This post is the final
of three parts on the history of France’s fast breeder Superphenix reactor, now
in the fifteenth year of its decommissioning phase (see Part 1
& Part
2). What follows is a translation of a blog post at GEN4 - Les 4 Vérités du Nucléaire.
This post goes into
some detail about the ongoing problems with decommissioning of this reactor
that had its life cut short in 1998 after numerous technical problems,
dangerous incidents, and political conflict over national energy policy.
The story of the
Superphenix is relevant today because the promise of fast breeder reactors and
the closed fuel cycle is always being reborn, like a mythical, amnesiac Phoenix itself.
Promoters hope the present generation has missed the lessons of all the
dangerous mishaps, wasted national treasure, and ongoing decommissioning
dilemmas related to fast breeder reactors.
The Union of Concerned
Scientists has pointed out that the main flaw with fast breeder technology is
that it makes an unreasonable bet that future generations will be able to
manage the waste products, which are still substantial, regardless of what is
said about the reactors’ ability to “burn them up.” For the UCS, the problem is
that this technology does… “not
satisfy the fundamental ethical principle for the disposal of nuclear waste: intergenerational
equity.”
If a nation one hundred
years from now could not or did not want to maintain its fast breeder reactors,
the promised closed fuel cycle would no longer exist. The country would suddenly
have a massive waste and decommissioning problem to deal with. This could be
horrific enough for a future society ravaged by war, environmental damage or economic
decline, but the story of the Superphenix illustrates that it’s enough of a
nightmare when it happens just a few years after the reactor goes on line, and
the society that manages the decommissioning is the same relatively competent
and prosperous society that built it.
Translation of a blog post at GEN4 - Les 4 Vérités
du Nucléaire,
August 2013
The
fire reported last night in the former Superphenix reactor occurred in heating
ducts meant, according to l’ASN, to recover 5,000 tons of sodium which was used
to cool the core of the fast breeder reactor that was shut down in 1998. You may
wonder what is going on with this damn sodium at Creys-Malville, 15 years
later? Here are some answers.
August
8, 2013, fire breaks out in the facility for recovering sodium.
Last
night around 19:00, the ASN (1) Rhone-Alps division announced that a fire had affected
the installation holding sodium at the site of the decommissioning of the
Superphenix fast breeder reactor (2). The primary circuit of the reactor was
slowed in 1998 after numerous technical and financial problems led to its
closure.
The
fire would have been delicate to handle because sodium fires are particularly
devious, corrosive and toxic, so much so that a specialized sodium fire response
course was created at Cadarache in the 1970s, requiring 250 hours of training
for firefighters.
The
important question: solid or liquid sodium?
We
already discussed this question in relation to a fire at the Monju (Japan) fast
breeder reactor in May 2013. In that case also it was very difficult to have a
precise idea of the gravity of the fire because the information available about
such fires, regardless of the country providing it, is always fragmentary and
incomplete (3).
It
is necessary to keep in mind that sodium, in order to circulate in the pipes,
must be kept heated to its melting point of 100° C. If the sodium solidifies or
gels, it stops circulating (4) and makes it very difficult to restart
circulation. It is impossible to drain the sodium if it is not in a liquid
state, and so it must be constantly heated to its melting point (5).
In
2006, EDF (Electricité de France) (6) announced that the drainage of the sodium
cooling circuit would be complete in 2013 and all risk from it would be
eliminated. Today this doesn’t seem to be the case. The fire seems to have been
limited to a piece of equipment designed to heat and reheat the sodium so that
it can be isolated in small quantities, deactivated and placed in thousands of
concrete blocks (7). However, Le
Monde Diplomatique
reports that the operations are not going well – obviously not, according to
the plan of 2006.
Sodium
still stored in liquid state 15 years after the supposed “shutdown” of the
installation?
In
this article that deserves a more detailed analysis, the journalist points out
notably that sodium is still stored in liquid form in its primary containment
which has a temperature of 180° C. In order deactivate it without causing a
fire, EDF collects it in small amounts (150 kg?). An article appeared in Le Canard enchaîné in August 2011
stating that 5,000 tons of sodium were still being heated at that time. The
article noted the irony that the operation consumes vast quantities of
electricity.
Sodium,
a doubly dangerous metal
Beyond
the non-negligible chemical risks that it presents, the sodium that is stored
now in ad hoc containment is
radioactive after having flowed some eleven years in the primary circuit of the
reactor. Why? Simply because of the same phenomenon of neutron activation that
creates new isotopes and new elements in the presence of nuclear fission. It is
thus that the stable isotope Fe-54 gains a neutron and becomes radioactive
Fe-55. Likewise for Cobalt, Chrome, Silver, Nickel, and Manganese which are
used in various parts which come into contact with the reactor core. Some of
the cooling water used in light water reactors becomes Carbon-14 (8) and
Tritium (H-3) (9).
Radioactive
sodium is formed by the activation of the stable isotope Na-23 + neutron =
Na-24, an isotope which decays quickly (half life: 5 hours) to Mg-24, a stable
element. Thus the radioactivity of sodium is almost completely gone in two or
three days. But it’s not so simple. Actually, during the cooling process, other
elements, highly radioactive ones, are created and mixed into the liquid sodium
(10).
The
fuel, 15 tons of Plutonium-239, still stored in proximity to the sodium hazard
We
must remember that 15 tons of Plutonium-239, placed in the SPX reactor in 1984
are still kept in close proximity to the turbine building where the
“de-sodiumization” process is carried out. Knowing that this quantity of Pu-239
could, in the case of a fire or explosion, spread a billion lethal doses (11),
we can say this is like storing explosives and matches side by side.
Notes:
(1)
Rhône-Alpes
regional office of the French regulatory agency Autorité de Sureté Nucléaire.
(2)
Decommissioning
is an unfortunate neologism. Demolition would have been sufficient, but the
connotations might be critically important.
(3)
Since
the 1950s there have been nine nuclear installations of this type and they have
all had accidents or fires.
(4)
That
is, if the temperature goes below 97° C.
(5)
The
enormous thermal constraints linked to the phase change would break a part of
the sodium circuits.
(6)
As
operator of the site, EDF was found to be responsible for the decommissioning.
(7)
There
are to be 38,000 containers holding 5,500 tons of sodium, so 150 kg of sodium
per container.
(8) O-13 gains
1 neutron to become N-14 (stable) which gains a neutron (cool double effect!) to
become C-14, emitting one proton.
(9)
Lithium-6
+ Neutron => Lithium-7 => Helium-4 + Helium-3 or again by ternary fission
of boric acid used often in reactors.
(10)
The
metal coolant strains the metal circuits and ends up incorporating their active
elements: Fe-56, Co-60...
(11) Lethal dose of
Pu-239: 50 micrograms.
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