The military coup in Niger has raised concerns about uranium mining in the country by the French group Orano, and the consequences for France's energy independence.
This is just the fact: there are, at the current state, only two energy sources that can form the backbone of a decarbonized grid, and they have proved it, hydro and nuclear.
Hydro is not available everywhere, however, as it has really large area demand, and geological requirements.
And I repeat: nuclear /is/ very capable of load following.
And I repeat: batteries at the needed scalability don’t exist (yet?).
There are lots of ways to solve intermittency. Nuclear is one strategy that potentially works, but still needs short term storage - modern designs can vary load, but not quickly.
3x renewables plus a few hours storage is likely fine. So is a lot of nuclear. Hydrogen or iron-air *might* make the whole thing much cheaper, but indeed are immature technologies. More interconnectors are mature technology that always makes it easier, but are not enough on their own; dynamic demand is helpful and semi-proven.
But building “too much” renewables while we wait for nuclear is fine. Because most likely that nuclear will never be delivered. At least not in the UK. And as I understand it the supply chains don’t really overlap. But above all because *it’s the total carbon emitted that matters*. We’re on a deadline.
I see no obvious reason to expect that the UK can build large amounts of nuclear quickly, even if there was the political will to do so. Successive governments have tried and failed. On recent progress, by 2050, if we’re lucky, we might have 3 more 3GW plants running, which is nowhere near current demand, let alone future demand with electrification.
Even if the government meets its own target of 24GW by 2050, which seems extraordinarily unlikely given the slow progress so far, that will be a lot less than the total peak demand given electrification. So you still need storage.
So I’m not going to campaign to stop building renewables on the basis that one day we *might* build more nuclear.
Having too much renewables is *NOT* a problem, especially when compared to nuclear that will probably never materialise. Worst case, switching off wind and solar farms is much easier than switching off nuclear reactors. Best case, we can export that energy, use it for intermittent energy intensive industrial processes, or store it.
Currently we (UK) always run at least ~3GW of fossil fuels, as well as a surprisingly variable amount of nuclear, because of the inertia problem. That will be solved by 2025.
Britain is up to 36% renewables *on average* over the last year, and still building fairly quickly. Plenty of countries have much higher proportions of renewables. But they also have other ways of dealing with it, e.g. Denmark’s trick was always much more energy trading.
Iceland is 86%, Norway is 76%. It can be done, though these figures are inflated by geothermal and hydro, which may not be viable for the UK. Sweden is 63%, but that includes a fair bit of biofuels. California is already up to 59%.
Intermittency is a problem, there are lots of ways to manage it. Nuclear is one of several options.
The amount of lithium batteries needed to reach 100% is probably ecologically unreasonable, although several academic studies do talk about this. So we probably do need some nuclear, unless iron-air batteries or hydrogen pan out rapidly. Nonetheless, the idea that there’s a ceiling of 40% is way out of date.
There are already single events of more than a few hours where sunshine and wind are lacking. But that is only the immediate perspective; you need to integrate over at least several years to see the longer-term shortages that need to be handled as well. And that is quite obviously much more than a few hours. Therefore, I have some problems regarding such studies as credible.
@Ardubal@MattMastodon@BrianSmith950@Pampa@AlexisFR@Wirrvogel@Sodis Interconnectors make the “long term no wind in winter” scenario much less likely, though obviously this varies depending on the country; there’s less opportunity for it in Australia, but on the other hand it’s just much bigger - “long range” may be within the country.
As I understand it the Australian study was based on real world data.
But let’s say you’re right. After all the study accepted that 2% of the time it’s not sufficient. You have a few options for that last 2%. One is more nuclear - not necessarily 100% nuclear, or even 40% nuclear, but enough to prevent any freak weather events from causing serious harm. Another is hydrogen - an immature technology that is nonetheless 50+ years old.
There was a European study … I think I lost it on X though. That specifically made the case for hours not days. But to achieve that you have to over-build.
Really one of the biggest arguments for nuclear is that over-building renewables makes a minor problem with rare earths into something much more serious.
Most likely we need either some nuclear or some long-term storage. Long term storage means immature but clearly technically feasible technologies: hydrogen or iron-air, maybe a few other candidates. Against that you have the fact that with the exception of France in the 1980s, building large amounts of nuclear power quickly has almost never happened.
Nuclear just takes too long. So use it for what it is - a modest amount of baseload power at roughly twice the cost of renewables.
Let me see if I can find some of the sources … I already posted the study on Australia.
Here’s a Scottish one, they concluded that over-building renewables is feasible. Also arguing for some more hydro. Unfortunately hydro is generally considerably dirtier than nuclear.
Here’s the National Grid’s view; IIRC they are skeptical about the claim of 24GW of nuclear by 2050, but their models say it won’t be enough on its own anyway and bet on hydrogen.
Here are some of the numerous academic-ish sources, probably out of date. As I said, system models often assume there is infinite lithium, so doubtful IMHO.
That has 60% wind and 45% solar, with hours of storage, including some hydro, reaching 98%, using real world data (and scaling the output of existing plant). Going from 105% capacity to 170% eliminates the problem entirely - assuming no freak weather events not included in his ~ 1 year trace. Equally you could solve it with long-term storage. Long-term storage doesn’t have to be cheap or efficient per kWh; it’s the capital cost, the ecological cost (e.g. hydrogen leaks), and whether it’s feasible at all, that’s the real question.
If you don’t have nuclear equal to your *PEAK* demand, which looks unlikely on any reasonable timescale, then either you need quite a bit of storage, or you need to accept there will occasionally be power cuts for non-essential users.
We need to cut carbon emissions *NOW*. That might mean starting some new nuclear power projects. But both renewables and short term storage are being installed today, cheaply, and while there are some obstacles to this (e.g. grid access), balancing is not the main problem.
We can’t use nuclear as an excuse any more than we can carbon capture.
If you don’t have power output from storage equal to *PEAK* demand, it’s the same argument for any storage. And storage doesn’t /produce/ energy, it /consumes/ it (because of conversion losses, which are significant).
You seem to argue that our /current/ fossil grid would also need more storage, but it works just fine as is. Nuclear is better at load following than fossils, so what gives?
It’s not just the UK. Every third gen PWR has taken way longer than expected.
The public rightly insist on the safest designs possible. And those at least have been tried once (generally only once!). However, they take a long time.
Nuclear is faster at load following than everything but pumped hydro and (very dirty) gas peakers. It was even a design requirement for the german Konvoi type in the 70s and 80s.
Ultimately this is determined by how much we can build of each technology by the deadline (which ideally is 2030 or 2035). If we can scale up iron-air fast, that’d be great, but there’s a lot of uncertainty there. But this also applies to nuclear: How much new nuclear we can build by 2035 is probably quite limited. Whether hydrogen can be significant on that timescale, and whether leaks can be managed, is another big question.
It’s worth trying all the plausible technologies (i.e. other than biofuels and fossil+CCS).
PS “volatiles” *already* make up over 30% of the UK’s generated kWh. 😀 So I expect a higher figure.
IMHO the only thing that matters more than the ecological impact of the transition is the *speed* of the transition. Because that determines total carbon emitted. And it determines the carbon intensity of the rest of the transition.
You seem to assume that only one reactor will be built at a time, and nothing learned. But that’s not how you do it, and not how France already did it, obviously.
I have a little problem understanding how one can acknowledge the success of the Messmer plan and at the same time claim it unrepeatable.
Right now, renewables essentially build themselves. They do not require a state subsidy - the “contract for difference” level is set at roughly the wholesale price of electricity.
Whereas no nuclear is ever built without massive state involvement.
Not that that’s bad. We need more state intervention in e.g. insulation. But it’s slow. We can’t afford to stop installing renewables now on the basis of a few reactors that may well be cancelled by a future government.
At least Germany never had subsidies for commercial nuclear power.
On the other hand, »renewables« are still subsidized heavily, and there is much moaning right now because the build-out is slowing down, as the best places are taken.
And France has no /real/ problem with its riverside plants. Last year (much bemoaned) had 0.05% (one twentieth of a percent) curtailing for river temperatures.
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@MattMastodon @matthewtoad43 @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
This is just the fact: there are, at the current state, only two energy sources that can form the backbone of a decarbonized grid, and they have proved it, hydro and nuclear.
Hydro is not available everywhere, however, as it has really large area demand, and geological requirements.
And I repeat: nuclear /is/ very capable of load following.
And I repeat: batteries at the needed scalability don’t exist (yet?).
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis As I already mentioned, California has 2.5GW of batteries today. And credible half hourly models suggest that you only need hours of storage to get up to approximately 98%.
There are lots of ways to solve intermittency. Nuclear is one strategy that potentially works, but still needs short term storage - modern designs can vary load, but not quickly.
3x renewables plus a few hours storage is likely fine. So is a lot of nuclear. Hydrogen or iron-air *might* make the whole thing much cheaper, but indeed are immature technologies. More interconnectors are mature technology that always makes it easier, but are not enough on their own; dynamic demand is helpful and semi-proven.
But building “too much” renewables while we wait for nuclear is fine. Because most likely that nuclear will never be delivered. At least not in the UK. And as I understand it the supply chains don’t really overlap. But above all because *it’s the total carbon emitted that matters*. We’re on a deadline.
I see no obvious reason to expect that the UK can build large amounts of nuclear quickly, even if there was the political will to do so. Successive governments have tried and failed. On recent progress, by 2050, if we’re lucky, we might have 3 more 3GW plants running, which is nowhere near current demand, let alone future demand with electrification.
Even if the government meets its own target of 24GW by 2050, which seems extraordinarily unlikely given the slow progress so far, that will be a lot less than the total peak demand given electrification. So you still need storage.
So I’m not going to campaign to stop building renewables on the basis that one day we *might* build more nuclear.
Having too much renewables is *NOT* a problem, especially when compared to nuclear that will probably never materialise. Worst case, switching off wind and solar farms is much easier than switching off nuclear reactors. Best case, we can export that energy, use it for intermittent energy intensive industrial processes, or store it.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis What you say about “40% volatiles” is a myth.
Currently we (UK) always run at least ~3GW of fossil fuels, as well as a surprisingly variable amount of nuclear, because of the inertia problem. That will be solved by 2025.
https://www.nationalgrideso.com/electricity-explained/how-do-we-balance-grid/what-inertia
Britain is up to 36% renewables *on average* over the last year, and still building fairly quickly. Plenty of countries have much higher proportions of renewables. But they also have other ways of dealing with it, e.g. Denmark’s trick was always much more energy trading.
Iceland is 86%, Norway is 76%. It can be done, though these figures are inflated by geothermal and hydro, which may not be viable for the UK. Sweden is 63%, but that includes a fair bit of biofuels. California is already up to 59%.
Intermittency is a problem, there are lots of ways to manage it. Nuclear is one of several options.
The amount of lithium batteries needed to reach 100% is probably ecologically unreasonable, although several academic studies do talk about this. So we probably do need some nuclear, unless iron-air batteries or hydrogen pan out rapidly. Nonetheless, the idea that there’s a ceiling of 40% is way out of date.
https://www.euronews.com/green/2023/01/20/which-european-countries-use-the-most-renewable-energy
https://www.govtech.com/smart-cities/california-hits-new-record-for-renewable-energy-generation
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
There are already single events of more than a few hours where sunshine and wind are lacking. But that is only the immediate perspective; you need to integrate over at least several years to see the longer-term shortages that need to be handled as well. And that is quite obviously much more than a few hours. Therefore, I have some problems regarding such studies as credible.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis Interconnectors make the “long term no wind in winter” scenario much less likely, though obviously this varies depending on the country; there’s less opportunity for it in Australia, but on the other hand it’s just much bigger - “long range” may be within the country.
As I understand it the Australian study was based on real world data.
But let’s say you’re right. After all the study accepted that 2% of the time it’s not sufficient. You have a few options for that last 2%. One is more nuclear - not necessarily 100% nuclear, or even 40% nuclear, but enough to prevent any freak weather events from causing serious harm. Another is hydrogen - an immature technology that is nonetheless 50+ years old.
There was a European study … I think I lost it on X though. That specifically made the case for hours not days. But to achieve that you have to over-build.
Really one of the biggest arguments for nuclear is that over-building renewables makes a minor problem with rare earths into something much more serious.
Most likely we need either some nuclear or some long-term storage. Long term storage means immature but clearly technically feasible technologies: hydrogen or iron-air, maybe a few other candidates. Against that you have the fact that with the exception of France in the 1980s, building large amounts of nuclear power quickly has almost never happened.
Nuclear just takes too long. So use it for what it is - a modest amount of baseload power at roughly twice the cost of renewables.
Let me see if I can find some of the sources … I already posted the study on Australia.
Here’s a Scottish one, they concluded that over-building renewables is feasible. Also arguing for some more hydro. Unfortunately hydro is generally considerably dirtier than nuclear.
https://scottishscientist.wordpress.com/2015/04/03/scientific-computer-modelling-of-wind-pumped-storage-hydro/
http://re100.scienceontheweb.net/
https://scottishscientist.wordpress.com/2017/07/14/wind-storage-and-back-up-system-designer/
Here’s the National Grid’s view; IIRC they are skeptical about the claim of 24GW of nuclear by 2050, but their models say it won’t be enough on its own anyway and bet on hydrogen.
https://www.nationalgrideso.com/document/263951/download
Here are some of the numerous academic-ish sources, probably out of date. As I said, system models often assume there is infinite lithium, so doubtful IMHO.
https://web.stanford.edu/group/efmh/jacobson/Articles/I/145Country/22-145Countries.pdf
https://twitter.com/AukeHoekstra/status/1557466581185224704
https://www.helsinkitimes.fi/themes/themes/science-and-technology/22012-researchers-agree-the-world-can-reach-a-100-renewable-energy-system-by-or-before-2050.html#.YvPUxCrrWdI.twitter
https://ieeexplore.ieee.org/document/9837910
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis It is well worth reading the original Australian model.
That has 60% wind and 45% solar, with hours of storage, including some hydro, reaching 98%, using real world data (and scaling the output of existing plant). Going from 105% capacity to 170% eliminates the problem entirely - assuming no freak weather events not included in his ~ 1 year trace. Equally you could solve it with long-term storage. Long-term storage doesn’t have to be cheap or efficient per kWh; it’s the capital cost, the ecological cost (e.g. hydrogen leaks), and whether it’s feasible at all, that’s the real question.
https://reneweconomy.com.au/a-near-100-per-cent-renewables-grid-is-well-within-reach-and-with-little-storage/
If you don’t have nuclear equal to your *PEAK* demand, which looks unlikely on any reasonable timescale, then either you need quite a bit of storage, or you need to accept there will occasionally be power cuts for non-essential users.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis But the fundamental thing for me is I won’t wait for new nuclear.
We need to cut carbon emissions *NOW*. That might mean starting some new nuclear power projects. But both renewables and short term storage are being installed today, cheaply, and while there are some obstacles to this (e.g. grid access), balancing is not the main problem.
We can’t use nuclear as an excuse any more than we can carbon capture.
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
If you don’t have power output from storage equal to *PEAK* demand, it’s the same argument for any storage. And storage doesn’t /produce/ energy, it /consumes/ it (because of conversion losses, which are significant).
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis Nuclear does not avoid the need for short-term storage to cover the peaks, unless you can build vast amounts of it (equal to peak).
Nuclear *does* avoid the need for long-term storage, if you can build enough of it (equal to average).
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
You seem to argue that our /current/ fossil grid would also need more storage, but it works just fine as is. Nuclear is better at load following than fossils, so what gives?
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
Ah, but historically, France is not an outlier. Here are the largest 10-year deployments of clean energy sources. The green ones are nuclear.
Nuclear doesn’t take long.
Here is an overview of historic build times.
The task is not fearing we might get a bad case, but creating an environment in which we get a good one.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis That graph includes some huge deployments of wind, and today, it’s a mature, cheap technology (though still improving). Same with solar.
On the timescale on which the historic installs occurred, that was not the case: nuclear and hydro were the only mature options.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis Can you name *one* nuclear project in the last 20 years in Europe that wasn’t severely over-budget and severely delayed?
It’s not just the UK. Every third gen PWR has taken way longer than expected.
The public rightly insist on the safest designs possible. And those at least have been tried once (generally only once!). However, they take a long time.
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
And again, nuclear can load follow /just fine/.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis Sure, 80s French reactors can. As I understand it, modern PWRs can vary load but relatively slowly.
And in any case it is highly unlikely that we will be able to match *peak* demand with nuclear capacity.
You at least need significant intra-day storage.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis I do not understand your diagrams - which curve is the EPR on?
Realistically we’ll have to build more EPRs. There isn’t time to try more designs out.
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
Nuclear is faster at load following than everything but pumped hydro and (very dirty) gas peakers. It was even a design requirement for the german Konvoi type in the 70s and 80s.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis Do you have figures for a modern PWR? Any modern PWR, and specifically EPR1000, since we’re likely stuck with that?
In any case, you still need storage, because you won’t be able to build capacity to peak demand.
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
https://en.wikipedia.org/wiki/Load-following_power_plant#Nuclear_power_plants
For a grid of 100 GW peak demand, you either need
- 100 GW nuclear plants, or
- 100 GW storage output, plus (100 GW × storage loss factor) storage input (volatiles or whatever), plus additional transmission capabilities, or
- a combination of 60% nuclear plus, say 10% hydro, plus 30% volatiles
I’d say some variation on the last looks most plausible to me.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis Well if we’re ruling out long term storage (iron-air batteries and hydrogen), maybe 30-40% nuclear, 80% renewables (intentionally over 100%), and a fair bit of lithium storage?
Ultimately this is determined by how much we can build of each technology by the deadline (which ideally is 2030 or 2035). If we can scale up iron-air fast, that’d be great, but there’s a lot of uncertainty there. But this also applies to nuclear: How much new nuclear we can build by 2035 is probably quite limited. Whether hydrogen can be significant on that timescale, and whether leaks can be managed, is another big question.
It’s worth trying all the plausible technologies (i.e. other than biofuels and fossil+CCS).
PS “volatiles” *already* make up over 30% of the UK’s generated kWh. 😀 So I expect a higher figure.
IMHO the only thing that matters more than the ecological impact of the transition is the *speed* of the transition. Because that determines total carbon emitted. And it determines the carbon intensity of the rest of the transition.
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
You seem to assume that only one reactor will be built at a time, and nothing learned. But that’s not how you do it, and not how France already did it, obviously.
I have a little problem understanding how one can acknowledge the success of the Messmer plan and at the same time claim it unrepeatable.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis Second generation reactor designs that would never be built today. Vulnerable to climate change because they were built on rivers. Also, Britain is not France.
Right now, renewables essentially build themselves. They do not require a state subsidy - the “contract for difference” level is set at roughly the wholesale price of electricity.
Whereas no nuclear is ever built without massive state involvement.
Not that that’s bad. We need more state intervention in e.g. insulation. But it’s slow. We can’t afford to stop installing renewables now on the basis of a few reactors that may well be cancelled by a future government.
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
At least Germany never had subsidies for commercial nuclear power.
On the other hand, »renewables« are still subsidized heavily, and there is much moaning right now because the build-out is slowing down, as the best places are taken.
And France has no /real/ problem with its riverside plants. Last year (much bemoaned) had 0.05% (one twentieth of a percent) curtailing for river temperatures.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis Farm scale solar, onshore and offshore (non-floating) wind cost approximately £50 per MWh in the last CfD auction. That’s half the CFD agreed for Hinkley C.
Mature renewables are already cheaper than nuclear. By a factor of two, compared to first-of-a-kind over-budget new nuclear.
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
Again, £50 per MWh is at current penetration levels of volatiles. This doesn’t scale linearly.
See that you get to more-of-the-same-kind nuclear reactors. This does.
@Ardubal @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis What do you mean it doesn’t scale linearly?
If you need to over-build by 3x, then it costs £150/MWh.
If you need to use £170/MWh storage for 10% of demand (plausible for hydrogen), you still get a very reasonable figure.
There’s no obvious non-linearity here. Switching off renewables is trivial, unlike thermal plant.
@matthewtoad43 @MattMastodon @BrianSmith950 @Pampa @AlexisFR @Wirrvogel @Sodis
Anyway, I don’t want anyone to stop building renewables, but I don’t want anyone to stop building nuclear either. We need every option.
(Even if nuclear is a safer bet.)
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