less heat in the Tokyo area, how much conservation is practical? If Tokyo gets to the point of not having rolling blackouts but still has to live with conservation measures, can it still be a megacity capital of world commerce?

This whole thing is very complex.

Gomennasai if I insult any Japanese who read this - but this is because you are such sticklers for rules and regulations - any will do - not able to function without.

Forget original thinking - the drive towards conformity is staggering. Even they themselves admit to this - they have a saying: "the nail that sticks out should be hammered down". So you get few innovators who drive the technology industry - but most worker drones and officials have been brought up by a system that allows absolutely no independent thinking or deviation from the norm. Enter unusual circumstances and this is the result.

I love Japan and am looking forward going to visit friends late summer. Hope there is something left to visit...

In light of the fact that they have been bombarding the nuclear plant with water for the past 2 weeks (minus a day or so of posterior scratching) "Who could have predicted there would be radioactive water in the basement?"

The reactions to the crisis have been much slower and more measured than I would have expected. I can't fathom not getting emergency generator sets and fuel in there within 12 hours. Hard to believe they are sending in fresh water barges only now. I can get generators, pumps, water cannons, portable piping, etc. on-site anywhere in the state in a day, and that's without government help. Sure, things were terribly disrupted by the quake and tsunami, but you would have thought the Japanese government would have gotten them any resources they needed at the site if they had asked.

I wonder if Tepco's hierarchy in particular slowed down the implementation of emergency measures?

I've seen it said that in general the Japanese do not function well as a group when "the plan" doesn't work. Give them a plan and trained to execute it, and they will do very well. Screw 'the plan' up, and they don't do well at all. I'm not saying the Japanese can't innovate or be creative, but their society values compliance and following the rules, not taking risks.

Fukushima went off "the plan" a few hours after the diesel generators went offline, IMO. The batteries were only able to keep controls and sensors running, and when the portable generators didn't work there wasn't anything left in 'the plan' to try. Nothing in their crisis scenarios expected to be dealing with a loss of offsite power and disabling of the diesel generators simultaneously. I read early on during this crisis that US nuclear experts were making suggestions to them on what to do next and no one on the Japanese side was willing to take responsibility, because it wasn't in "the plan".

The World Without Us by Alan Weisman
He does describe spent fuel storage pools boiling dry and catching fire. Chapter 15 "Hot Legacy", part 4 "Too Cheap to Meter".

PS - The cockroaches will be fine.

"Most of them were military conscripts which were ordered to run inside and do even the most minute task. Many of them died of cancer later on but they saved the population."

That's an interesting point. Do you expose a small number of people to certainly lethal doses, or spread out the exposure over a large number of people, only some of whom will die over the next few decades? Which method has the lowest cost in person-years of life?

Who is ghoulish enough to study that sort of situation? And yet it's critical to know for real emergencies.

Yes, without immediate and effective action to deal with the radioactive waste already in existence, this WILL be our default future-or rather, lack of future. Every other kind of planning or preparation is ultimately irrelevant.

I should point out that Cs 136 has two states, spin 8 has half life of 19s and spin 5 of 13 days. But the Cl 38 is still troubling

Ok the implications of that list of isotopes scares me. In order for those short lived isotopes to still be present in the water, a nuclear chain reaction is still taking place inside Reactor 1's core. I thought that was impossible, what with the control rods inserted, boron flooding the core, and damage to the fuel rod geometry.

Is it possible that the operators only thought the control rods had been fully inserted, and the boron hasn't been as effective for whatever reason? Plus, if there's a chain reaction still taking place in #1, what's going on in #2 and 3?

Yow. By my calculations it won't kill you to stand near the stuff, but you definitely do not want to take a bath in it.

You want the unit #3 report, the mox fueled plant.

It's not a matter of turning the key and letting 'er rip. All the fuel rods have been removed. Refueling a plant like this is a labor-intensive, multi-week process, and one you really don't want to do when hell's own furnace is pumping out gamma rays a few hundred yards down the road.

They have on-site power. The grid. Why start 5 or 6??

Anyone who believes that decontamination has to involve million-dollar gadgetry has been watching too many movies. Never underestimate the power of a plain old bucket of soapy water, rubber gloves, and a sponge.

No you are the one that is stupid.

These workers are injured. How else do you decontaminate anything? You wipe it down. Although they should have been wiped down at the plant. On the good side their feet can take more radiation then their organs.

an example:

http://www.jlab.org/div_dept/train/rad_guide/dose.html

ORGAN --------DOE DOSE LIMIT
Extremities---50 rem/year

These workers got 17-18 rem on their extremities.

To answer your question it got there by being both the low bidder and an American design.

Considering the efficiency of our own biological metabolism ,
it is beyond wonder why that same efficiency would rely on the reduction of heavy elements ?
Especially when our input is fully provided for by an equally ingenious fotosynthetic metabolism.

I'd say it's a tragedy of over-abundance.

And follies.

And perhaps with a tiny amount of creative destruction

Or universal creation

"In my humble opinion, in the nuclear world, the true enemy is war itself"
- Commander Hunter, in Crimson Tide

I'd say, "In my humble opinion, in the nuclear world, the true enemy is nuclear technology itself"

To me, this is like Edgar Allen Poe's 'The Birthmark', where we have sought to find an energy source so ideal and free of blemish, that we have have applied mortal poisons in our frenzied rush to realize this immortal ideal.. and it's supporters are still puzzled by both the failures and the unbelievers.

As a friend once said to me about something else.. "It would be perfect, but there are humans involved."

`Prophet!' said I, `thing of evil! - prophet still, if bird or devil! -
Whether tempter sent, or whether tempest tossed thee here ashore,
Desolate yet all undaunted, on this desert land enchanted -
On this home by horror haunted - tell me truly, I implore -
Is there - is there balm in Gilead? - tell me - tell me, I implore!'
Quoth the raven, `Nevermore.'

I don't agree with your assessment "clean" and "emission free" about nuclear power!!

The plants take millions of tons of cement to build and that takes cement trucks, bulldozers, the engineers and their cars, the whole oil complex in other words, has to be in place first. Lots of emissions in other words....

The oil complex was but one link in the poisonous chain you describe...

Oil spoiled people and made them used to luxuries and ways of life they had never imagined before.
Oil is somewhat like "magic"---its power is not deeply understood, but it sure can bring heavy huge things far and that is all we need for a massive monumental something, something that will turn into goddawful garbage later.

Oil getting expensive drives desperate people to find alternatives that are even worse.

The second law of thermodynamics is still not widely understood either but I think people are starting to pick up on it. The piles of garbage we generated with all our oil will surely be with us for many many generations to come. Some of the garbage will be highly radioactive.

"...technology is stunningly beautiful, irresistibly seductive..."
Your words remind me very strongly of high-end weapons work.
This stuff is breathtaking in concept and beautifully made.
But it's deployed by the amoral to rob resources from the poor.
Security, nonexistent.
... The lesson was the same: The weakness of systems of humans.

+1

This problem is clearly well beyond the capabilities of not only TEPCO, but also of the Japanese government.
There needs to be a concerted effort to provide help, before this thing becomes entirely unmanageable.
We face the prospect of 1800 tons of nuclear fuel gradually decaying and daily emitting radioactive byproducts equal to 10% of the Chernobyl total from somewhere in a heap of scrap a half mile long. Not good for anyone, not just the Japanese.

And so it goes

Misinformation Clouds Much Japan Coverage

...“I went to the BBC and I started watching the coverage there, and as it progressed I was shocked because I always thought the BBC was a fairly straightforward news organization—but it was starting to not match what I could see was going on,” said Woolner, a thirty-five-year-old theatre artist born in Canada. He moved to Japan close to eight years ago.

...That was two weeks ago. As time passed, Woolner said the gap between the reality he and others in Japan were experiencing and what international media was reporting seem to widen. He’s not alone in that assessment.

If nuclear is safe and good, then why aren't we hearing all the great stories of how the site is secure and safe and plain clothed people can skip rocks in the puddles and farmers can grown veggies a mile or two away from the plant. Coast is clear right?

My bet is the newspapers are worried about this destabilizing the markets. It may be very complex why the media is ignoring this.

Linsay Lohan!
And that baseball guy with the possible shrunken testicles!
Elizabeth Taylor... which takes us right to Michael Jackson!
They should just offer Mel Gibson big money
to do something really stupid
right about now.
====================================================
Google has their "Nuclear Power" heading back up, not "Accident"
or "Disaster".

Neutron Beams
These are generated when Hopium decays into Despairium.

It is not know where the Hopium comes from in nuclear accidents, but its appearance is correlated with the release of Official Statements and is thought to involve changes in the spin state of Disasterium.

Some political scientist believe that if you do not observe the Disasterium, or spin it intensely enough, then its state cannot be known with certainty, and the ultimate generation of Desparium will be avoided.

The problem is that Hopium is very unstable, with a half-life of just a few weeks, regardless of the energy put into the spin-field.

Intense neutron emission and the presence of radioisotopes with short half lives indicate fission is occurring or has recently occurred. A free neutron has a half life of 14 minutes and 46 seconds.

that's got to be as translation error.you would have neutron hot spots. unless you have a hot neutron source and some kind of culminator.

The biggest surprise for me is that these japanese reactors dont seem to have had overpreassure vents for the containment. Is that oversight correct?

The Swedish ones were built with overpreassure vents from day one and about 20 years ago were they complemeted with overpreassure vents that would open at a lower preassure and vent thru a filter, for the now closed Barsebäck plant a giant silo filed with gravel and each of the other reactors has a water tank to bubble the gasses thru followed by a moisture separator. As far as I know it is a passive non electrified system with a parallell valve to the bursting diaphragm for manual venting.

I would add to that list the design choice to not locate the reactor complex on higher ground. This questionable decision was mentioned in previous threads, but I have not seen any estimate of the cost of vs. altitude trade-offs.

Is the energy cost of pumping sea water uphill the main factor?

Any one seen a link / Video of Unit 4 blowing up? Unit 1 & 3 explosions were so different.
Did I just miss it or was it in the middle of the night or censored?

After thinking about the hydrogen explosions some more, reactor building 4 also exploded even though it had no fuel in the containment vessel. Maybe the hydrogen for each of the explosions came from the spent fuel rod ponds instead of the reactor vessels. There might not be a hydrogen recombiners at the pools.

This venting system works by moving steam and radioactive gas from the primary containment vessel through the reactor building, and to the large 100 meter emissions stacks located outside the power plants (which can filter and diffuse the gas to minimize it's environmental impact).

Wow - so that is what those read and white derricks are for. They sure did not work out as planned. Just a question: Units 1&2 have a tower between them. Units 3&4 have a tower between them. And there is another tower just south of Unit 4, and it has four pipes going up it, whereas the other two towers seem to have just one pipe. Make anything of that?

HTH

NAOM