I too am happy about advances in nuclear energy research, and would like to make a remark regarding its suitability for fighting the climate crisis.
In 2019, just 4 % of the global primary energy came from nuclear power (the figure is about 10 % if we restrict to electricity). Hence replacing fossil sources by nuclear would entail large-scale construction of new nuclear reactors. By the time we're done building these, we will already have exceeded our CO₂ budget for keeping below 1.5 °C at a reasonable certainty.
Also, at the current rate, the Uranium reserves last for approximately 140 years; if all fossil sources were switched for nuclear, it would last for 10 years. This problem can in principle be alleviated by innovative reactor types, but realistically they won't be available for large-scale production in the next couple years.
Luckily, we do have all the technology for phasing out fossil energy while staying within our CO₂ budget: water, wind, solar, storage of synthetic gas, gas-fueled power plants (fueled by synthetic gas obtained using renewable energy). Energy production with these alternatives is cheaper than with nuclear; this fact is an additional issue for expanding nuclear power -- it's not economically viable.
> Also, at the current rate, the Uranium reserves last for approximately 140 years; if all fossil sources were switched for nuclear, it would last for 10 years. This problem can in principle be alleviated by innovative reactor types, but realistically they won't be available for large-scale production in the next couple years.
You either have to use seawater uranium or use breeder reactors of any fuel cycle. If you use both, uranium will last on the order of how long the nuclear fusion fuel of the sun will last (i.e. billions of years).
Most importantly, you don't need to only build breeder reactors right now. The "won't be ready in 10 years, forgetaboutit" argument doesn't really stand, especially as we look to powering direct carbon capture tech alongside decarbonizing a growing world.
National nuclear energy programs have always and will always consider a transition to breeder reactors essential for any meaningful long-term energy source. This has been the known plan since the mid-1940s.
Fun fact (pointed out to me by user pfdietz): If you dig up any average rock on earth, it has more energy in nuclear fuel (uranium and thorium) than a piece of pure coal of the same mass. WOW!
> Also, at the current rate, the Uranium reserves last for approximately 140 years; if all fossil sources were switched for nuclear, it would last for 10 years.
This is a so well known misconception that it is hard to not consider it propaganda by this point.
Known reservers of Uranium are of that size, yes. That's because with nobody bothers to look for more, because not only is there enough known for now, but finding more would actually increase competition and lower the prices - losing those who own the reserves the money.
There is way more Uranium just in the ocean water.
Meanwhile, all the technologies you're listing are either already maxed out (hydro), intermittent with unsolved storage (solar and wind), or vapourware (power to gas, etc).
The 140 years number is also for the very inefficient reactors that are mostly used now, where majority of the "spent" fuel could be reused in different design - but reprocessing is dead for political reasons.
> This is a so well known misconception that it is hard to not consider it propaganda by this point.
Wikipedia paints a different picture but I consider that a fair point and I will look into it, thank you.
> intermittent with unsolved storage (solar and wind)
Can you be more specific about that? I know the figures only for Germany. Here, solar and wind match up almost perfectly (solar excees in the summer, wind excess in the winter) -- we would only need to store energy reserves for about two weeks. Gas tanks capable of storing these amounts already exist, they have been built several decades ago.
> or vapourware (power to gas, etc)
This is the first time that I hear power to gas described as vapourware. I'm very interested in that topic, could you give some more details or pointers?
> This is the first time that I hear power to gas described as vapourware. I'm very interested in that topic, could you give some more details or pointers?
Surely the onus is on whoever is claiming the technology does exist to provide some details of it.
I checked Wikipedia though [0] and the world's total installed P2G capacity looks like...less than 100 MW? It's at best one step above vapourware.
I don’t think they were saying that just the resources to build the reactors would exceed that CO2 budget, but rather that the world would exceed that CO2 budget in the time it takes to build the reactors.
Would be interesting to estimate and compare nuclear vs alternative "initial co2 efficiency per 1 megawatt priduced", considering large lifespan and power of reactor.
The thrust of it is nuclear power takes long enough to build that if we try to meet the 1.5C goal using principally nuclear power by the time the plants come online we will have put enough carbon into the air from the existing power sources that we'll blow past 1.5C and get into the 'absolutely catastrophic sea level rise' territory instead of just causing whole island nations to disappear and the largest displacement in human history we're currently aiming for.
I think it amounts to "this only solves half the problem, so we shouldn't do it".
Most big problems aren't solved by just doing one thing. When global warming is finally solved, it will have been by 10 separate things that each solved 5-20% of the problem.
Also, imposing an arbitrary deadline in 2029 is horrible project management. In a commercial project it's also dumb, but at least there you can cancel the project, and people move on to do other things.
For Earth, we can't cancel the planet in 2029 if targets weren't met.
If we decided today to do large-scale deployment of new nuclear reactors, then we would see reductions in CO₂ emissions from the energy sector only in ten to twenty years.
But at our current rate, the global CO₂ budget will be fully exhausted in about eight years.
Hence we need to seize other measures, measures which reduce our emissions on a shorter timescale: switching to wind+solar+storage and in the process democratizing energy production, rethinking mobility (massive expansion of public transport, massive price reduction of public transport, massive investion in biking infrastructure, making outer city districts more attractive), putting a prize on CO₂ with a substantial steering effect (but ensuring that the proceeds of such a tax are given, in equal parts, to the population, so that people who contribute less-than-average to the climate crisis have more money available at the end of the day), transforming the system (because even with a prize for CO₂, there are lots of valuable things which cannot be measured in dollars, and competition pressure in unchecked capitalism deepens inequality and exploitation), ...
But at our current rate, the global CO₂ budget will be fully exhausted in about eight years.
We don't actually know that. It's a model projection. Academic models have a long history of being wrong and seemingly always in the direction of being too pessimistic, across a variety of fields.
Do we need to transition away from fossil fuels? Sure. Are the models so robust and so beyond question that nuclear should be ruled out on the basis of a handful of years of construction time? No way. The science is nowhere near solid enough for that.
> If we decided today to do large-scale deployment of new nuclear reactors, then we would see reductions in CO₂ emissions from the energy sector only in ten to twenty years.
Nobody serious is suggesting we do nothing but deploy nuclear reactors. Just in the energy sector, we should do a massive build-out of wind, solar, transmission, and, yes, nuclear.
> switching to wind+solar+storage and in the process democratizing energy production
These have large economies of scale too. While you might want to install a small propeller in your back yard, it's much more cost effective to get the energy from the grid supplied by a large scale wind farm.
> rethinking mobility (massive expansion of public transport, massive price reduction of public transport, massive investion in biking infrastructure, making outer city districts more attractive), putting a prize on CO₂ with a substantial steering effect (but ensuring that the proceeds of such a tax are given, in equal parts, to the population, so that people who contribute less-than-average to the climate crisis have more money available at the end of the day), transforming the system (because even with a prize for CO₂, there are lots of valuable things which cannot be measured in dollars, and competition pressure in unchecked capitalism deepens inequality and exploitation), ...
These may all be good ideas (and personally, I would certainly agree with some of those), but has nothing to do with whether the needed energy is produced by renewables, nuclear, or mass deployment of hamster wheels.
Could you provide some sources? Embodied CO2 & energy is certainly a huge problem, but it seems likely to affect solar & wind as well. Could we really build enough solar and wind at today's level of technology (assuming sufficient economic motivation) without also blowing through our CO2 budget?
At this point, it seems likely to me that we are doomed to at least a 1.5°C global temperature rise.
> Could we really build enough solar and wind at today's level of technology (assuming sufficient economic motivation) without also blowing through our CO2 budget?
A back of the envelope calculation suggests that the necessary construction efforts require the emission of a couple of Gt CO2e. For comparison, at the start of 2018 our CO2 budget was 420 Gt (now it's about 320 Gt).
In 2019, just 4 % of the global primary energy came from nuclear power (the figure is about 10 % if we restrict to electricity). Hence replacing fossil sources by nuclear would entail large-scale construction of new nuclear reactors. By the time we're done building these, we will already have exceeded our CO₂ budget for keeping below 1.5 °C at a reasonable certainty.
Also, at the current rate, the Uranium reserves last for approximately 140 years; if all fossil sources were switched for nuclear, it would last for 10 years. This problem can in principle be alleviated by innovative reactor types, but realistically they won't be available for large-scale production in the next couple years.
Luckily, we do have all the technology for phasing out fossil energy while staying within our CO₂ budget: water, wind, solar, storage of synthetic gas, gas-fueled power plants (fueled by synthetic gas obtained using renewable energy). Energy production with these alternatives is cheaper than with nuclear; this fact is an additional issue for expanding nuclear power -- it's not economically viable.