@edyong209 tweeted that this was the “Best explanation I’ve read of how nuclear power plants work”
Overall it’s not too bad; I’ve seen worse, and there is some good information. But let’s look at what the reporter got wrong.
A fission reaction is a lot like a table filled with Jenga games, each stack of blocks standing close to another stack. Pull out the right block, and one Jenga stack will fall. As it does, it collapses into the surrounding stacks. As those stacks tumble, they crash into others. Nuclear fission works the same way–one unstable atom breaks apart, throwing off pieces of itself, which crash into nearby atoms and cause those to break apart, too.
I’ll ignore the unquoted part where he treats heat as a substance (a far more ingrained conceptual issue). The atom throwing off pieces of itself is really throwing off two fission fragments, which don’t go very far — they’re highly charged nuclei (the electrons get left behind) and they deposit their kinetic energy in a short distance, which is where most of the energy is deposited, and why the reactor heats up. The parts that cause more fissions are neutrons. They are uncharged, and can travel a greater distance — they don’t have to hit an adjacent nucleus. The Jenga analogy isn’t horrible, but it’s not great, either.
The neutrons don’t cause another fission because they have lots of energy, which is implied by the description. Quite the opposite — a slow moving neutron has a greater chance of interacting with a U-235 nucleus and inducing fission, which is why you put a moderator in the reactor — it’s something the neutrons can hit and lose energy to, but isn’t likely to capture the neutron — you don’t want to lose any more neutrons to non-fission reactions than you have to.
The author continues to imply that the atoms hit each other through the article; I’m not going to call out each instance.
Proximity is also what makes the difference between a nuclear bomb, and the controlled fission reaction in a power plant. In the bomb, the reactions happen—and the energy is released—very quickly. In the power plant, that process is slowed down by control rods. These work like putting a piece of cardboard between two Jenga towers. The first tower falls, but it hits a barrier instead of the next tower. Of all the atoms that could be split, only a few are allowed to actually do it. And, instead of an explosion, you end up with a manageable amount of heat energy, which can be used to boil water.
Control rods aren’t the only difference between a bomb and a reactor. If you somehow managed to pull all the control rods out of the core you’d have a nasty nuclear accident on your hands, but no nuclear explosion.
When a reactor core is shut down, its energy output drops not to zero, but about 6% of its normal output, Forsberg told me. The reactions grind to a halt over the next few days, as the falling Jenga towers run out of other towers they can actually hit. In the meantime, atoms keep breaking apart, releasing both heat and fast-moving particles that can penetrate human skin and damage our cells. Because of this, every nuclear reactor has ways of getting rid of the heat, and blocking those fast-moving radioactive particles.
and at the end
And then what happens? Remember, this is really just an emergency shutdown gone awry. The control rods are still in place. The Jenga columns are still separated. So, over time, the fission reactions will still slow down and stop. As they do, heat levels will drop, and so will levels of radiation.
The author first implies and then explicitly states that fission reactions are the cause of this power output, and it’s not. As I previously explained, this power comes from the decay of fission products. The reactions slow down because the short-lived products decay away quickly (which is why they are called short-lived). Not fission — this fission rate has been reduced by many orders of magnitude, to the point where heating from it is negligible.
Edit: You really should read this.
About 7% of their thermal output should be decay heat, 40-50 megawatts I reckon. That will boil a tonne/minute of water in round numbers. Minimal cooling would be around 6-7 tonnes/minute cold water inflow, with output still near boiling. If they go cold water-hot zirconium Leidenfrost effect, they are so deeply screwed – little heat removal, and fuel element temp skyrockets even under water until zirconum reduces water to hydrogen, turns into zirconium oxide cement, and spews fission products and enriched uranium plus a plutonum garnish everywhere.
http://www.scipub.org/fulltext/ajas/ajas76846-851.pdf
http://darkwing.uoregon.edu/~linke/papers/Walker_leidenfrost_essay.pdf
Really, really bad day.