[This is a transcription of a YouTube video embedded in the link below]
By Sabine Hossenfelder
October 2, 2021 -- Today I want to talk
about nuclear fusion. I’ve been struggling with this video for some while. This
is because I am really supportive of nuclear fusion, research and development.
However, the potential benefits of current research on nuclear fusion have been
incorrectly communicated for a long time. Scientists are confusing the public
and policy makers in a way that makes their research appear more promising than
it really is. And that’s what we’ll talk about today.
There is a lot to say about nuclear
fusion, but today I want to focus on its most important aspect, how much energy
goes into a fusion reactor, and how much comes out. Scientists quantify this
with the energy gain, that’s the ratio of what comes out over what goes in and
is usually denoted Q. If the energy gain is larger than 1 you create net
energy. The point where Q reaches 1 is called “Break Even”.
The record for energy gain was just
recently broken. You may have seen the headlines. An experiment at the National
Ignition Facility in the United States reported they’d managed to get out
seventy percent of the energy they put in, so a Q of 0.7. The previous record
was 0.67. It was set in nineteen ninety-seven by the Joint European Torus, JET
for short.
The most prominent fusion experiment
that’s currently being built is ITER. You will find plenty of articles
repeating that ITER, when completed, will produce ten times as much energy as
goes in, so a Gain of 10. Here is an example from a 2019 article in the
Guardian by Phillip Ball who writes
“[The Iter project] hopes to conduct its
first experimental runs in 2025, and eventually to produce 500 megawatts (MW)
of power – 10 times as much as is needed to operate it.”
Here is another example from Science
Magazine where you can read “[ITER] is predicted to produce at least 500
megawatts of power from a 50 megawatt input.”
So this looks like we’re close to
actually creating energy from fusion right? No, wrong.
Remember that nuclear fusion is the
process by which the sun creates power. The sun forces nuclei into each other
with the gravitational force created by its huge mass. We can’t do this on
earth so we have to find some other way. The currently most widely used
technology for nuclear fusion is heating the fuel in strong magnetic fields
until it becomes a plasma. The temperature that must be reached is about 150
million Kelvin. The other popular option is shooting at a fuel pellet with
lasers. There are some other methods but they haven’t gotten very far in
research and development.
The confusion which you find in pretty
much all popular science writing about nuclear fusion is that the energy gain
which they quote is that for the energy that goes into the plasma and comes out
of the plasma.
In the technical literature, this
quantity is normally not just called Q but more specifically Q-plasma. This is
not the ratio of the entire energy that comes out of the fusion reactor over
that which goes into the reactor, which we can call Q-total. If you want to
build a power plant, and that’s what we’re after in the end, it’s the Q-total
that matters, not the Q-plasma.
Here’s the problem. Fusion reactors take
a lot of energy to run, and most of that energy never goes into the plasma. If
you keep the plasma confined with a magnetic field in a vacuum, you need to run
giant magnets and cool them and maintain that. And pumping a laser isn’t energy
efficient either. These energies never appear in the energy gain that is
normally quoted.
The Q-plasma also doesn’t take into
account that if you want to operate a power plant, the heat that is created by
the plasma would still have to be converted into electric energy, and that can
only be done with a limited efficiency, optimistically maybe fifty percent. As
a consequence, the Q total is much lower than the Q plasma.
If you didn’t know this, you’re not
alone. I didn’t know this until a few years ago either. How can such a
confusion even happen? I mean, this isn’t rocket science. The total energy that
goes into the reactor is more than the energy that goes into the plasma. And
yet, science writers and journalists constantly get this wrong. They get the
most basic fact wrong on a matter that affects tens of billions of research
funding.
It’s not like we are the first to point
out that this is a problem. I want to read you some words from a 1988 report
from the European Parliament, more specifically from the Committee for
Scientific and Technological Options Assessment. They were tasked with
establishing criteria for the assessment of European fusion research.
In 1988, they already warned explicitly
of this very misunderstanding.
“The use of the term `Break-even’ as
defining the present programme to achieve an energy balance in the
Hydrogen-Deuterium plasma reaction is open to misunderstanding. IN OUR VIEW
'BREAK-EVEN' SHOULD BE USED AS DESCRIPTIVE OF THE STAGE WHEN THERE IS AN ENERGY
BREAKEVEN IN THE SYSTEM AS A WHOLE. IT IS THIS ACHIEVEMENT WHICH WILL OPEN THE
WAY FOR FUSION POWER TO BE USED FOR ELECTRICITY GENERATION.”
They then point out the risk:
“In our view the correct scientific
criterion must dominate the programme from the earliest stages. The danger of
not doing this could be that the entire programme is dedicated to pursuing
performance parameters which are simply not relevant to the eventual goal. The
result of doing this could, in the very worst scenario be the enormous waste of
resources on a program that is simply not scientifically feasible.”
So where are we today? Well, we’re
spending lots of money on increasing Q-plasma instead of increasing the
relevant quantity Q-total. How big is the difference? Let us look at ITER as an
example.
You have seen in the earlier quotes
about ITER that the energy input is normally said to be 50 MegaWatts. But
according to the head of the Electrical Engineering Division of the ITER
Project, Ivone Benfatto, ITER will consume about 440 MegaWatts while it
produces fusion power. That gives us an estimate for the total energy that goes
in.
Though that is misleading already
because 120 of those 440 MegaWatts are consumed whether or not there’s any
plasma in the reactor, so using this number assumes the thing would be running
permanently. But okay, let’s leave this aside.
The plan is that ITER will generate 500
MegaWatts of fusion power in heat. If we assume a 50% efficiency for converting
this heat into electricity, ITER will produce about 250 MegaWatts of electric
power.
That gives us a Q total of about 0.57.
That’s less than a tenth of the normally stated Q plasma of 10. Even
optimistically, ITER will still consume roughly twice the power it generates.
What’s with the earlier claim of a Q of 0.67 for the JET experiment? Same
thing.
If you look at the total energy, JET
consumed more than 700 MegaWatts of electricity to get its sixteen MegaWatts of
fusion power, that’s heat not electric. So if you again assume 50 percent
efficiency in the heat to electricity conversion you get a Q-total of about
0.01 and not the claimed 0.67.
And those recent headlines about the NIF
success? Same thing again. It’s the
Q-plasma that is 0.7. That’s calculated with the energy that the laser delivers
to the plasma. But how much energy do you need to fire the laser? I don’t know
for sure, but NIF is a fairly old facility, so a rough estimate would be 100
times as much. If they’d upgrade their lasers, maybe 10 times as much. Either
way, the Q-total of this experiment is almost certainly well below 0.1.
Of course the people who work on this
know the distinction perfectly well. But I can’t shake the impression they
quite like the confusion between the two Qs. Here is for example a quote from
Holtkamp who at the time was the project construction leader of ITER. He said
in an interview in 2006:
“ITER will be the first fusion reactor
to create more energy than it uses. Scientists measure this in terms of a
simple factor—they call it Q. If ITER meets all the scientific objectives, it
will create 10 times more energy than it is supplied with.”
Here is Nick Walkden from JET in a TED
talk referring to ITER “ITER will produce ten times the power out from fusion
energy than we put into the machine.” and “Now JET holds the record for fusion
power. In 1997 it got 67 percent of the power out that we put in. Not 1 not 10
but still getting close.”
But okay, you may say, no one expects
accuracy in a TED talk. Then listen to ITER Director General Dr. Bigot speaking
to the House of Representatives in April 2016:
[Rep]: I look forward to learning more
about the progress that ITER has made under Doctor Bigot’s leadership to
address previously identified management deficiencies and to establish a more
reliable path forward for the project.
[Bigot]:Okay, so ITER will have
delivered in that full demonstration that we could have okay 500 Megawatt
coming out of the 50 Megawatt we will put in.
What are we to make of all this?
Nuclear fusion power is a worthy
research project. It could have a huge payoff for the future of our
civilization. But we need to be smart about just what research to invest into
because we have limited resources. For this, it is super important that we
focus on the relevant question: Will it output energy into the grid.
There seem to be a lot of people in
fusion research who want you to remain confused about just what the total
energy gain is. I only recently read a new book about nuclear fusion “The Star
Builders” which does the same thing again (review here). Only briefly mentions
the total energy gain, and never gives you a number. This misinformation has to
stop.
If you come across any popular science
article or interview or video that does not clearly spell out what the total
energy gain is, please call them out on it. Thanks for watching, see you next
week.
Posted by Sabine Hossenfelder
http://backreaction.blogspot.com/2021/10/how-close-is-nuclear-fusion-power.html
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