I think this is problem with nuclear power...
You can never get a new project started without a public outcry.
So instead of new, safe, carbon neutral nuclear power (like thorium reactors, passive cooling, etc), we're are continuing to running literal old-timer nuclear plants (Diablo Canyon was built in 1981).
Most folks would not drive a car from 80s, but somehow we're cool with running powerplants that old.
IMHO The best for our carbon footprint with safety would be new nuclear plants.
The problem with nuclear is not the public outcry against it. That did not stop our attempts at Vogtle or Summer in the 2000s.
What stopped these new nuclear builds, and doomed future new nuclear builds, was fraud on the part of management, unconstructable designs, incompetence in EPC, etc. these are the challenges with nuclear.
If somebody could build cost effective nuclear that didn't bankrupt those building it, there are roughly 100 reactors in the US nearing their end of life that local populations would love to keep running.
Nuclear didn't die because of public outcry in the US, it died because of cost overruns and bankrupting utilities. No buyer wants to take on that risk.
Nuclear didn't make it because coal was to cheap. People now are willing to pay more for solar/wind and so on, and government is willing to help pay for it. This wasn't the case for Nuclear in the 70/80s.
Combine that with the complete rewrite of regulation and the whole governmental structure in regards to nuclear, making them much tougher to build, killing much of the research, limited political support from either side and so on and so on.
They had to essentially rebuild plants according to newer standards stopping all new construction. While some of those changes were worthy, its also objectively true that coal plants were not subjected to nearly as much additional regulation despite them being much less save both for the workers and for the population around.
So if you have one standard of safety applied to one thing, and a completely different standard to another thing, then of course nuclear can't win in a market situation.
Large scale nuclear is successful if you can do it at scale. But that needs a top down approach or at least government approval and support.
Had nuclear received the kind of support wind/solar had in the last 20 years, the US would have transition to nuclear at a rate comparable to the adoption of oil.
Now it does. Not 20-30 years ago. And then building more gas would have been cheaper, specially in the early 2000s.
The government has used many mechanism to push those things, not sure how that's questionable. Including to force Utilities to adopt renewable energy (even those that already had carbon free nuclear). Other laws that prevent pricing on intermittence. Support and tax-breaks for rooftop solar. And lots of other policies.
Exactly like the huge subsidies nuclear power have had for the past 70 years?
The difference is for renewables the cost savings panned out, while nuclear has only gotten more expensive.
Renewables are cheaper than fossil fuels, that is why we see mass adoption. Stop crying over spilled milk because nuclear never materialized, embrace the technology that are forcing true change.
Nuclear was getting massively cheaper and was scaling well and fast. Then a huge amount of extra regulation came killed all forward progress in the industry, a new regulator was essentially anti nuclear and the utilities understood that the political wind had massively turned against nuclear. All vital research projects for next generation plants were killed.
At the same time cheap coal was discovered and changed the economics and utilities had little intensive to adopt nuclear.
In France where a top down nuclear approach was adopted, it has been an absolutely amazing deal. Far, far cheaper green energy then German 30+ year journey adopting renewables (and they aren't close).
> embrace the technology that are forcing true change.
Nuclear actually made true chance 40 years ago. It just some countries that took advantage of it and some countries that burned a lot of coal that cost them much, much, much more.
Renewables are cheaper if you only compare cost of generation. The issue is they need storage. Add in that cost and the price becomes super murky, and depends heavily on geography; access to good clean water (electrolysis), viable valleys to dam (hydro) etc.
The parent poster’s got a valid point, though. Solar PV and wind used to be expensive but have seen massive cost declines that seem set to continue. Battery storage is currently expensive but is also following a similar pattern of cost declines as the industry ramps up mass production. The current state of the art in large nuclear plants can’t be mass produced, and so we haven’t seen any durable price declines at all. I suppose it’s possible that over the next 20 years we’ll hit some kind of technological wall in grid storage tech that prevents further price declines, but that seems like an incredibly low-odds bet to make.
> The current state of the art in large nuclear plants can’t be mass produced
That just false.
> any durable price declines at all.
If we stopped building wind turbines for decades the price declines wouldn't be durable either.
The simply reality is that when nuclear was built at scale, even with current PWR the prices are pretty damn good. India cost in their heavy water reactors are really good. South Koreas reactor prices in UEA are incredibly reasonable.
I actually did a bunch of calculations on this. Starting in around 2000, what if Germany had gone nuclear instead of solar/wind/storage and so on. I took very pessimistic price assumptions for the nuclear plants based on the South Korean reactors in UAE. And I assumed a scaling rate far lower then what France did in the 70/80s.
And even then the price for a complete transition of the whole grid to 95%+ nuclear was both cheaper and faster then what Germany actually achieved. And that would have come at a cost that amounts to about 4-5% of extra debt per GDP with resulting low electricity prices.
Germany as society is paying, far, far more then that. Just their recent emergency measures to subsidize prices are about as much as a whole nuclear fleet. Germany had decades of high energy prices that one had to account for and then they had a huge investment in wind and solar. Plus costly deals with Russia both politically and in cost terms.
Frankly, there is simply no evidence that Germany did better by Solar/Wind/Coal/Gas route then if they had done nuclear. And that is before we are even considering that without storage the system Germany building is very brittle and its not at all clear when they will actually achieve consistent 95%+ green energy.
Not if you build out enough storage to account for intermittency. 12 hours of storage just for diurnal fluctuations, then there's seasonable fluctuations in output due to weather that can last for weeks or more.
Moving demand is far easier said than done. A lot of people erroneously assume that the rest of the grid is like a house where you can install a power all and schedule your dryer to run during the day. But the power grid is running a whole bunch of utilities and industrial systems like the pumps running your sewage, traffic lights, telecoms, etc.
From what I understand, power is cheap at night because they can't turn off the power plants easily, and the daytime load is always higher than night.
But although some things are used all the time, other things like charging your electric car or heating a tank water heater can be moved around, and people don't mind doing it if they save money.
Even if this were true (and I have my doubts), nobody has a proposal for a different regulatory scheme that would lower costs. France has seen similarly high costs with an entirely different regulatory scheme, for example.
"Regulations" are the excuse of people that didn't do their homework or prepare for the serious work of large construction projects. All of which have huge overruns in the US, regulations or not.
In truth, it's a labor and productivity problem. Advanced economies have far more productive uses for workers than sitting around construction sites, waiting for something to arrive so that they can finally do a small amount of work before waiting some more.
> In truth, it's a labor and productivity problem.
Yes, and the gigantism of the projects does not help. Here's an example [1]. Last week they mounted the reactor dome at Hinkley. Here's a quote:
> Using one of the world's largest cranes, known as Big Carl, the dome - with a diameter of almost 47 metres, height of 14 metres and weighing 245 tonnes - was lifted and then slowly lowered onto the 44-metre-high reactor building.
SMRs would address that. Every single thing about gigawatt scale reactors is extremely expensive. If you reduce the scale of the reactor by a factor of 10, then you won't need "Big Carl", you would not need a 245 ton dome, you wouldn't need containment vessels that can only be build by a handful of forges in the world [2] (none in the US).
You are absolutely right, this has nothing to do with the NRC. They have a job to do, and in a world where Fukushima can happen, you can't be too careful.
But can SMRs reduce construction costs? The anti-nuclear crowd is dancing in the streets for the failure of NuScale to keep the Utah project alive. But NuScale is a player with zero experience. There are numerous other players [3] that actually build reactors. For example one is BWXT, a company that makes nuclear reactors for the US Navy.
"SMR" has been tried time and time again by both established players and startups since the 50s. It is what the industry tend to swing to when large scale designs once again prove too expensive. They've never panned out.
> The Forgotten History of Small Nuclear Reactors
> Economics killed small nuclear power plants in the past—and probably will keep doing so
I read that article, and it's not that convincing. The article goes over some attempts made in the '50s and '60s. And that's it, the conclusion is SMRs can't work now. It completely ignores that naval nuclear reactors are nothing else but SMRs and they work just fine, and are not expensive compared to civilian reactors.
Of course, the article was published in 2015, so it could not predict that China would build and put in operation two fourth generation SMRs in 2023[1]. And that they would state they intend to build 6 more that would drive a single 650 MW turbine.
Naval nuclear reactors have the world's least price sensitive customers, run on highly enriched uranium, scuttling the vessel is deemed a safe outcome and military staffing is completely different from civilian.
That does not match reality on land.
China is barely building nuclear anymore. China added more wind and solar the past nine months than all of its nuclear reactors under construction will provide. Yes, that includes capacity factor.
You also do the common misstake of always talking about future nuclear plans. They will be the savior, as long as the costs are marketing material and not real. Because we can't look at the existing batch of botched nuclear construction the past 20 years in the west, that would spoil the rosy image.
Better trust our future to Powerpoint reactors. Rather than competitors delivering day in and day out.
They’ve also built way more coal plants and nuclear plants than anyone else. What’s your point? China is a massive country with massive electricity needs (they still use half per capita that the west does and they’re trying to close that gap).
Nuclear and coal is the plan for baseload because solar/wind doesn’t cut it for that use (coal I believe is intended to be a mechanism of last resort intended to never be run as long as other alternatives are available although I suspect reality will not be so kind).
That's a funny way to look at things. China built 40 GW worth of nuclear power plants in the last decade [1], which matches the best decade of France, and almost matches the best decade of the US. In 2022 they started work on 5 reactors (GW-sized), 2 more than the rest of the world combined.
> Naval nuclear reactors have the world's least price sensitive customers, run on highly enriched uranium, scuttling the vessel is deemed a safe outcome and military staffing is completely different from civilian. That does not match reality on land.
Congress is, in fact, very price sensitive about military procurement, and there are significantly greater engineering challenges in ship construction than in terrestrial construction. The difference is that the scale and regulatory environment around building naval ships is not completely dysfunctional.
The problem is both (and more) are true. Public outcry is a significant effect. Cost is a significant effect. Over regulation is a significant effect.
Worse, these are coupled. The result is often that people say x -> y! And stop there. But it's not an acrylic graph so narrow views don't work and simply trap us in this circular argument we've had for 40 years now (not unique to nuclear either). Truth is public outcry influences regulation which influences cost which influences outcry and so on and on. There is no root to point to as the start and there are arguments you can make about any of these being the start because influence doesn't mean sole contributing factor. As an example, you can argue cost is related to regulation and even that lack of innovation have been "caused" by public outcry (or claim regulatory costs/lack of innovation are confounders). Certainly it is a causal variable, but multiple causal variables can contribute to something. Truth is there are unique costs to nuclear independent of regulatory concerns. There's a reason you'll find far more physicists actively managing a nuclear power plant than a wind farm. There's also different dangers and uniquely there are proliferation concerns which do impose unique regulation. Can all this be better optimized? Certainly! But we can never do that if we are just going to endlessly have these circular arguments.
I know the weeds and details often don't matter for many subject matters (actually I think this is naive) but can we at least admit that nuclear power is at least a little bit complicated? And that there's a unique history? And that any opinion that is not formed through years of schooling and experience in the field is de facto naive? No matter how many youtube videos or articles you read from science communicators and even if you have a degree in physics because there's more to the problem that simply nuclear physics?
Most importantly, can we also admit that it's perfectly okay to have naive opinions? Literally nothing wrong with them unless high confidence is placed in those opinions. We're all smart people here, right?[0] So we recognize that the modern world is built via specialization and no person can really be an expert in all things, and realistically only in a few? Fuck man, I think one of the great filters is when a species gets to the point where approximate/naive solutions are no longer effective and they just fucking kill themselves because evolutionary pressure makes these solutions incredibly effective in the beginning but makes those same species ill equipped once a certain level of complexity is reached. I just wonder if we're intelligent enough to overcome these limitations in more than narrow settings (sure, you're smart in x, but are you okay being dumb at y?). Certainly the capacity exists.
[0] If we all know what you're (ambiguous) going to comment in response to this line, are you proving you're "better" or demonstrating your lack of intelligence? Please, just don't. Respond to something more substantial.
Do you have any specific criticisms of its safety? Age doesn't make something unreliable or unsafe. If you had a Nokia phone in the 80s, I'll bet that thing is more reliable than any phone produced in the last decade.
I'm all for more nuclear power displacing natural gas and coal and worse things until we can find a way to deploy renewable energy faster. Nuclear is near-zero carbon, it's just not renewable, but that's less of a problem in the short term.
What I don't like is that Diablo Canyon is built on the shoreline, which is ripe for another Fukushima-like disaster in the event of a tsunami that hits California.
Even if that cliff edge is high it may destabilize with a high enough wave.
For reference, the nuclear plants Germany shut down, were all built in the 1980s as well, although some of them in 1989 with construction started in '82 or the 70s. People still complain, that those got shut down, but really the problem was rather that no new ones were built in the last 40 years, especially considering what we learned in that time.
Renewables are simply much easier to build. They mostly affect people that can see them and especially solar can be built in a lot of places, that don't really bother people, unless they don't like how they look (like a roof or to shade parking spots). Wind is a bit more difficult, but apart from the shadow and in closer distances the noise, the look isn't actually that bad. Kids tend to get about as excited about them as when they see a fire or dump truck. It is mostly that we prefer to look at peoples cars and streets than a spinning wheel on a wind turbine.
That's probably the big benefit renewables have. They have relatively few downsides to people and failure modes are mostly predictable as well (electrical faults or falling over would probably be the worst case and feel much easier to run away from, when you try to imagine them). So there shouldn't be as much resistance against them, apart from people living directly next to them even when people are unreasonable.
If a 100% electrical grid with renewables is possible (and I think it is), I think it is simply the better option, because it really shouldn't bother anyone (and probably also is cheaper and quicker to build). But maybe I am overestimating how much people care about looks or the coolness factor of nuclear.
Given the renewable option, I don't think CA should be building new nuclear plants. The state has plenty of sun, year-round, and plenty of open, undeveloped space to build PV fields with battery storage.
I think it's perfectly fine (and smart) to keep Diablo Canyon running longer. $6B over five years doesn't seem crazy at all for a plant rated for 2.2GW. And shutting it down when our generation mix still heavily relies on burning natural gas would be a step backward.
But renewables are here now, today, and are cost-effective, much more so than building new nuclear plants, which are huge capital undertakings, that take many years to build, and the disposal of nuclear waste is still fraught with political and NIMBY issues.
I think you are incorrect to suggest that building new nuclear plants (even the new safest, cleanest designs) is the best bet for our carbon footprint. It seems pretty clear to me -- at least in a place like California -- that solar is miles ahead the better choice.
> Most folks would not drive a car from 80s, but somehow we're cool with running powerplants that old.
C'mon, that's just disingenuous. You can't just throw out a random machine and try to compare it apples-to-apples with a nuclear power plant.
Are you opposed to all reactor designs? Because MSRs generate way less waste than even existing designs, don’t need a turbine/water cooling, and can’t melt down.
> the cost to maintain the plant an additional five years could reach $6 billion.
This does not appear to be a serious attempt to help the environment with carbon-free electricity.
It looks more to be a PR move to satisfy people who have been boosting nuclear, without regard to costs.
$6B for a mere five years is highway robbery. Installing $4B of solar and $2B of batteries will result in 20-40 years of carbon-free electricity, and far far far more of it.
Those who have been boosting nuclear without a hard nosed look at the costs of technologies have a lot to answer for here. This is just a PR game.
The average price of electricity in California is 27 cents/kWh, or $270/MWh [1]. Some of this go to middlemen, but some to producers. I don't know the split, but let's say it's half and half.
Diablo produces about 16000 GWh of electricity per year [2]. At $135 per MWh it comes to $2.2 BN/year, or $11 BN for 5 years.
For reference, my PG&E bill splits out transmission/delivery and generation very conveniently, since SF provides its own power generation utility service. It appears to be closer to 60/40. At PG&E generation rates (a little higher), perhaps up to 55/45.
Incidentally, $0.13748/kWh in generation costs, with an increase of only $0.01/kWh for exclusive wind/solar sourcing.
That generation cost is also far far higher than the cost of new solar. New floating offshore wind, a new technology that is "expensive," is about at that generation cost.
Even the $6B here amounts to roughly $0.08/kWh, which is far higher than the alternative uses of the money.
Electricity is expensive in California not because we use renewables, but because we have not switched to them, and because PG&E has astronomical costs for its grid. We need CPUC to start pushing back harder here.
That must be an average including lots of old, expensive installations.
Even five years ago, PG&E estimated for new solar was less than $0.06/kWh, and they tend to overestimate these things, and underestimate the rate of cost decreases with solar.
In evaluating the difference between maintaining an existing nuclear site, or building new solar, the new cost is the more accurate estimate.
If you look at new solar deployments in California, nearly all include storage, because it increases profitability to be able to deliver during the evening. Storage is profitable today, meaning that it necessarily costs less than market rates.
Yeah people keep claiming that solar is cheaper in these threads but when asked for proof they point solely at panel prices like that’s anything. The data I’ve been about to find puts hydro, fossil fuels, nuclear, and wind on par with each other with solar about ~2-3x the production cost (not including batteries) if I recall correctly.
You can move to Texas and sign up for retail rates from one of their lesser regulated providers, and when the temperatures drop and your energy markets spike in value you too can pay market rates to heat your home.
In fairness, there are many other states with lower generation prices than CA and that don’t have weird grid failures like TX. Those two states both seem nuts to me, especially given how many natural energy resources they’ve been gifted with.
In fairness I was answering the question of where you can get market rates. Very little of TX's grid failures in February 2021 directly affected the infrastructure to the homes, many Texas providers cut power because they could not afford the wholesale rates while offering the customers a protected monthly rate. There was a very good chance that if your provider was one of the TX providers that allowed you access to Texas's energy market, you maintained power during the freeze and paid massively for that.
PG&E's generation rates are listed as though PG&E is paying that amount on average. So I don't think this is a spot-vs-guaranteed price issue -- I think it's more like wholesale vs retail.
California doesn't have an energy market like Texas. Correct me if I'm wrong but if the price of energy spikes during a billing cycle you don't pay any extra that month as a residential customer, PG&E has to change the rates later.
>. Installing $4B of solar and $2B of batteries will result in 20-40 years of carbon-free electricity, and far far far more of it.
Beginning when? Diablo Canyon is already on line today, and just as importantly, tonight.
Where is the land going to come from to support $4B of solar panels? How many times will those batteries need to be replaced over 20-40 years? What are the ongoing maintenance costs? How will all that solar be connected to the grid?
Alleging "PR move" and "PR game" without similarly considering the motivation for your comments weakens your position.
> The land area required to supply 100% of projected U.S. electricity demand in 2050 with PV installations is roughly half the area of cropland currently devoted to growing corn for ethanol production, an important consideration given the neutral or negative energy payback of corn ethanol and other complications associated with this fuel source. That same land area - i.e., 33,000 km2 to supply 100% of U.S. electricity demand with PV -is less than the land area occupied by major roads. The currently existing rooftop area within the United States provides enough surface area to supply roughly 60% of the nation’s projected 2050 electricity needs with PV...
You could power California off a solar field roughly the size of Andrews Air Force Base.
Some things that are easy in theory are not as easy in practice.
In theory it's so easy to build lots of huge solar power plants. We all know that solar is dirt cheap, because we've all seen the Lazard report with the levelized costs of energy.
In practice, here's the list of solar power stations in California [1]. None is close to 1 GW. Only 3 are above half a gigawatt nameplate capacity. But their capacity factor is on average less than 30%.
Or to put it differently, 20% of the electricity generated in California comes from solar, and 9% from nuclear (i.e. from Diablo). If you want to replace nuclear with solar, you need to increase the current solar generation by 50%. That's doable, but it's not something you do overnight, it will very likely take a few years. Meanwhile, guess what you'd use to replace Diablo? Of course, it would be natural gas, which, by the way, accounts for 47% of the current generation.
We've heard the story of nuclear being replaced with renewable in my state, New York. Two reactors, with a combined capacity of 2.1 GW were shut down in 2020 and 2021. But instead of renewables, they were replaced with natural gas [2].
> As a result of the permanent shutdown of the plant, three new natural-gas fired power plants: Bayonne Energy Center, CPV Valley Energy Center, and Cricket Valley Energy Center were built, with a total capacity of 1.8 GW, replacing 90% of the 2.0 GW of carbon-free electricity previously generated by the plant.[6] As a consequence, New York is expected to struggle to meet its climate goals
The solar doesn't need to be in one large install, and that would actually be a very bad idea. Big central points of failure are less reliable than widely spread resources. So I'm not sure what the point is of saying the biggest single site is X MW.
And if the idea is that "oh no we are going to see an emissions spike when DC shuts down" that's going to happen anytime before 2035, while there's still gas on the generation network. If it happens now or in five years is less important than the total emissions over time. If we bit that bullet in five years, but didn't spend the $6B on more permanent solutions that bring us to our long term transition, it's money wasted.
Sure, but I think the GP's point is that this doesn't just happen overnight. Let's say the same people who planned out keeping this nuclear plant open another 5 years today said "ok, let's plan out a same-price solar build and get it started".
How long would you expect the planning process to go, buying up the land, permitting, the construction process, connecting it to the grid, testing, and then finally energizing it? A couple years? More? (Also remember that this is California, where people will put up stupid roadblocks even for construction out in the desert, away from anyone's home.)
Now, they absolutely should be doing that in parallel! It's dumb that they aren't. But this nuclear plant is running today, and will continue to provide much-needed electricity, and that'd still be needed if we got this (unfortunately only hypothetical) solar project going right now.
Keep in mind you need to multiply those power numbers by capacity factor. Solar in California is at ~29% capacity factor (much higher than I expected honestly), while nuclear is generally around 92%.
That is, Diablo Canyon actually puts out 2,070MW of power from it's nameplate 2,250MW. While 4,779MW of PV in California will generate 1,385MW of power.
So, they really only added half of a Diablo Canyons worth of capacity last year. (Still an impressive amount of power, but not as much as it seems).
It seems that people do not understand that capacity factor is the #1 criteria when building an electricity grid.
Electricity grids do not have the luxury of being able to shut down, they must meet the demand every day of the year, every minute of the year
Technologies with an higher capacity factor are inherently more valuable than the ones who don't and technologies with an unpredictable capacity factor are worth even less than those two.
There are lots of gas generators with super low capacity factors, but the capacity factor is not the key part of the generator, it's dispatachability, the ability to generate when asked to by the grid.
Neither nuclear nor coal are very dispatchable, as they can not respond to changes in demand in cost effective ways. Gas turbines can easily, as can batteries. While the sun is shining, solar can be dispatchable, because it's easy to shut off on demand or turn on demand. But for 60%-75% of the day, solar is not dispatchable.
In the modern grid, dispatchability is a far more useful attribute than capacity factor. Capacity factor is just an incidental.
In today's world ran by fossil fuels, there's not a need to turn off the non fossil fuel production, there's always more parts of the economy willing to get cheap electricity.
What matters then is the reliability and this is why the capacity factor and especially its variation are critical. See what happened in the EU when the russian gas turned off.
Batteries are a low scale solution at best at the moment anyways and aren't working at the scale of a grid.
More importantly, Nuclear generates the base load capacity that renewables struggle with - the 27,000 MW is great, but its use it or lose it, as we dont have anywhere near the capacity in place to store the excess - nor will I think we will build it in anything resembling a timely manner.
If that's the reasoning, it's just a variant of the sunk cost fallacy.
The question is what is the most effective use of our limited resources right now. Diablo Canyon will be shut off at some point, causing a momentary blip in emissions rising. Is $6B on a short extension a good use of our resources? It's certainly difficult to see much benefit.
Instead, the benefit is mostly to assert that we still are open to using nuclear. Which, fine, is a good goal, but instead what if we just spent $3B each on an SMR, with the expectation they would probably fail? I think that would have a bigger positive impact towards more nuclear in the future.
Solar projects take about 6 months. Solar projects are one of the only types of major infrastructure project that regularly come in ahead of schedule and under budget. (I couldn't quickly find the cite for this, but if I find it again I'll edit it in).
No they asked for 1GW of power in 6 months. You responded with the amount of capacity added in 1 year implying that amortized over a 6 month period. They asked how long it took from the start and you accused of moving the goal posts but it just looks like you’re talking about different things - throughout vs latency.
California already has a lot of solar installed in the desert. They could just expand that. Nuclear is a base load though, so they would need batteries or pumped storage to add to that.
Land requirement for Solar is negligible. Solar can be installed on lakes, reservoirs, canals, in deserts, on superfund sites, on farmland as agrivoltaics and on highways[1]. All these options are available in California.
A small fraction of land used for ethanol (40M acres) is enough to supply all the electricity that US needs.
But, I agree with you, Diablo Canyon is ready now, we should keep it online. We can't deploy new nuclear anyways, might as well keep the existing ones as long as possible. Besides, it might cost a few billions to decommission anyways.
Except how easy is it to build a plant to connect panels installed there to feed back into the grid? It’s not just a matter of throwing some panels down. Don’t you need ancillary large equipment to manage all that power safely?
> A small fraction of land used for ethanol (40M acres) is enough to supply all the electricity that US needs.
Are you sure that’s including capacity factor because solar panels don’t run in ideal conditions at all times vs assuming the rated panel output is what you’re always getting? Also I feel like that’s missing the storage requirements which is frequently ignored and would take up some non trivial amount of space.
Nuclear also generates base load - I dont think zero fossil fuel is possible (peaking is the hard one to solve), but I know its not even close to possible without replacing the base load supplied by thermal plants - without base load capacity, the grid goes down when the wind doesn't blow and the sun is down.
Citation required. You cannot replace Diablo Canyon with $6B of solar and batteries.
Installing your proposed $4B of solar will get you 4GW at peak, which will produce about 5840 GWh per year due to variations in sunlight over the days and seasons. Diablo Canyon produces 18,000 GWh per year. Replacing Diablo Canyon with solar will cost $12B plus batteries, maintenance, and operations staff.
The panels do but that just means the far more efficient, next gen panels that come on the market five years from now will be purchased and used to replace the original set.
So in reality, the often cited “20-40 years of utilization” they offer is nice to say but has minimal practical impact on future costs.
Diablo Canyon produces ~2 gigawatts of power rain or shine.
Let's say you need 12 hours of battery capacity, so 24 gWh.
A casual google search says grid-scale storage is $300-600 per kWh. Even generously assuming $300/kWh, that's $7.2 billion just for the batteries. How long do the batteries last?
I wouldn't call 8.5% insignificant. It's certainly not a majority, or even a plurality, but "insignificant" is surely downplaying its importance.
And if we shut down Diablo Canyon today, what do you think would replace that 8.5% in the years before a replacement solar+battery field could come online? Probably gonna be more natural gas.
I know right? Like install 3-5 more and California would be net 0 for the electricity grid making all those EVs finally meaningfully beneficial to the environment.
The plant generated 16,477 GWh in 2021 [1]. Over 5 years, it'd generate 82,385,000,000 kWh. At the LAX average retail rate of $0.287/kWh [2], that generation would return $23,644,495,000 in revenue.
That retail rate of electricity is mostly T&D; generators of electricity get far less than $0.10/kWh. Somebody else in this thread estimates that the $6B would result in $0.8/kWh, which is 50%-100% more expensive than new solar.
Yes, but it is still cheaper than nuclear, and has the benefit of increasing the productive capacity for installing even more solar and batteries.
The one-off work for nuclear here will do little to nothing to enable new nuclear builds. It's short-term dead money.
If we are truly at the limit of what we can deploy with solar and batteries right now, and we have spare money to spend, then perhaps this short extension is worth it, but it must be evaluated versus the alternatives such as floating offshore wind, enhanced geothermal, long-duration storage (100h), etc.
People are so excited about nuclear that they don't evaluate it rationally, on its own merits, versus alternatives. That is not a healthy way to help the climate. We must be very hard nosed about not only the short term impacts but also the long term effects of investing in industries.
Maybe what you're saying is true but it's pretty unclear to me. According to the article, it supplies 10% of the state's electricity needs. $6B over 5 yrs => $1.2B/yr => total cost of state's electricity at $12B/yr.
With a population of 40M this would mean yearly cost of electricity per capita in CA would be $300. That sounds extremely cheap.
Doesn't sound like highway robbery to me but maybe you can make that clearer rather than just tossing out "install $4B solar and $2B batteries which is obviously better, idiots!".
Wikipedia claims the plant generated 16 TW h of energy in 2019. At $6 billion for five years of generation, that corresponds to about 8 cents per kilowatt hour. That's not great, but it doesn't seem like highway robbery to me. Seems reasonable to keep using the plant while building up solar and storage capacity.
Wikipedia also claims that PG&E pays more per kwh for solar, without storage.
If diablo Canyon is cheaper than the next best alternative, then it obviously makes economic sense to keep it. It doesnt matter how scary the big number is if the alternative is higher
> $6B for a mere five years is highway robbery. Installing $4B of solar and $2B of batteries will result in 20-40 years of carbon-free electricity, and far far far more of it.
How would you install $6B overnight? That alone would take years. And where do you buy it from? China?
$6B is not a ton of money when it comes to solar and batteries, these are technologies on massive scales. Using round numbers of roughly $1/W for solar and $500/kWh, my off-the-cuff split buys 4GW of solar and 4GWh of batteries. For comparison, 6.5GW of solar was installed Q3 2023 in the US, and this is a tiny tiny fraction of the global market.
The challenge with large installs is the interconnection queue and permitting, not any industrial capacity limitation. And these could be solved by CPUC with a snap of their fingers, like they snapped their fingers to extend Diablo Canyon.
As someone who has worked closely with those running the Interconnection studies, this sounds overly rosey.
The ISO (in this case CAISO) runs those studies for a reason to maintain grid reliability. The reason they're slow is that it involves a crazy amount of simulations to determine grid upgrades and it is difficult when things must be done recursively and when the renewables developers speculate so much.
If the state regulator could snap their fingers, they would have done so in California, New York, the Midwest... everywhere. They made some changes to speed things up in Texas, but honestly they're kicking the can down the road.
China has the solar panel market cornered, so probably. Of course they might decide to cut us off given all the trade drama so I'm not sure even that is a sure thing.
> $6B for a mere five years is highway robbery. Installing $4B of solar and $2B of batteries will result in 20-40 years of carbon-free electricity, and far far far more of it.
Because the goal isn't generating arbitrary amounts of carbon-free energy. The goal is displacing fossil fuel use with carbon-free energy. California is already hitting daytime saturation of energy demand for about a month of the year. $2B in batteries isn't actually going very far. The US manages to build battery storage at ~500/KWh. So 2 Billion is only about 4 GWh. The Diablo canyon plant puts out 2.5 GW of electricity, so this is less than 2 hours worth of battery storage relative to the plant its replacing.
Diablo Canyon delivered 17,593 gigawatt hours of electricity in 2022 [1]. If California had continued to install solar power at the same rate it did 10 years ago, that much solar output would have been added in the last 3 years alone. Coupled with battery storage like you suggest, that would also cover the early evening demand peak in California.
However, California's rate of solar addition slowed down considerably since 2014. It went from 3,813 GWh of utility scale solar generation in 2013 to 9,932 GWh in 2014 for an annual growth of 6,119 GWh. But from 2017 to 2022 it grew by an average of only 2,994 GWh annually [2]. This happened at the same time that solar hardware costs continued to decline rapidly. California was more aggressive about building large scale solar projects when it was more expensive, and has oddly slowed down compared to other states in recent years. That's a reason that Diablo Canyon is still needed.
If California picks up the pace again on decarbonization with renewables, then Diablo Canyon can shut down. It shouldn't shut down while natural gas is still California's top electricity source [3].
Solar often produces much less power than the sticker because it doesn’t some at night (among other reasons). Someone else in the thread noted that solar efficiency is 20-30% of the installed capacity compared with 92% for nuclear (and solar costs always ignore storage which is a massive cost that would make the numbers waaay worse and is otherwise borne by installing nuclear/fossil fuels/hydro).
The numbers I posted already accounted for capacity factor differences, because they were generated energy output (gigawatt hours) rather than peak capacity (gigawatts).
Sibling posters seem to think that $6B isn't unreasonable (and that $6B spent on solar+batteries won't come close to replacing this plant), but I won't address that.
Take a look at today's CA electricity source mix[0]. Regardless of cost, why would you shut down a nuclear plant (prematurely, when there's no renewable capacity right now available to replace it) when we still burn so much natural gas?
Shutting down that nuclear plant now would require that 2.2GW supply to come from somewhere else. And I bet you it would end up coming from fossil-fuel burning. Even if the plan was to spend that $6B on building out solar and batteries, that would take, what... two or three years to come online?
Now, we should be doing both! Keep this nuclear plant online, and accelerate building out solar fields and battery storage. We shouldn't be building more nuclear plants, but things that work today... work today. Shutting this plant down right now would seem like a net negative, carbon-emissions-wise.
I disagree about not building new nuclear. I think we should be installing way more new nuclear capacity. Existing solar installation plans only handle peak growth during the day. However baseload power will increase (eg EVs charging overnight) and batteries are just way too uneconomical and won’t be for the foreseeable future (and they reduce the efficacy of those plants because you have to overbuild peak capacity even more to recharge the batteries during the day). Nuclear remains the cheapest and we should be installing next gen designs like MSR which are even simpler, completely safe (can’t meltdown), and generate even less waste which also means they’re cheaper projects. We get more out of every nuclear dollar we spend than we do for solar and we’ve spent a metric fuckton for solar already (it’s fine- we need solar and wind, but nuclear is well past the time to have been kickstarted into high gear but it’s never too late to start)
Let's do the math. I'm leaving out capital costs for Diablo Canyon because I'm guessing it's paid off at this point.
Diablo Canyon is producing 2 GW. $6B / (5 years * 2 GW) is approximately $0.069/kWh.
That sounds extremely competitive to me and not "just a PR game". You won't get solar and batteries installed and connected to the grid cheaper than that (especially not at current interest rates), sorry. There's also the fact that Diablo Canyon is running right now, while getting large amounts of solar and batteries connected to the grid is a years long process at this point due to grid operator connection planning backlog.
You so almost have a point I'd agree, but then go off the rails with your nonsensical solar retort.
I agree the expense sounds extraordinarily high to the point of not being profitable at all, but I'm not an expert in the energy sector so maybe the industry numbers really are that high.
however, my arm chair quarterback position in solar would immediately recognize you're numbers being touted for a solar solution in $ and years are just made up
So build those cheap, affordable, clean $6B solar plants in addition to nuclear plants and let's use them. California spent $100B on high speed rails that aren't even working yet, it can certainly fund two $6B energy projects.
47% of CA's power generation is still coming from fossil fuels as of 2022 [1], and that's before we consider non-electricity energy uses. It's ridiculous to watch people demanding we choose exactly one of nuclear or renewables while we're spewing CO2 to the atmosphere every single day.
I'm so tired of all these people that seem to be firmly convinced that we can't do nuclear and any other option.
Why can't we do both? We run nuclear for the base load that will always be there and then supplement it with wind and solar and what not. We know nuclear works we know it is stable. My understanding is that a lot of the battery and solar technology needs to be replace every few decades or so and generally involves mining operations that are highly toxic and produce many emissions.
Not too mention that we have to construct elaborate massive sprawling battery infrastructure to supplement a grid that depends heavily on wind and solar in order to answer the simple questions of "what about when it is nighttime or cloudy, or the wind isn't blowing?"
I don't get why so many people are fighting against nuclear. Either we need to do everything possible to reduce carbon emissions or not. Nuclear does not rely on some battery technology that is "almost there", and that is "showing promise". It is a proven technology that works and has a reliable answer.
So in short nuclear for the base, solar and wind for the supplement. There is no reason we can't do both.
P.S. Given the massive amount of government money being handed out for "green technologies" there's part of me that wonders about how honest this objection to nuclear and pushing of solar and wind is.
I dont know why you're being downvoted, you're correct.
We need base load capacity to replace thermal fossil fuel generation, it's not negotiable if you want the lights to work reliably 24 hours a day, no matter the weather conditions. Be it nuclear or more hydro - or we reconfigure to only run hydro when we need base load - either way it must be there.
I dont think we can reach zero fossil fuels, because of the need for peaking generation - but we can get pretty close though. Having to fire up a dozen gas turbines during severe weather conditions seems like a small price to pay if the other 99% of the time we could go without any fossil fuels at all.
There's another issue with firing up dozens of gas turbines: they don't spin up instantly. Hawaii (and California) are already starting to run into this issue, where peak use follows sunset. So even if you don't need it, you have to keep some generators going so they can ramp up fast enough when solar drops off and peak use starts. Otherwise you get outages.
With at most a ~30 min dispatch time, I dont know why a turbine wouldn't be adequate - what the turbines can't do, I would think a battery storage should be able to do. I suspect we have the same issue in Texas too.
What gets me is people propsing battery storage as a replacement for turbine peaking plants - which seems like a poor mix. I wish more places could build pumped storage, but it's hard to build.
I'm still a firm believer in nuclear though, with a mix of nuclear, renewables (solar, hydro, wind), batteries, and gas turbines, we should be able to solve this.
> $6B for a mere five years is highway robbery. Installing $4B of solar and $2B of batteries will result in 20-40 years of carbon-free electricity, and far far far more of it.
Do batteries and solar panels have lifetimes of 20-40 years?
Happy to hear the state is making a wise decision here, instead of bowing over to conservation groups who only consider climate goals when it aligns with their larger conservation focus
Wahoo! I mean it'd be nice if we could start not building nuclear reactors on fault lines, but I think this is a good start.
One of the things people underestimate in physical systems is the amount of tribal knowledge there is and how it actually takes skill and training for a country to become good at something.
One of the biggest challenges facing us right now is the fact that we've been reducing nuclear power and if we want to expand it we're going to need capable professionals to be able to do it, those won't spring out of thing air. Keeping existing facilities open will allow us to start training up new engineers that can work in new installations. b/c tbh ramping up nuclear work is probably one of the most important and pressing issues facing not just America but most countries to an extent right now.
We shouldn't be expanding nuclear power in California. We have so much sun, so much wind, and so much open, undeveloped land.
The calculus for other places (low-sun, low-wind) will certainly be different, but I don't think it's useful or productive to build new nuclear plants in CA.
I think it's the correct move to keep this plant running: it works, today, and shutting it down would undoubtedly mean picking up the slack with more natural gas burning, at least in the medium term, and that would be bad. But building more? I just don't see the need.
That is incorrect. Nuclear is baseload power and as such is way cheaper than solar at that (no batteries). All those EVs charging overnight (only at 2% of the vehicle market right now)? Baseload power that will have exponentially more growth over the coming decades.
We should be building so much nuclear right now it isn’t funny (should be targeting 40-80% of all production to hit net 0 I suspect). That’s like another 3-10 Diablo canyons worth of production. That doesn’t mean we shouldn’t build solar. We should to have it handle peak energy requirements and derisk things.
Also we should be building modern designs like molten salt reactors which are safer and cheaper.
Chinese or French nuclear power engineers should be in abundant supply, maybe we could just import the knowledge?
When I was graduating from high school, I did the navy recruiting thing just for kicks, and after taking the asvab, they said I had a promising career in navy nuclear. But that scared me away from the military, since my dad had a career in nuclear power, we even got a DOE settlement after he died of cancer, they don’t put nuclear power plants in nice places, it’s not the career I wanted. Towards the end of my dad’s career, many of the engineers were Central American (??? Not sure why) or Indian already. We can totally import the expertise in the future, especially if we are will big to build out French or Chinese designs.
No actually not the same thing. There’s a lot of local cultural expertise that you can’t import (ie regulatory environment and knowing how to work within it). You can import some technical knowhow but that’s only a fraction of the experience problem.
Also re cancer, nuclear power plants emit no radiation. All the radiation exposure risk comes when you’re doing certain kinds of maintenance (eg refueling). Nuclear subs are a different matter. I don’t know the safety standards there and the military is typically a lot more loosy goosey with safety.
Sorry, I should have mentioned that my dad got his start in nuclear at a reactor at Hanford. For some reason, he was included in on the settlement due to improper storage of waste, which is why the settlement was from the DOE and not Westinghouse (the company he was actually contracting for). I wouldn’t blame the reactor for the cancer, I’m not even sure it was the waste’s fault, but the cancer was rare enough to qualify.
If we bought plans for the French, I’m sure we could merge in American culture quickly. We won’t find any pure nuclear engineers being trained up in the USA anyways outside of the navy, there are only a few programs left.
What steps are being taken to transition to other forms of sustainable power generation beyond 2030? Solar and wind are pricing coal out of the market and modern nuclear options seem viable, yet we keep hearing “five more years.”
If my math is right on the "$6 billion over 5 years" then that is 2250 MW capacity * 720 *12 to get a bit more than 19000 Gwh per year. So what is the annual, billable power generation for this nuclear plant?
Has there ever been a case of a nuclear project that came in under the worst case projection? I'm sure there have been one or two. But typically nuclear is known for blowing past the cost estimates, not staying within them.
Ok, so if we shut off 8.5% of the electricity supply today(ish), where do we make up for that shortfall while we spend 2-3 years building a solar+battery farm to replace it?
Most likely we'd make up for the lack of that plant by burning more natural gas, at least in the short/medium term.
Also not sure why you think that price point is out of whack. Seems well in line with current CA electricity prices.
This plant should not run forever, but extending its life another 5 years seems entirely prudent.
Not to mention that this is all baseload power and therefore comes out way cheaper than similar solar once you include battery costs. And ignoring the fact that nuclear is 92% efficiency of nameplate power compared with 30% for solar but people keep comparing nameplate power.
I agree in principle, but it's also sitting right next to several fault lines. PG&E claims it's engineered to withstand quakes, but given PG&E's history, I'm not inclined to take them at their word on anything.
That would be the CPUC, which is apparently siding with PG&E. I can actually see CPUC's side here, there really aren't any good alternatives that are ready to go in any reasonable timeframe, but I do hope they're actually doing some independent verification of PG&E's claims.
Both of those links indicate they discovered seismic faults below the two facilities after construction. That seems like a reasonable thing to be wary of.
I've come to realize there are a percentage of people who are unable to visualize risk unless they have personally observed the issue. While others can visualize risk that has not yet happened.
I'm general those in the first group, while it comes in many forms, it seems to boil down to "What are you worried about, X hasn't happened". Trying to present it as neutrally as I can the two side seen to be "Hey you're playing Russian roulette, the bullet is going to hit you if you keep pulling the trigger, stop before it does and their response is. 'Nothing has happened so far why are you worrying about nothing?'"
The opposite perspective is "You worry about every possible thing that could ever happen. There are a billion things that could happen it's useless worrying about them all so just worry about the ones we've seen happen and are likely to occur."
Both have their merits and their downfalls. And I think these views have become more visible recently.
I feel more strongly towards one approach than the other, but I feel that often times people talk past each other because they're using fundamentally different frameworks.
So not weighing in one way or the other here. More just observing that this seems to be an instance of it between OP and you.
I have seen both tactics used by same person fitting to their agenda. In the end this is just another logical tactic ( or fallacy, pejoratively) and we have to keep cool mind to not be tripped by cheap tricks.
> The proximate cause of the accident was the 2011 Tōhoku earthquake and tsunami, which resulted in electrical grid failure and damaged nearly all of the power plant's backup energy sources. The subsequent inability to sufficiently cool reactors after shutdown compromised containment and resulted in the release of radioactive contaminants into the surrounding environment.
One person died from radiation exposure at Fukushima, from lung cancer, four years later. More people died from the evacuation. More deaths occur from rooftop solar installations, as fatal roofing accidents are one of the most common workplace fatalities. Electrical linemen also have a high rate of workplace fatalities, which means the power lines themselves are even more deadly.
Not sure why you're comparing utility-scale generation in Japan to tiny-scale residential generation here. I doubt many people building utility-scale solar farms on the ground are falling off roofs during those builds.
Rate of accidents for linemen is irrelevant; you need that sort of work regardless of your generation source.
Coal is even more dangerous. In other words, we can’t be so anemic to all risk and nuclear is comparatively very safe. At these levels, the talk of safety is a non-event (like the car everyone drives in every day in is riskier as is flying in an airplane which is also safer than driving a car not to mention gun violence which is “fuck yeah ‘Merica”). The risk here can just be largely ignored as statistical noise. You still need to manage the risk carefully when things do go wrong, but you existing reactor designs are pretty safe when Fukushima which ignored a bunch of warnings actually still turned out to be mostly a nonevent. Also modern reactor designs can’t even melt down so why are we even talking about Fukushima which is using heavy water reactor designs from the 80s?
It took more than a decade before it was deemed safe for everyone to return, and decommissioning the plant alone is costing tens of billions over several decades.
Sure, because we all know these safety systems are 100% reliable, and nothing like Fukushima (yes, I know, not quite the same conditions, but that's not the point) could happen again.
So instead of new, safe, carbon neutral nuclear power (like thorium reactors, passive cooling, etc), we're are continuing to running literal old-timer nuclear plants (Diablo Canyon was built in 1981).
Most folks would not drive a car from 80s, but somehow we're cool with running powerplants that old.
IMHO The best for our carbon footprint with safety would be new nuclear plants.