fukushima.html

---
layout: default
title: The Fukushima Accident
category: issues
description: Learn about the Fukushima nuclear accident
author: nick
date: 2011-03-15
byline: true
---
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        <div class="float-end"><img class="img-rounded img-fluid" src="img/fuku-march30-aerial-small.jpg" title="Fukushima Dai-ichi unit 3" alt="Fukushima Dai-ichi unit 3" /></div>
        <p>
     On March 11, 2011, a historically large earthquake struck Japan, which gets
     a large percentage of its electricity from nuclear power plants. All
     affected plants automatically shut down by inserting control rods into the
     cores (an operation called a SCRAM). After each SCRAM, the nuclear chain
     reaction in each core stopped and total heat generation went immediately
     down to about 6% and decreasing. However, nuclear reactors cannot be turned
     completely off immediately. Splitting atoms produces smaller atoms, many of
     which are radioactive. These produce quite a bit of heat as they emit
     alpha, beta, and gamma <a href="{% link radioactivity.md %}">radiation</a>,
     even in the absence of a chain reaction. As these fission products decay,
     the heat generation decays away with time exponentially.   
    </p>

<p>The plants were not built to be able to handle an earthquake and tsunami of
the magnitude seen. This error in judgment and knowledge of the environment at
that site led to under-engineering of the backup systems. This has caused the
loss of these plants, a general downturn in public acceptance of nuclear energy,
and radioactive contamination of a large chunk of Japan. So far, no one has died
from radiological reasons (2 workers were lost in the tsunami). </p>

    <div class="card border-success mb-3">
      <div class="card-header bg-success text-white">Meltdown</div>
      <div class="card-body">Even if a nuclear reactor is shut down, it still
      produces quite a bit of <a href="{% link decay-heat.html %}">decay
      heat</a> that must be cooled to prevent the fuel from overheating and
      melting. If all the fuel melts (known as a meltdown), there is a higher
      chance that the radiation that was contained within the pins could get
      outside the reactor.</div>
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	<p>The emergency diesel generators and/or their fuel supplies at the 5 of
	the 6 reactors at the Fukushima Daiichi site were flooded by the tsunami
	that followed the quake. At this time, the plants entered a station blackout
	condition. Extra engineered features that do not require electricity to
	operate attempted to remove the decay heat and prevent fuel melting, but
	these can only work for a certain amount of time, and they eventually failed
	in units 1 through 3. Unit 4&rsquo;s fuel was all in the spent fuel pool
	(the reactor had been undergoing an outage at the time) and it is unclear
	why there was a hydrogen explosion there. </p>

    <div class="card border-success mb-3">
      <div class="card-header bg-success text-white">Earthquakes</div>
      <div class="card-body">Extremely large earthquakes leading to loss of
      decay heat removal is considered one of the highest likelihood events to
      cause core damage in a nuclear reactor.</div>
    </div>

	<p>After station black-out, unit 1&rsquo;s engineered safety system (an
	isolation condenser, or IC) went dry after 18 minutes (should have lasted
	days). Hours later, the fuel melted and produced hydrogen, which soon
	exploded. In units 2 and 3, a system called the RCIC (which uses steam
	generated by the decay heat to circulate water) cooled the reactors for ~2
	days before failing, finally allowing the fuel to melt. </p>
	
	<p>Fuel melted in the reactor vessels of units 1 through 3 and seems to have
	penetrated through the reactor pressure vessel. In unit 4, the fuel in the
	spent fuel pool seems to have melted, probably due to a leak in the pool
	(since it should have taken at least 10 days to boil off that much water).
	When fuel gets very hot in these reactors, the Zirconium cladding interacts
	with water and produces hydrogen. In units 1 through 3, hydrogen explosions
	occurred and caused damage to the reactors. </p>


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    <hr/>



    <div class="row"> <div class="col-md-8"> <h1>What&rsquo;s happening?</h1> 
    <h2>These old updates are left here for historical perspective. Info is much
    more understood at this time</h2> <h2>Update, March 16</h2> <p>Today&rsquo;s
    concerns seem focused on the spent fuel pools, particularly in units 3 and
    4. White smoke was seen coming out of unit 3, indicative of burning
    Zirconium and therefore melting rods. With the secondary containments
    damaged, these exposed spent fuel pools would have a direct path to release
    radiation into the environment if the water level truly has dried out,
    leading to local radiation levels that would make it difficult to continue
    cooling operations on the site. This development is extremely surprising
    because spent fuel pools do not require substantial cooling to keep cool. If
    a firetruck could hook up outside the building and pump in water, this
    problem seems like it would be avoided! We&rsquo;re anxiously awaiting
    details and hoping off-site power can be restored immediately. We keep
    cheering on and appreciating the efforts of the heroes who are working on
    this disaster in the high radiation environment.  </p> 
    
    <h2>Update, March 15</h2> <p>A third hydrogen explosion occurred yesterday
    at unit two at Fukushima, but rather than happening in the not-so-important
    secondary containment, this one happened below the core, near an area called
    the suppression pool. Pressure dropped and coolant levels did not rise after
    this, suggesting that coolant is going from the pressure vessel into the
    primary containment. Meanwhile, at unit 4 (which was shut down before the
    earthquake), a fire broke out last night and was subsequently extinguished.
    The spent fuel pools in that unit (and the others) is in need of cooling as
    well, and will probably be doused with cold water. Decay heat in the spent
    fuel heats up the water surrounding it. As in the core, if the rods are
    exposed to air, they may melt and release their radiation. Very high doses
    were measured on the site when the fire happened (40 rem/hr), but these have
    since fallen drastically. Readings off-site are still fairly low. </p> 
    <h2>Update, March 14</h2> <p>Three of the 6 reactor cores on the Fukushima
    Daiichi site are experiencing coolability problems and have experienced
    partial melting of the fuel elements. Two barriers of protection are still
    intact (the pressure vessels and the reactor containments), but the vessel
    in at least one of the reactors has so much pressure in it (from steam
    buildup) that attempts to pump in seawater are failing. The valve that is
    supposed to relieve this pressure is apparently stuck. Efforts to ensure
    cooling are ongoing.  </p>
    
    <h2>Initial posting, March 12</h2>
    
    
    <p>In an attempt to piece the details together, it seems that Fukushima shut
    down like the other plants and the main pumps failed probably due to the
    loss of offsite power (since the whole electricity grid went down at the
    same time). At that time, diesel generators kicked in to power the emergency
    core cooling systems to cool the decay heat. Then, when the tsunami hit, the
    redundant diesel generators failed (probably due to fuel tank and/or piping
    problems). This kind of large event is known as a common mode failure. With
    no power for the emergency pumps, the water covering the hot fuel rods
    started to heat up. At this point, operators would have been trying to find
    some way to get the coolant flowing past the fuel rods again. As the coolant
    heats up, it produces steam which pressurizes the containment of the
    reactor. Hydrogen can also be produced, which is explosive. </p>
    
    <p>At this point, it seems that the operators opened a valve to reduce steam
    pressure in the containment. Oxygen and hydrogen mixed between the
    containment and the reactor building, resulting in an explosion that
    allegedly did not damage the primary containment. Generators and batteries
    have arrived on site and seawater impregnated with Boron (a strong neutron
    absorber, to keep the reactor well-subcritical) is being pumped into the
    containment to help remove the decay heat from the fission products. Some
    fuel may have melted already, so we&rsquo;re hoping that they are able to
    provide reliable cooling to the rest of the core until the heat generation
    decays down to safe levels. </p>
    
    <p>By the way, some later-generation nuclear reactors are capable of doing
    decay heat removal with natural circulation, so no pumps or electricity
    would be needed for this event. This is called passive safety, and is an
    important feature of modern designs. </p>
    
    <p>The best live updates so far are at <a
    href="https://en.wikipedia.org/wiki/Timeline_of_the_Fukushima_nuclear_accidents">Wikipedia
    timeline of Fukushima</a>, with more coverage at <a
    href="http://www.nei.org/Issues-Policy/Safety-Security/Fukushima-Response">The
    NEI</a> and at <a
    href="http://www.world-nuclear.org/information-library/safety-and-security/safety-of-plants/fukushima-accident.aspx">World
    nuclear news</a> as well. </p>
    
    <p>Find a detailed timeline of Fukushima <a
    href="http://www.nei.org/newsandevents/newsreleases/inpo-compiles-timeline-of-fukushima-events-after-japan-earthquake-tsunami">from
    INPO here</a></p>
    
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