As an observer following the space, it is fascinating to me how everything in a given electricity/energy market changes once a given technology (solar, wind, energy storage) becomes "economic". Or, in other words, the best/cheapest on balance option for delivering electricity or primary energy.
Be aware that many current policies in Australia and vested interests are actively AGAINST further development of renewables. So all of this is actually IN SPITE of the regulatory environment, rather than because of it.
It will be interesting to see how prices move given all this new volume that will be coming online in the next decade.
Note for the curious: The reason the above is even possible is because solar and energy storage prices follow the same kind of principles / learning curve behind the proliferation of the microchip and Moore's law. While the curve and "speed" of cost reductions for renewables are no-where near as fast as MicroChips, I can only hope that this trend continues. See: https://en.wikipedia.org/wiki/Swanson%27s_law
For large-scale solar you need batteries, and batteries do not follow this kind of cost curve.
Countries that are truly interested in sustainable energy production should be building nuclear power plants. France & Germany will come to deeply regret their decisions to decommission old reactors and not build new ones, since nuclear is an incredibly safe source of baseline power.
Additionally, while nuclear is definitely a good option for delivering clean, always on electricity - the reason nuclear power plants aren't being built is because whoever is financing it / coming up with the money has to deal with not only a 5-10 year construction lead time but also a 50 year operating period. Given the cost reductions of renewables, how do you price in the risk that your plant will become completely uneconomic at some point in that time period?
I was referring specifically to the rapid Moore's Law-type decreases we've seen in the panels themselves, but upon investigation it looks that the price of batteries is decreasing faster than I had realized. So I'll cede that point. Global output of LiPo batteries is still a pittance compared to what would be required to run the world on solar, but there are promising trends there.
I should clarify that I'm not against solar as an important part of the energy mix, but it seems incredibly wasteful when we consider the sheer amount of material required in panels + storage to replicate the sustained output of a single fission plant, not all of which can be easily recycled. Solar hasn't historically been widespread enough for us to experience the issues associated with widespread end-of-lifing of components, but one look at the electronics industry and the waste it produces should tell us that it could be a massive problem we're kicking down the road. The sheer amount of material required to run the world on solar energy is staggering. Nuclear waste is comparatively a tiny and easily tractable problem by comparison - all the world's nuclear waste over a 50 year period could probably fit in a single underground site of sufficient volume.
There has been plenty of work done on smaller, safer fission reactor designs over the last 50 years, but the regulatory burden to get new designs approved & operational is extremely limiting. There's no way to do it without the support of government as things currently stand, and it's a pity - nuclear could provide 50%+ of the global energy mix emission-free with a relatively small footprint compared to solar, and certainly with far less in the way of materials input between plant construction & fissionable material (the latter producing 24,000,000 kWh from a single KG of U-235).
Solar decentralizes and democratizes energy generation. It’s waste (panels, mounts, inverters, wiring) is easily stored, transported, and recycled. It can be rapidly manufactured. There are no proliferation issues. It can be freely given to the third world to obviate their need for fossil or nuclear fuels.
Nuclear is worse in every other way except space used, and Earth is huge.
I will never understand the fawning over a technology that has proven so lackluster under human control. (Nuclear is fantastic with rigid controls such that the US Navy implements, but this never happens is commercial fleets)
Australia will be at 100% renewables before the first nuclear generator would come online if you broke ground today. We should stop mourning nuclear and keep ramping renewables and battery production. The model is proven at scale.
The main attraction of nuclear, judging by the comments I see is that "silly environmentalists don't like it". It seems the people who bring it up enjoy the thought of other people being wrong more than they enjoy being correct themselves.
This was already a little sad, but now that the economic case has turned decisively against nuclear power, with things going badly for basically every nuclear project and things going better than expected for most renewables it's becoming absurd.
> The main attraction of nuclear, judging by the comments I see is that "silly environmentalists don't like it". It seems the people who bring it up enjoy the thought of other people being wrong more than they enjoy being correct themselves.
Sorry, but you are the one making judgment calls and "enjoying being correct" here. I'm advocating for nuclear power, and I also understand the battle is mostly lost, so please don't act smug like this. Other than the economic case, there are massive hurdles on the way of a 100% renewables world, which I hope will be overcome, since that's obviously the way the world is going forward to now.
Solar and wind are reliable and economic in many parts of the world, but much less so in many parts of the world that already have very high population density. “Move everyone to a different part of the world” is an even less tractable approach than “figure out how to handle nuclear’s downsides”.
On top of that, while reliable and cheap renewables are “nearish future”, fusion tech is potentially not much less “nearish”, and would enable people to go back to living in Northern Europe, America, Asia, etc.
Note: I’m not trying to espouse or argue for a particular approach here; I’d trying to suggest some reasons why there might be so much (and such long-lived) “fawning over [nuclear] technology”. This is just some mildly educated guessing on my part.
> Solar and wind are reliable and economic in many parts of the world, but much less so in many parts of the world that already have very high population density.
Hence why the article describes one of the projects under consideration is a massive renewables concentration in northern Australia (the population of that area is a rounding error), with the goal of exporting to Asia via undersea cable.
You might be surprised how much nuclear waste is out there. A bunch of estimates on this thread put it in the "millions of cubic feet" range, which is considerably more than what could fit in a single underground site:
Note also that this is mostly just considering high level waste (like, the actual spend fuel rods and reactor parts), and not all low- and intermediate-level waste, of which there is a lot more:
If I follow your link, I read this: Over the past four decades, the entire industry has produced about 62,500 metric tons of used nuclear fuel. That's the high-level waste.
The rest of the comment goes on to explain that including all low- and intermediate-level waste, plus legacy waste from military activities, then it may reach the millions of cubic feet you're citing.
Low-level waste is not much more dangerous than the extra natural radiation you receive from a plane trip, so the real danger is high-level waste. And that can fit in a fraction of the space required for a single solar park.
UK estimates that the amount of nuclear wast we'll have (both high and low-level) will be smaller than the volume of one of the UK's national sports stadiums
Simple. Build molten salt reactors like Terrestrial Energy's IMSR, which have low capital costs and relatively short lifetimes for the reactor cores.
This is really hard in the U.S. because the NRC is very unfriendly to R&D, but T.E. has already gotten through the hardest part of Canada's licensing process and expects to have the first IMSR running by 2025 or so. Moltex and Elysium also have MSR projects in Canada.
Nuclear naturally looks bad if you compare today's nuclear to the future of wind/solar/storage.
Permissioning is complicated because nuclear plants, even small ones, are complicated. There's a reason real nuclear plants are getting bigger and bigger.
You're comparing vaporware to technologies with a proven track record.
A couple years ago I got to sit in a meeting between people from a dozen GenIV reactor startups and a former head of the NRC. The reactor people said their biggest problem was that the NRC required a near-complete design before they would even take a look. At that point they either said yes or no. If no then that was the end of it, you were out of business. If yes you still had only a paper reactor. Getting to that point required several hundred million dollars.
That's a very difficult sell to investors. They said just a more phased process would help a lot. The NRC person was unsympathetic, said it wasn't the NRC's job to help develop or promote nuclear technology, and was uninterested in climate change.
Canada has a more rational approach to R&D, while maintaining rigorous safety. That's why MSR companies are moving there, and why the first one, Terrestrial Energy, is making solid progress.
(And as a side note, molten salt reactors are a lot simpler than light water reactors, because they have safety advantages inherent to the physics of the fuel and coolant.)
> And as a side note, molten salt reactors are a lot simpler than light water reactors, because they have safety advantages inherent to the physics of the fuel and coolant.
I don't know. MSR's are certainly interesting, but they have downsides as well as upsides.
Some of the PWR SMR's like NuScale also sport passive safety features, which should make it simpler and safer. Being a PWR, it's still a high pressure design, of course, which MSR's avoid.
While MSR are very cool, in some ways they're pretty scary too. I mean, you're pumping around tonnes of super-radioactive goop. What if you have a leak? At least with a traditional design you have a couple of extra protective layers, with fuel being contained in solid pellets contained in tubes. And you have to be very careful with the chemistry of the fuel salt; IIRC one of the early MSR's (ARE?) had to be shutdown since they messed up their redox chemistry which lead to fissiles plating out on the heat exchangers. Eek!
There's the famous Rickover quote that anybody can design a paper reactor, but real reactors tend to be complicated, over budget, and over schedule.
That quote by Rickover is one reason we should fix the NRC process, so companies don't have to spend $300M and get nothing but a paper reactor.
Moltex Energy agrees with you on pumping fuel salt. They keep their liquid fuel in a fuel rod, open at the top, no pumping. All the rods are immersed in a pool of liquid salt coolant, which just sits there. Secondary coolant in pipes through through that.
> That quote by Rickover is one reason we should fix the NRC process, so companies don't have to spend $300M and get nothing but a paper reactor.
(I didn't answer your previous points about the NRC process, but for the record, I completely agree with you.)
> Moltex Energy agrees with you on pumping fuel salt. They keep their liquid fuel in a fuel rod, open at the top, no pumping. All the rods are immersed in a pool of liquid salt coolant, which just sits there. Secondary coolant in pipes through through that.
Yes, Moltex is an interesting design. The main drawback, AFAICS, is that since the fuel concentration in the fuel salt is quite low compared to solid fuel designs, they have to use pretty enriched fuel. I think their current plans call for 40% Pu. And the breeding ratio is poor, around 0.5 according to a paper I skimmed through a while ago.
Yes, the "waste burner" design. So the entire fuel story revolves around having access to spent fuel which they can reprocess to extract the Pu.
Yes, they also have the thermal design which I'm quite sure requires much lower enrichment, but AFAICT is more a concept than something they're actively developing. It makes sense of course to focus on one design at a time, unless they have infinite money.
One of the other fast spectrum MSR startups, Elysium, also proposes using spent fuel + maybe leftover military Pu for startup. The interesting thing about Elysium is that their design at least breeds, so they only need enriched fuel for starting up. They're saying that they can run up to 40 years before needing to reprocess the fuel, just by adding U238 online to the salt.
Only several hundred million dollars? This is not some software startup we are talking about here. The reactors are going to cost several billion dollars so it doesn't make sense to let startups just "wing it". Even if the R&D costs are 10 billion you could quickly amortize it by simply building multiple reactors with the same design. At least that is what the pro nuclear lobby says will happen.
It sounds like we should let Canada shoulder the brunt of the research and then build commercial MSRs once Canada has mastered the tech....in 50 years or so.
> Sorry, but you are incorrect. Technically, every manufactured good has a learning curve.
Sure. But at some point physics limits how far you can go. We had a good run for many decades with micro-electronics because it's possible to cram a huge number of transistors on a tiny microchip. For solar cells and batteries we're not that far away from fundamental physical limits.
So even though batteries look poised to replace gas for services like frequency control and some peak shaving, they're still orders of magnitude too expensive to allow us to completely run a grid on wind and solar, with no guarantee they will ever actually hit those price levels required.
Totally. And yes, no guarantee that battery storage will reach those price levels needed (i.e. if volume dries up).
However, for the last 20 or so years there were chants about the end of Moore's Law. Still appears to be going strong, "somehow".
My take on battery storage: several incremental developments coming down the pipeline on the anode and cathode side of li-ion batteries (improved chemistries, less cobalt, increased silicon %, new electrolyte mediums, etc). Combined with the "coming surge" of li-ion batteries and development for upcoming EV models with billions invested in new battery factories, it's hard to not see significant changes to the price within even a decades time.
> However, for the last 20 or so years there were chants about the end of Moore's Law. Still appears to be going strong, "somehow".
Well, Moore's law has already slowed down quite a lot, and in the not too far future we won't be able to miniaturize further since atoms are only so small (e.g. lattice spacing of Si is, from memory so might be wrong, 0.54 nm).
Of course, there is hope for various non-Si based electronics; we'll see.
> My take on battery storage: several incremental developments coming down the pipeline on the anode and cathode side of li-ion batteries (improved chemistries, less cobalt, increased silicon %, new electrolyte mediums, etc). Combined with the "coming surge" of li-ion batteries and development for upcoming EV models with billions invested in new battery factories, it's hard to not see significant changes to the price within even a decades time.
To clarify, I didn't mean to say that we're at the end of the road for battery development today. Just that we cannot expect decades of exponential improvement like we have seen with microchips.
I don't think an order of magnitude improvement in price/kWh is out of the question (in terms of kWh/kg it probably is, though?). But two orders of magnitude? Color me skeptical.
Aside from storing energy from a large array in the desert, won't we still need batteries for transportation in order to get them off fossil fuels? That is, even if my house runs off nuclear and hence no batteries, wouldn't I still need one in my car, hence a lot more innovation is needed in batteries anyway (albeit drastically different types of batteries)?
Like I mentioned in an answer to a sibling comment of yours, I didn't mean to say that we're at the end of the road for battery development today. Just that we cannot expect decades of exponential improvement like we have seen with microchips.
I don't think an order of magnitude improvement in price/kWh is out of the question (in terms of kWh/kg it probably is, though?). But two orders of magnitude? Color me skeptical.
Wrt cars, I think batteries are not too far from being viable to replace most uses in cars, city buses etc. And that will be a massive, and welcome change, in our society.
For long-range ships, planes etc. I don't see batteries as viable. My guess would be, for a future decarbonized society, synthetic hydrocarbons for planes and ships; some ships might use hydrogen or nuclear reactors.
And it appears nobody factors in the cost of nuclear electricity the cost of associated with non-zero probability of a malfunction, or dealing with the long-term storage of nuclear waste.
I do not understand how spending 2 billion on a plant and 50 billion in case of a major meltdown is better that putting 2 billion into covering the country in solar panels and batteries.
The reason, as many commenters have said, is the vested interest of powerful players.
> I do not understand how spending 2 billion on a plant and 50 billion in case of a major meltdown is better that putting 2 billion into covering the country in solar panels and batteries.
And 2 billion may be very optimistic even. The current price tag estimate for the nuclear plant being built in Finland is almost 10 billion euros, and over 10 years late. It'll likely be the second most expensive building in the world.
For Finland specifically, I understand it is difficult to rely on solar. May be in a 100 years, when we can run a superconducting cable through Russia to more Southern places.
On the other hand, imagine a scale of disaster if Fukushima-style meltdown happens in Finland. Is it really worth it?
I don't know how or why it happened, but solar/wind has become the most prominent notion of sustainable power generation.
It isn't. Not by a long shot. We don't even have a workable way to recycle or decommission photovoltaic solar panels after their useful lifespan. Reflector based solar plants and wind plants are causing so much ecological damage that their initial designers and proponents are now advocating against their use. At the same time these plants are consuming huge amounts of land that must be cleared of native flora and fauna. The guys building the Ivanpah solar plant have been walking off their jobs because of the wildlife destruction they were causing[1].
Wind and solar are a feel-good distraction which fall an order of magnitude short of meeting our projected energy demands. I'm not fundamentally against these power sources, but ignoring their limitations and trying to scale them to tackle climate change is absurd.
Nuclear is literally the only path forward. Nuclear fusion preferably, but even nuclear fission with all its downsides is currently the lowest deaths per kWh and lowest ecological/climate impact per kWh power source that exists today. Nuclear is also the only power source where we can internalise the waste product and store it in an inert form instead of immediately inflicting it on the environment. It's an order of magnitude better than solar/wind on those metrics.
This is not a controversial fringe view. This is what pretty much everyone in the sector has converged on over the last decade. It just hasn't filtered down to become popular opinion for some reason.
> Reflector based solar plants and wind plants are causing so much ecological damage that their initial designers and proponents are now advocating against their use. At the same time these plants are consuming huge amounts of land that must be cleared of native flora and fauna. The guys building the Ivanpah solar plant have been walking off their jobs because of the wildlife destruction they were causing[1].
I've lived in places with massive wind farms and the turbines don't take up very much space. Each one displaces a small amount of corn or soybeans, perhaps enough to feed a family of 4 when considering the small perimeter and dirt driving paths (stupid trade wars notwithstanding). And each turbine creates enough energy to power 200 homes or so, which to me is a great tradeoff.
I encourage everyone to watch the 3 minute, 11 second video linked that presumably supports the claim that wind energy is causing massive ecological damage. You'll find that wind energy isn't even discussed in the video, which is about a solar reflection plant that boils water to power a turbine. The project designers moved, according to the video, roughly 173 tortoises, to another location. And quoting the video, they found "no significant difference in the survival or mortality" of those tortoises.
The strongest statement against this clean energy plant was a claim that in the 1940s or 1950s, there were lots of tortoises in that area. Was the plant created in the 1950s? Did the plant cause the tortoises to die or go somewhere else? I don't know when the plant was created but I'm guessing it was recent, and if so, it would be dishonest to blame it for a change that sounds like it started in the 1950s.
I started supporting wind energy in 1992, and am a bigger supporter today.
I'm not against nuclear energy; I think we need more of it. That said, nuclear proponents will probably have better luck comparing nuclear to coal than by attacking clean renewable energy like wind and solar. Wind and solar are here, they're good, and they're part of the future.
The linked video is about Ivanpah which in addition to the wildlife displacement, kills around 6000 birds each year by incinerating them mid light. At no point was that video purported to be related to wind energy.
If you want to read up on the impact of wind energy, let me google it for you.
Each turbine requires the clearing of 5 acres of land around it. Each turbine 'powers 200 homes or so'. There are 128 million homes in the US. That's 640k turbines. That's 3.2m acres of land cleared of vegetation and wildlife just for turbines, nevermind access roads, energy storage, etc. Wind turbines currently supply 8% of US demand and at this scale they kill around 200k birds, 600k bats and ~10 people in maintenance accidents each year. Multiply those numbers by 12.5 to power all of US. Multiply those numbers again by 10 to power china. By 100 to power the world. Starting to get the sense of how absurd this idea is outside of small-scale feel-good wind farms that look past the ecological damage?
I'm pro nuclear, but it's hard to be. The communication around the nuclear industry has been anything but honest.
Typical nuclear plant costs, when compared to wind power in France, do not include decommissing of the plant or the cost of cabling while it is for wind turbines.
Also accidents side effects are downplayed so much it's insulting. According to the french medias, the tchernobyl nuclear cloud never crossed the french border. Yet we know now that thyroid cancer near said border spiked during a decade, and it's impossible to sell nuclear energy to one of my best friend whose life has be shatered it.
So the first step to promote nuclear power would be to actually respect people.
> Also accidents side effects are downplayed so much it's insulting
I think you might have fallen for media bias. While the nuclear industry doesn't have anything resembling a flawless safety record, it's still orders of magnitude safer than all mainstream power sources which see no scrutiny due to the dilution of their impact.
Nuclear accidents are viewed as bad in the same way that airline crashes are viewed as bad, despite airlines being the safest mode of transport and safer than the car journey to the airport. They are extremely rare, and they impact >100 people when they happen so they're always newsworthy. Unlike the 4.6M people that die due to fossil fuel related air pollution worldwide at a steady state each year.
Telling the population the border is safe knowing it's not and then they get cancer is quite factual.
I'm not talking about potential risks, I'm talking about actual confirmed events and the way they have been handled. It's not speculation, it's history.
The problem here are not the victims. It's not the risk or the stats. It's respect.
E.g: I can read your comment calmly. My friends with his scar in the throat and his helicopter pilot career down the toilet ? He would insult you and you would lose any chance of convincing him and hence his social network about nuclear.
So yeah, the pro nuclear community has a serious communication problem.
> Telling the population the border is safe knowing it's not and then they get cancer is quite factual.
It's not so clear cut. Thyroid cancer rates started increasing dramatically almost everywhere in the world in the mid 80's. Diagnosis rates in the US for example have tripled since 1980, in South Korea they have gone up 13x since 1993. Meanwhile the mortality rate has been completely flat. The most likely cause of this is increase in both screening and the sensitivity of testing [1]. There is also a current debate about if we should be screening / treating thyroid cancer the way we are, i.e. it seems like we're detecting a lot of innocuous thyroid cancers and then operating without need resulting in unnecessary life long complications for the person.
This is why there is a lot of research out there indicating that the vast majority of the increase in thyroid cancer diagnosis in areas like France is unrelated to Chernobyl.
It is worst than this, of course, because some plants accumulate radioactivity and we ate them. No recommendation had been given to the general population at all.
The region with the most thyroid cancers in the 20 years following is the Isère, at the center east of this map.
Now let's say we end up calculating that the actual number of cancers is, let's say, 100 more in France because of the cloud. It would not be much, and would not be worth acting on it: the flu would be more dangerous.
I've seen the exact opposite in the general media - when Fukushima was occurring people were buying iodized salt in North America out of panic (I was working at a drug store at the time, I watched it happen). If anything, when people think of nuclear power they only think of the accidents.
I had a cousin in CA worried about Fukushima defend her concern by saying that she had a Ukrainian friend whose family was affected by Chernobyl. Two guesses as to how effective it was to tell her that Chernobyl was freaking IN Ukraine and that CA is as far from Fukushima as New York is from Chernobyl.
Most people make decisions based on a hazy blur of random exposure to flashy stories, not anything remotely resembling rational adult thought. I don't know what the solution is to nuclear's PR and political problems, but I know that it isn't anything that requires a third grader's level of critical thinking ability.
I don't know about France but in the U.S. nuclear plants are required to put money aside for decommissioning. They were also required to pay into a fund for long-term waste storage, but since the government shut down its long-term waste facility and companies have to store waste on site, a court decided they shouldn't also have to pay into a fund that's not doing anything.
Regarding Chernobyl, I'll just mention it was used both for power and weapons production, and lacked basic safety features including a containment dome.
I'm pro nuclear and french. The media are terrible when speaking about nuclear, but the communication around nuclear is not bad. There is some obsfucation using technical jargon, but almost nothing is hidden. IMHO France has made a big mistake when it has stopped building plants. Now, we have lost most of our know-how. I think the future is solar power and that a nuclear plant build now will become obsolete before being amortized. It is too late to build new nuclear plant and maybe a bit too early to build solar plants.
Like many other topics today, discussions around energy and renewables has become so ideologically driven that it's hard to find any actual decent discussions.
The cost for handling nuclear waste is likewise ignored. Even worse, forget the cost, just knowing what to do with the waste isn’t absolved problem. A solution isn’t a solution until we know how to deal with this last step.
Temporarily storing the waste onsite forever isn’t a solution.
Fusion is a pipe dream, an absolute fantasy. Yes, we should still research it, but it’s still a fantasy. We can’t even sustain a positive energy fusion reaction let alone deploy it as an energy source.
Waste isn't 'temporarily stored onsite forever' It's stored in cooling pools onsite while the most active radionuclides decay, because the fuel elements are giving off enough heat to melt if not actively cooled. This takes around 5 years. After that the waste is moved offsite for vitrification and storage.
Vitrified nuclear waste has caused a grand total of 0 deaths or incidents throughout its history. More people die due to solar plants each year than have died to vitrified nuclear waste in all time.
Gen 3, never mind gen 4 reactors are able to consume waste from older reactor designs and spit out relatively inert waste products. Gen 4 reactors generally don't produce the kind of active waste that needs cooling pools, and their waste can be immediately made inert.
The hot waste problem exists only because most plants operating today date back to cold war era designs and were intended to produce weapons grade nuclear material rather than the the cleanest kWh. Despite that, they're still cleaner than every other energy source we have today.
> Vitrified nuclear waste has caused a grand total of 0 deaths or incidents throughout its history.
How do you know? From what I learned, a big problem with spent fuel is radiotoxicity. How do we know that no amount of weakly radioactive, but pretty toxic because of that material made it to the environment? Are all those storage containers that safe?
Vitrification is the process of turning the spent fuel into a glass-like substance. This includes chemically stabilising the fuel so that it's not chemically reactive, and immobilising it in a crystalline structure. While vitrified waste is stored in containers, it doesn't really need them. The only way it would be a health hazard is if it were liquefied with sulphuric acid or aerosolised by explosion and then ingested.
Even if all that were to happen in the worst possible case scenario (as has happened at Lake Karachay in Russia where untreated nuclear waste leaked into the groundwater in large volumes), it's still a long shot from being as deadly as the fossil fuels we take as a given today. That sets the upper worst hypothetical imaginary case for vitrified nuclear waste if some super volcano erupts at the storage site and converts it back into a chemically active form.
You can buy kitchen plates and glasses made from uranium glass, and that stuff is relatively a bigger hazard than vitrified nuclear waste. So is the americium in your smoke alarm, so are the various nuclear materials used at your local hospital for radiography and radiology.
To really nail this point home: coal fired power plants release more radioactive waste into the environment that nuclear plants do. The trace uranium found in coal can't be combusted and makes its way out the chimney, and that is more than a nuclear plant releases including disposal [1].
> coal fired power plants release more radioactive waste into the environment that nuclear plants do.
Are the coal-produced concentrations of such waste equal or higher than with the nuclear power waste? Say, if somebody is particularly unlucky and digests that?
I'm not against nuclear, and I'm not saying renewable are absolutely perfect, but let's break down the claims you're making here as there's a lot to unpick.
>We don't even have a workable way to recycle or decommission photovoltaic solar panels after their useful lifespan
Nor do we know how to recycle nuclear waste (since that's what you're comparing it to) At best we know how to store nuclear waste, but we'll only know if we've done a good job in thousands of years so I wouldn't bet on it.
You also seem to forget how Uranium is mined in the first place, but mining is involved for solar panels so I'd say they probably compare equitably here.
There is however progress in recycling solar panels [1]
>Reflector based solar plants and wind plants are causing so much ecological damage that their initial designers and proponents are now advocating against their use
What damage are we taking about? The tortoise in the link you gave seem to have been displaced. Sure it's not the best, but I'm sure building a nuclear plant comes with its own side effects, such as warming of the surrounding water, increase in traffic and noise pollution for the local wildlife.
>The guys building the Ivanpah solar plant have been walking off their jobs because of the wildlife destruction they were causing
There's no mention of that in the link you posted
>Wind and solar are a feel-good distraction which fall an order of magnitude short of meeting our projected energy demands.
Wind and solar resources can provide an order of magnitude more than what we currently consume. [2]
>Nuclear is literally the only path forward
No it's not.
>Nuclear fusion preferably
Not anywhere near being production ready, though the day it is I'm happy to have a fusion boiled cup of tea, heck I'm happy to pay more taxes in order to fund research.
>It just hasn't filtered down to become popular opinion for some reason.
> Wind and solar resources can provide an order of magnitude more than what we currently consume. [2]
Why are you linking a study that just looks at the potential wind kinetic energy available for conversion? A study that ignores where the bulk of useful wind turbines would need to be built? That ignores the economics and ecological impact? I mean that study is pretty clear about what it's looking at, and it isn't at all what you're implying.
"We elected in this study to exclude forested, urban, permanently ice covered, and inland water regions"
Uhhhh. Cool, in more breaking news, theoretically if we cleared flora/fauna and covered 1/5 of each continent in solar panels we'd also exceed our energy demand!
Did you just google your premise and pick a paper that vaguely seemed like it agrees with your presupposition? Take the time to actually read it.
Sorry for ignoring the rest of your gish gallop. I'm sure you understand that it's hard to engage in serious debate with people who scan your entire post for a couple of uncited fragments and latch on to those one by one. If you held yourself to the same standard, your entire comment would need to be broken down line by line and attacked since you have cited nothing. Especially if you're ignoring commonly understood facts like the existence of a nuclear waste disposal cycle, or if you're citing completely unrelated papers without even checking them first.
> I don't know how or why it happened, but solar/wind has become the most prominent notion of sustainable power generation.
Clueless environmentalists demonstating, skyrocketing costs for construction of new reactors, overregulation, fear of nuclear proliferation.
Nuclear is not the only path forward, there's also geothermal power where it's available. Nuclear can be nearly renewable if we reprocess and recycle nuclear "waste" and further burn it in fast breeder reactors. Unfortunately those are prohibitively expensive.
Base load power and high capacity factor. It's not preferring it to solar/wind but using it as base load and supplementing with solar, wind, hydro and gas peaker plants when there's availability or demand.
Modular nuclear reactors could also very useful and they're quite safe since they're derived from naval PWRs which have an excellent track record. So far only the Russians have two naval reactors on a barge called Akademik Lomonosov. The rest of them are in various stages of design or regulatory review. There's hope NuScale will be comercially available around 2025.
>Clueless environmentalists demonstating, skyrocketing costs for construction of new reactors, overregulation, fear of nuclear proliferation.
No shortage there.
Last week I just saw a bunch of kids camp out at our city hall to protest and demand the “New Green Deal” which proposed to eliminate plane travel and retrofit all buildings in the USA with renewable energy...
Two quotes from the article contradicting your outdated talking point:
> “The battery pipeline has grown exponentially,” Dixon says
> Other projects include the 4GW Walcha project in NSW, proposed by Energy Estate and Mirus Wind, which aims to combine huge amounts of wind, solar and storage for the biggest project proposed so far for the main grid.
It's funny how the wider tech community has this obsession with nuclear technology. It's a sort of scientism, where the actual science has long moved on, but a certain group just clings to outdated ideas because they are still invested in a culture clash. It has gotten to the point where I think the potential danger of nuclear technology is actually appreciated, as a sort of sticking-it-to-the-environmentalists feature. Or it's a symptom of people growing up with science fiction culture prominently featuring nuclear power, unwilling to let their ideas of a glorious future go.
But the facts have simply moved on, and renewable energy is now winning on economic arguments alone. Thanks to actual scientists, and to a significant degree politicians (especially Germany) offering magnificently effective subsidies, solar, wind, and storage are now competitive even with coal. Nuclear power is big hairy dangerous technology some people somehow adore, but it's also prohibitively expensive.
People like the idea of nuclear, but none of these pro-nuclear advocates can make it cost-effective in practice. Look at South Carolina, what a debacle and the costs are being thrown onto rate-payers. New-build nuclear is just not working economically in the USA, we'd need a big change in policy, permitting, and willingness of the populace.
In many ways, China's nuclear demonstrates the advantages of its authoritarian system; it can get some things done far better than democracies, willingness/permitting/policy being such non-concerns for their governmental system.
And nuclear power costs less than half as much in South Korea. An MIT study examined the reasons and suggested various changes to industry practice and regulations in the U.S.
I've read in various places that nuclear power missed its window of opportunity. It would have been great had they been up and running now. But to start building them now would mean they're up and running after wind and solar and batteries have significantly brought the price of power down to a level that makes nuclear power plants unviable.
Yeah - renewables are quicker to bring online, and allow for faster iteration and innovation. If Australia currently had nuclear power plants I definitely wouldn't be in favour of shutting them down, but it seems a better bet to invest in the renewable energy.
> Storage of nuclear waste is a close-to-unmanageable risk
Not in Australia it isn't. We have very large areas of geologically stable, sparsely populated land. Some of it is even already contaminated by nuclear tests in the 50s.
The green movement does not have that kind of political power, and in any case is split on nuclear. What has stopped nuclear is almost entirely economics.
> For large-scale solar you need batteries, and batteries do not follow this kind of cost curve.
Tesla would beg to differ. Their entire EV market is made possible by better, cheaper batteries, and that stems from the popularization of smaller, longer lasting, power sucking smartphones.
Presumably you're referring to Lithium or Cobalt - but the supply of these resources really isnt an issue (at worst, it's an issue of timing). Lithium mines in North America are beginning to reopen [1]. Cobalt is a bit trickier, because it's produced as a byproduct - but Panasonic already has cells working at R&D with dramatically less cobalt [2].
Elon Musk has said on Twitter Tesla intends to produce batteries without any cobalt in the future. And lithium is extremely plentiful as you mention. The materials supply is a non-issue.
Yes indeed - I just found a different, primary source. Some people (unfairly, I feel) write off anything he says.
I saw a cool graph showing how much cell price would change if different material inputs price changed. Essentially, cobalt or lithium could double in price, and the cost of a battery pack for a car would only increase 5-10%. Can't find the exact graph, but this article has quite a lot of detailed info on battery price constituents. http://thedeepdive.ca/lithium-ion-battery-cells-cathodes-and...
edit: oo it actually has forecasts for cobalt production and demand showing demand for cobalt higher than supply by 2025. And forecasts that material costs are not likely to drop. And that manufacturers will work other angles of the price equation to get prices lower.
That is something that changes every year as well, and Tesla in particular has greatly cut the scarcer materials in the latest iterations of their batteries.
Fossil fuels are safe. They kill people, but they kill a fairly low and most of all predictable number of people. Theyre dangerous for a coal miner, but not for a country.
Nuclear power is generally pretty harmless. But when it fails, it has the potential to kill millions and render large parts of the country uninhabitable. That is danger.
I still think we should have gotten rid of coal before nuclear. But long-term, nuclear is not an acceptable power source.
I am not against nuclear power, but I am also slightly skeptical of such high praise which seems to appear in every thread related to "green" energy. To refute your comment about batteries, there was an article 2 weeks ago on HN[0] analyzing the significant drop in battery prices over the years. It's not a Moore's law but the present price is also better than some earlier cost-projections[1].
According to Wikipedia's entries about France[2] and Germany[3] neither country is without accidents, albeit not Chernobyl or Fukushima-level incidents. The list of accidents involving Gen-II and Gen-III reactors is quite long[4], with USA leading (of course they have the highest number of reactors worldwide so it makes sense).
Please correct me if I'm wrong but as far as I can determine, a majority of operational reactors worldwide are still quite old (1965–1996) Gen-II designs with a smattering of Gen-III and most recently a handful of Gen-III+ upgrades, with most plans to upgrade being put off due to Fukushima.
The safest Gen-IV designs are planned to start construction earliest in 2030. I can't find any installations of Gen-III+ reactors anywhere in Europe, they seem to be spread across Asia with a small handful of US installations.
Also considering the reality of climate change and the resulting expectations of increasing frequency and strength of weather events, I would think another Fukushima-type event is not far away, especially factoring in the age and possible lack of preparation for such extreme weather events.
Also waste management is not a minor issue with no real solution other than "bury it underground and hope nobody digs it up by accident in the future".
There are some startups that try to store energy by lifting or spinning concrete (see www.energiestro.fr).
Also please note that in case France and Germany electrical grids frie because of a solar storm, cooling down the reactors will be impossibe once the emergency power generators run out of fuel.
Because the main reason for using renewables is to reduce CO2 emissions and Nuclear is a great way to reduce CO2 emissions and it is the safest technology around. (yes, even when accounting for Chernobyl, Three Miles Island and Fukushima).
I think it's no longer great; it takes too long to build, costs too much, presents a decomissioning problem, and still never quite dealt with weapons proliferation.
The weapons proliferation part has already been dealt with, since it depends on the type of nuclear reactor you build. Thorium salt reactors, are non-proliferation by design.
> costs too much
because we haven't invested in any experimentation in most markets. The US has stopped building new reactors for decades. There's no reason why nuclear reactors can't be made to be cheaper.
> I think it's no longer great;
This needs a benchmark. Nothing is great in absolute. It's still great vs all the other energy productions methods. Solar need huge surfaces to produce large quantities of energy, and solar panels require very toxic materials for manufacture... nothing's perfect unfortunately.
I love how there's always someone citing some future reactor design in response to criticism. Of course it's different future designs for each specific argument against nuclear technology.
> The weapons proliferation part has already been dealt with, since it depends on the type of nuclear reactor you build. Thorium salt reactors, are non-proliferation by design.
It's interesting how you say "has been dealt with" and then point to a technology that barely exists in reality.
Thorium reactors have been promised as a solution since a long time, people have predicted that many of them will be built really soon. It hasn't happened.
> Thorium salt reactors, are non-proliferation by design.
No. In some ways they're much worse, in fact.
> Nothing is great in absolute. It's still great vs all the other energy productions methods. Solar need huge surfaces to produce large quantities of energy, and solar panels require very toxic materials for manufacture... nothing's perfect unfortunately.
Indeed, by many metrics (deaths per kWh, environmental footprint) nuclear is the best option we have.
People don't think about solar like lego. Once you connect the first panel your pumping out energy. Then you just keep going.
Nuclear has such a complex set of technologies and industry that needs to be developed and maintained. The buildings themselves take years to develop and construct.
The real problem with nuclear is that when it fails, it fails hard and damages the environment for decades if not more. Wind and solar have the smallest impact even when they fail as far as I am aware. It is about more than just CO2 reduction.
Animals and plants don't care as much about higher infant mortality, cancers or lower lifespans as humans do. Plus the cumulative effects of radiation are less deadly than human predation and habitat destruction.
Depends on what you value more. Nuclear causes fewer deaths by a magnitude than solar and wind. And what is worse, dead birds from turbines and land covered in panels so that vegetation can't grow and support the native wildlife, or some giant stable old salt mine filled with nuclear waste and closed off from the world?
That assumes the land was available for wildlife before the site was constructed. In the UK our solar sites are on farmland, and provide a far superior habitat to intense agriculture. Wildflowers can grow under the solar panels which is fantastic for bees and butterflys. Also, it is common to do surveys to model the risk to birds and avoid important populations and migrating species.
Also, deaths during construction tend to be workers who have signed up to the risk. That isn't OK, but it is a lot less bad than risk to random members of the public who have not consented. And it is a vast improvement on the deaths caused by fossil fuels.
That baseload argument cuts both ways. Solar and wind can only serve as a baseload from 10-2, but only on sunny days, or when the wind blows (but not too hard). There's a reason every country moving to wind and solar is still burning more and more coal. Not everyone is as lucky as N. America to have a near limitless supply of natgas to make up for renewable's huge shortcomings.
People falling from rooves installing panels, mostly. Probably a few people poisoned by chemical pollution from manufacturing/disposal of panels as well.
The main reason that plants are actually built is to generate energy and the resulting revenue. Other issues like CO2, safety, emissions are the responsibility of regulators. If an investor can't get a return on a nuclear power station then arn't going to build it.
Not everywhere in the world has the land area to do wind and solar. In fact pretty much everywhere other than Russia, Australia, Canada, the US and Brazil.
There the energy density per head of population is too high for renewables.
Good video by the late David Mackay on that point here.
Nuclear takes a lot of space for security etc. In terms of power production vs lost land area wind is orders of magnitude butter if you have farming. And solar can be placed on other structures making it’s land cost approach zero.
You can also send power under water quite a ways cheaply. So, it’s hard to find a location which needs extreme power production density.
Nonsense:
"Specifically, this report finds that coal, natural gas, and nuclear power all feature the smallest physical footprint of about 12 acres per megawatt produced. Solar and wind are much more land intensive technologies using 43.5 and 70.6 acres per megawatt, respectively."
Multi megawatt wind turbines take up about around 1/4 of an acre. The rest of the land around them can be used for agriculture. https://www.awea.org/wind-101/benefits-of-wind/wind-in-my-co.... That’s several times more space efficient than nuclear as long as you also need farms which most countries do.
As to solar, clearly you have seen them on roofs which have no other real use.
Nuclear power is really expensive even in China and other countries outside of US regulations. This becomes much worse if you can’t run at 100% 24/7 so it effectively needs storage. France got around this by exporting a lot of power, but that only works until everyone tries to go nuclear.
Combining wind and solar dramatically changes the numbers, thus making a meaningless argument. They are so cleap you can balance the cost of overproduction and storage to end up with minimal storage. But in such an environment Nuclear is simply more expensive than either extra wind production or storage making it nearly useless.
That was written by someone that clearly does not know what they are talking about or was simply lying. Many off grid systems operate by having excess solar and minimal storage.
“storage for what could be many days — or even a month or more — of power.“
The only way you get that kind of assumption is to set production at exactly as much energy as you need over the year. If you produce extra power every day then you never need even 1 day of full storage. It’s true wind and solar does not always produce the same amount of power every day, they never produce zero. Thus, it’s a question of what you scale the system around minimum or average production over some time frame.
Run the numbers vs. assuming minimum production and some storage is a net gain. But, as Nuclear costs at a minimum twice as much and also needs redundancy, actual storage requirements are fairly low. Those numbers get worse if you need run Nuclear as less than full capacity.
The grid currently has almost zero storage. Saying we should build several times as much storage seems to suggest we need a lot of storage. But, it’s relative to a very small baseline. 1 hour of storage would be a vast increase, but it’s 1/10th the cost of 10 hours of storage. So, you need an accurate estimate to work from.
Further, the ideal amount of storage is heavily influenced by price and cost of production. The grid is a huge complex system and simple models don’t provide good answers.
Power generation must match demand very closely and in real time.
Demand is very predictable. As for supply, the generation capacity of fossil or nuclear power plants is known ahead of time and can be managed to provide power in a predictable fashion. These plants don't randomly begin generating more power when the wind blows or when the clouds part or the sun rises and they don't randomly generate less power when the winds die or the clouds arrive or the sun sets.
You don't need storage mechanisms with this type of generating capacity. But if you try to shift significantly towards solar/wind to provide power you now have an unpredictable generating system. That can be mitigated to some extent by adjusting the output of the traditional plants but the more your generating capacity is moved towards the unpredictable renewables the harder it becomes to keep the balance.
Even if you manage to keep things balanced, you can't decommission the old plants because sometimes (dark windless nights), your renewables aren't going to generate any power and most or all of the power has to come from those plants you were trying to replace with the renewables.
The only way around this is to come up with some sort of storage mechanism that can react quickly to the varying supply of renewables to maintain a smooth/constant power supply. Which wouldn't necessarily be a problem except for the fact that we actually know how to build high-capacity cost-effective storage mechanisms.
These number should are off the top of my head but should be reasonable.
Suppose, you want to supply an island with nuclear power. Lowest recorded useage at was 1GW of power and the peak recorded daytime use is 3.5KW of power. Average annual power useage was 2GW and peak daily useage was 2.4 GW.
You can buy nuclear power in 0.25 GW increments with 95% of the cost being there of the power is used or not.
Nuclear costs 149x per GW, Wind 45x, solar 40x average daily output. Nuclear needs to be offline 4 days out of the year for maintenance, wind and solar provide a minimum daily output of 40% their maximum.
Now, without lot of storage nuclear needs 3.5GW even if one plant is offline at a minimum but preferably some cushion if future needs are over 3.5GW. Thus we need 4GW of Nuclear for 596x to be safe. (Larger grids need less cushion, but still need to plan for multiple GW or Nuclear to be offline.)
Wind and solar need some storage, but even using the lowest values of 40% average output that’s 45 /.4 x 3.5GW = 400x.
Though if we had some storage we could also drop Nuclear to 2.4GW + safty factor to get closer to 400x. But remember we now produce 2.5x as much solar/wind on the average day for the numbers to get close, and we still need to use storage for nuclear. Further, those assumptions are unfair as in practice solar and wind minimums don’t occur on the same days as maximum power usage.
Your reasoning doesn't follow. If France's nuclear power was expensive, how did they export it? They sold it on a market where someone thought it was a better deal than alternatives.
When the value of something is zero for you, making anything from selling it is a net gain. It’s true France needed massive subsidies to get into that place, but by exporting they needed slightly lower subsidies.
For a current example, the US loses money by exporting subsidized food. But, they would lose even more money by letting that food rot.
South Australia has rolling blackouts in the summers when the coal "peaker plants" come online, and it takes 30-45 minutes in some cases for them to come online during a surge in demand due to blackouts. The government turned to Tesla to install (at the time) the biggest industrial battery in the world at 100MW / 129MWh and it is really working. Here is some info on it with some details (electrek is a Tesla fanboi site, but the reporting is accurate):
Which policies or regulations in Australia are against the development of renewables? The Renewable Energy Target scheme alone provides over $2bn in annual per mw/h subsidies to renewable energy generators, and is legislated to continue until 2030.
If renewable energy is truly the cheapest way to generate electricity, would you agree that subsidy schemes like the RET are no longer needed, and should be repealed?
Renewables have been the best/cheapest for a while now. What you are talking about is when they become so much cheaper/better that they overcome any subsidies and unaccounted externalities in fossil fuel alternatives.
Well run countries take advantage of this to save themselves money (e.g. subsidies to solar have paid for themselves even if you solely count reduced mortality rates from pollution.)
Oligarchies use a lack of understanding of this to extract out the last bit of wealth from their citizens that they can before the market comes for them.
A recent MIT study examined exactly what contributed to the price declines and government support accounted for the vast majority of the price decline:
Renewables are not the cheapest when you add in the backup base load generation systems that are required to run a grid 24x7. The sun doesn't shine and the wind doesn't blow 24x7.
I think the time it'll take to come up with economic grid storage will be a lot shorter than the time it'll take to get thorium and liquid salt reactors designed, tested and constructed all over the world.
It is not an analogous situation at all and it is mainly due to the highly intermittent/variable nature of wind and solar.
If I have to provide 100 units of energy (peak) a wind/solar farm that produces 100 units of energy (max) doesn't cut it. Solar obviously varies with time of day and doesn't particularly match actual demand curves. Wind is very unpredictable and can generate 0 units of energy when it is needed and 100 units of energy when it isn't needed. So you still need to have 100 units of capacity coming from traditional systems (coal/gas/nuclear). Congratulations you are now using renewables perhaps 30-40% of the time, still building/maintaining your existing systems, and everybody's electric bill has doubled or tripled.
See southern Australia or Germany for real life examples of the problems caused by relying too much on renewables.
These problems can be solved though with renewable backup/storage sources and increases in efficiency in electricity consuming tech.
Pumping water up a hill using solar and harvesting the kinetic energy has been proposed numerous times but it's a matter of social will to build the infrastructure to support such projects. Imagine if we built massive offshore tanks to pump sea water into and released them overnight. Inland areas would need a different solution if they didn't want to modify the landscape too much, but I think we can find a balance between traditional batteries and natural "batteries".
Onshore wind is cheaper than coal, gas or nuclear energy when the costs of ‘external’ factors like air quality, human toxicity and climate change are taken into account, according to an EU analysis (in 2014).
The report says that for every megawatt hour (MW/h) of electricity generated, onshore wind costs roughly €105 (£83) per MW/h, compared to gas and coal which can cost up to around €164 and €233 per MW/h, respectively.
Nuclear power, offshore wind and solar energy are all comparably inexpensive generators, at roughly €125 per MW/h."
The though that in 10 years time the whole country will completely switch energy source to new renewable sources that haven't even been built yet is a joke.
Hmmmm, so I work in renewables, and while I don't work in the Australian market, I would like to take issue with your assumption that a massive transition to renewables in 10 years is a joke.
If you look at most utility procurement plans, the vast majority are renewables, and prices are only getting cheaper. They are getting so cheap that new solar and wind are starting to beat currently running coal. Also, beating existing gas on price is expected within 5 years.
So the current behavior in the industry is that utilities are starting to close existing coal power plants and are expected to close existing gas power plants well before their lifespan is up simply because it's cheaper.
Hi! Yes I agree its entirely possible that renewables will make a big impact and that should be encouraged. I'm sure in Australia with enough backing they could get to 30% or even 50%.
I'm sure you realize though that even 80% renewables has some huge challenges with storage. Its hard to guarantee power will always be there. There are a lot of hot nights with no wind.
Combined with Australia having some of the cheapest coal in the world, such headlines are just click bait.
I think it will happen in Australia by overbuilding solar. Solar at utility scale is now regularly getting below 2c/kWh globally, retail electricity in Australia is 30c/kWh, we’ll probably just end up building twice as much as is necessary, then seasonal changes won’t matter.
Renewable energy will grow for sure, but every national survey in the US and every international survey of energy use definitively shows renewable won't be anywhere near majority anytime soon.
It's unrealistic to think that a national energy source is going to change drastically in such a short period of time. 10 years isn't that long of a time period.
At best you are ignorant of the real costs of renewables. The only way you (and that Forbes writer) can come to your cost conclusions is to ignore the intermittent nature of renewables, but then you no longer have a 24x7 power grid.
Ok, I was a bit too blunt there, but the fact remains that presenting the marginal generation capacity cost of solar or wind as the total cost to deliver that capacity in a 24x7 system is simply wrong.
If the cost for the next wind turbine or solar farm was just $1 it would be wrong to assume that your incremental energy cost is now just $1. You still have to build the coal/gas/nuclear plant to generate power when that turbine or farm is generating 0 energy. And because power from solar and wind can start and stop at any time you have to keep your other base load plants fired up and ready to go at any time.
> If the cost for the next wind turbine or solar farm was just $1 it would be wrong to assume that your incremental energy cost is now just $1. You still have to build the coal/gas/nuclear plant to generate power when that turbine or farm is generating 0 energy.
Only if you are starting from scratch. When adding a wind turbine or solar farm to an existing system, the incremental energy cost can even be negative, if adding the new generator means you can run your thermal power plants for less time or with less power (using less fuel and reducing wear on the mechanical parts).
> And because power from solar and wind can start and stop at any time you have to keep your other base load plants fired up and ready to go at any time.
"Start and stop at any time" is an exaggeration. Both solar irradiation and wind speed are predictable in the short term, so these backup power plants only have to be ready when a power shortage is predicted.
Cost. That was it. The project in Spain was significantly cheaper to build and was only a 50kw tower. The EnviroMission tower was going to be 200 MW facility. The benefits of the solar updraft tower are huge: Able to be built using readily available materials (concrete, glass, etc.) If a terrorist blows it up, just build another one. Tremendous tourism potential. The skirt/greenhouse could grow crops making the air denser and more efficient, and with a LOT of open land Australia would've been the perfect choice. Unfortunately it just came down to building cost.
reneweconomy.com.au is close to tabloid quality; the odds are good that they will correctly report the blindingly obvious but questionable otherwise. They are a few bars above an actual tabloid, I suppose, because at least they aren't trying to run human interest stories.
They push a pleasant barrow in that it will be nice if renewable are the economically best option now; but that site is the last place to look if you want evidence that it is happening.
No doubt yet another article about renewables which ignores the fact that nameplate capacity is not at all the same as average actual capacity. To wit, average actual capacity is often only about 1/4 of nameplate capacity. So take any power generation numbers quoted here and divide by four and you are probably much closer to the actual truth of the situation.
When you measure it in MW (i.e. how much power it can generate _per second_) the important variable is for _how long_ you can do it - getting you back to simply using MWh.
The Australian Energy Market Operator (AEMO) manages the electricity grid to which the Tesla battery connects and AEMO is reporting the battery works very well at helping them manage that grid.
It provides enough power to run he state for 6 minutes or so [0] [1]. Useful for peak lopping, but if batteries would be used to store renewables the bills would be about 20 times higher than they are now and Australia already has some of the most expensive power in the first world. South Australia is the most unhealthy energy market in the developed world, and several developing countries would be embarrassed by it.
Thats a touch disingenuous. It was never meant to power the whole of South Australia. It was specifically built to mitigate the peak power price gouging [0] that had been happening the for prior 10 years.
The 6 minutes it can run for during each cycle saves millions of dollars a year. Specifically 40mil in the first year. The cost of the unit was 66 Mil [1], so thats an insane break even time for grid infrastructure.
It provides enough power to run he state for 6 minutes or so
Powering an entire state for 6 minutes is massive. That's not what it's designed for, however. From what I've read it's designed to be a 'smoother' in times when the power system is under duress.
South Australia is the most unhealthy energy market in the developed world
I think you mean all of Australia. The market is severely gamed by primarily the gas generators at times when members of the aging coal fleet trip during either the night or when there's little wind, and so gas is left as the saviour. There have been times that gas generators have intentionally left turbines switched off so that the electricity from the operating turbines is of more value, as well as ignoring advice of the Market Operator to have generators 'ready to fire up' due to predicted dips in generation from the rest of the market.
The current government believe in 'the free market', which would ideologically allow gaming of the system by the few participants who can jump in at times of need. However, this is what's a significant part of the cause of power prices in Australia being some of the highest in the world, and thus resulting in some people not being able to afford their bills.
Imagine, in 2019, having to go back to candles? What an age we live in. A government at the helm when people were having to go back to reading stories by candle-light might have some multi-generational difficulty repairing their reputation. So they've been feebly attempting to bring the generators to heel. With little success.
(There's also a lot of validity in the arguments about poor building regulation resulting in poorly- and un-insulated homes where electricity is used to fill comfort void whether for heating or cooling or both. New housing estates in Australia are a series of snug-fit cardboard boxes with pitched roofs)
> The current government believe in 'the free market'
Good that you put that in quotes, because of course they don't really. They are crony capitalists at best. They killed a decent free-market approach to climate change (Emissions Trading Scheme) in favour of more subsidies (Renewable Energy Target).
> New housing estates in Australia are a series of snug-fit cardboard boxes with pitched roofs)
It breaks my heart when i drive past them. Ugly boxes with no attempt to match the environment. They fill up the whole block almost, leaving hardly any space for a garden. No verandahs, tiny eaves, small windows, hardly any trees. Horrible things.
> They fill up the whole block almost, leaving hardly any space for a garden.
You're welcome to live in a tiny house on an otherwise empty block if you prefer. Me, I like to have room inside my house where it's nice and air conditioned.
Or are you saying people should just be rich and be able to afford nice big houses on even bigger blocks of land (but still within a reasonable commute time of the city)?
It's there, quietly doing its job and covering surges in demand so that hugely expensive gas fired turbines don't have to be spun up. It's saved some stupid amount of money so far.
It is also under cutting the price that gas fired power stations need to be profitable. Since South Australia doesn't have coal or nuclear baseline generation any more we may see what happens when a state goes 100% renewable pretty soon.
The answer on the few hot days this year has been "plunging neighboring states into blackouts".
under cutting the price that gas fired power stations need to be profitable.
That sounds like a gas fired power stations problem, not a battery problem. In fact, it sounds like a good economic argument for the battery, and for more of them.
The answer on the few hot days this year has been "plunging neighboring states into blackouts".
Can you please point to some evidence of this? It doesn't sound like a logical progression to me. If South Australian's power situation was to cause black outs in New South Wales or Victoria, there would be a million fantastic articles about it.
I don't know what 'the rules' are, but I doubt Australia's two most populous states would be too excited about agreeing to rules that would cause SA's power to be maintained at the expense of theirs.
I'm also pretty sure that in 2018 SA was a net exporter of power to the East (that's a different metric, but somewhat related).
The Tesla batteries installed in South Australia are not used for keeping the city running just with solar, they are there to optimize the load and routing of energy through the entire region, to avoid outages when during sudden spikes of electricity usage.
I wondered what that "got" meant in this headline, the actual headline is a bit more clear "Australia has enough solar, wind storage in pipeline to go 100% renewables"
You either have to build more efficient buildings or retrofit existing buildings. Most home/office energy expenditure is on heating/cooling/fridging/hot showers. Only 10% is based on lighting [1].
The best way to tackle cooling/heating is by improving insulation, but unfortunately, there is little ability/reason to. Those that would get the most utility out of it are poor and therefore cannot afford it. Those who can afford it are rich, and therefore don't care about a few dollars lost to heating/cooling the outside air. Even if the rich do care, it often isn't worth the emotional/mental hassle of having massive construction done to your abode.
Depends where you are… in the UK domestic electricity consumption fell by 2.4% between 2016 and 2017 due to increased efficiency lighting / appliance efficiency [1]
There was a noticeable decrease in our personal electricity consumption when we switched to LED bulbs (our heating and hot water are gas)
Sounds nice but the reality is that demand for energy consistently grows faster than our ability to conserve energy. The challenge that is being met with the deployment of clean energy technologies is meeting that demand in a sustainable way. It's a good thing; cheap clean energy unlocks economic growth. Instead of strangling ambition, we need to empower it. The more clean energy we consume, the better. This needs to be a growth market and it is.
You can bicker over the timelines when coal is switched off permanently and lots of people seem to argue that the timeline in this article is a bit optimistic but the reality is that there's lot of growth in this sector with year on year increases in deployed capacity, price drops, etc.
I get really frustrated with politics surrounding fossil fuels vs. renewables. I feel like renewables are the future, will add a valuable skillset, and are very achievable.
But then it feels like we have a significant number of politicians who won't push for renewables because they are holding onto this "climate change is a myth" narrative, and are getting money from fossil fuels.
Politicians don't push for renewables because it doesn't get them any points with their constituencies. You can point to energy lobbyists as a reason for this, but it isn't necessary to do so. You can just ask the average citizen- "how much do you care?" and the answer is low to not at all (ignore the polls, look at their actual actions and behaviors).
Iirc, she also has or had quite a bit invested in Australia’s media.
How would I find out which companies are invested in the media and the cross over between it and mining companies? That would be something I want to read.
I’m not saying that they uses that to influence public opinion. But I do worry that it could be that way. The media here loves going on about the ‘baseload’. What ever that means.
I don't understand why so many people insist on using fossils.
On the one hand, "the west" is hating on Russia and the middle east for whatever reasons, on the other hand, they pour money into them like there is no tomorrow.
Who is "so many people"? From my view, 95% of the people I know (in a very liberal area, btw) don't consider their carbon footprint at all. They don't want to give up cheeseburgers, fancy cars (aka 2 ton wheelchairs), or living in their specific way. The idea that I want to bike to work, for health and emissions, is met with: "Wow, you're taking your life into your hands whenever you don't drive a car".
It won't and it can't. Rather it can at the cost of ~20 trillion dollars (23GWh [1] at 900 million [0] for GWh for the Tesla battery).
You need all that energy storage for when it's not sunny (like at night) and not windy and when you're in the middle of a decade long drought [2]. All things Australia is likely to get in the next 15 years.
If you want power without CO2 you either go nuclear or you expect 90% of your grid to go offline about monthly.
> It won't and it can't. Rather it can at the cost of ~20 trillion dollars (23GWh [1] at 900 million [0] for GWh for the Tesla battery).
Sorry, this statement is incomplete and as a result, leads to an incorrect conclusion.
Tesla (and other Li-ion batteries) are suitable for certain applications (e.g., powering cars, power tools, phones), but bulk energy storage is not one of them. Saying you want to store grid-scale power with tesla batteries is analogous to saying you want to replace the lights in a football stadium with thousands of mobile phone screens. You can do it, but screens are good at displaying image content to single users and not meant for general illumination, and would cost prohibitive from an acquisition standpoint not to mention the ancillary cost issues (e.g. lifetime, replacement).
All you need to do is find an energy storage technology that is appropriate, and the solution suddenly becomes viable. Molten Salt storage, for example, is 33 times cheaper than Li-ion storage. Other much more appropruate mass energy storage options includes H2 production, or 'simply' pumping water upstream of a hydroelectric plant.
At night demand is lower, so even ignoring all the storage technologies aside from expensive batteries, there are things like gas power plants, who can start and stop quickly and likely provide the needed energy. And at daytime ... you do have sun in australia, not like here in germany.
And a few more PHES (water reservoir pump storage) probably come in handy with drought anyway
1). The number is the current demand, it's 12am here.
2). Australia is larger than the EU. That there's sunshine in North Queensland is all well and good but you need power in Victoria and South Australia. The links between the states are already saturated (and absolutely tiny).
3). Can you name me one river in Australia that isn't already damed passed the point of viability? The Murry-Darling flows backwards about as often as forwards these days.
The idea is not, that you can go all renewable by tomorrow, but that you can work towards it.
So yes, you probably will have to invest in the energy grid.
And the lack of suitable rivers is a problem for conventional pump power plants, but there are concepts to do the same with artifical lakes on different heights.
Then there is hydrogen.
Energy costly to create, but the idea is, that solar energy is dirt cheap, once you have the plants.
And a tons of other potential technology.
So again, yes. Not really all market ready and exactly doable by tomorrow, but will be soon.
Sooner the more it gets invested into it, because there are no laws of physics hindering it.
Only lack of momentum due to the lazyness because of cheap fossil energy for "free"
Be aware that many current policies in Australia and vested interests are actively AGAINST further development of renewables. So all of this is actually IN SPITE of the regulatory environment, rather than because of it.
It will be interesting to see how prices move given all this new volume that will be coming online in the next decade.
Note for the curious: The reason the above is even possible is because solar and energy storage prices follow the same kind of principles / learning curve behind the proliferation of the microchip and Moore's law. While the curve and "speed" of cost reductions for renewables are no-where near as fast as MicroChips, I can only hope that this trend continues. See: https://en.wikipedia.org/wiki/Swanson%27s_law