Honest question: doesn't the production of battery and photovoltaic cells require quite an investment of rare elements and significant carbon emission?
Photovoltaic panels take around 1/30 of the energy they provide to build (that number is constantly going down). So if you replace all of our energy production in one go, it will take about 1 year of pollution to create them.
What is obviously a crazy idea that will never happen in practice. On the real world, the panels are produced more slowly, and are replacing the most polluting energy sources first.
(Batteries, by their turn, do not need as much energy to create.)
I imagine OP means the mining and production of batteries at grid and transportation scale will require an enormous amount of energy expenditure and resources.
By the time much storage is being built, renewable power will be the cheapest choice, by far. So, you are worried that somebody up the line will choose to use expensive fossil-generated power instead of cheap renewable power.
Just by preferring the cheaper product, you bias your choice toward being made with renewables. It is not a guarantee, but in aggregate it is good enough.
It did, but it does not any longer. Lifecycle estimates vary from 5x worse than nuclear to 50x better for solar and 5x worse to 5x better for wind.
At 30c/W, even if the only activity required to make a solar panel were dumping anthracite on the ground as you mine it and setting fire to it you would still get more energy per kg of CO2 than gas.
The raw materials are sand, are copper and silver for current PV tech with trace amounts (milligrams per kw) or dopants. The amount of silver per panel is decreasing faster than the rate of panel production is increasing. Copper is mainly for wiring up and can be exchanged for aluminium if scarcity and thus cost is an issue, and inverters require substantial amounts of exotic materials (but less per capita than a phone or laptop).
A nuclear reactor requires more steel than PV requires silicon, and commensurable amounts of exotic materials.
Wind turbines require about the same amount of steel as nuclear but substantially more concrete.
A gram or so of silver per kW is the rarest component of PVs, and the total ammount of (recyclable) silver per year the PV industry uses is going down even as production increases. The copper is less than a commensurable amount of steam generation. Silicon refining energy is a hundredth or so of output and declining rapidly steel in a nuclear reactor outmasses the silicon and has a lower but rapidly closing energy requirement. Frames can be aluminium or even wood. The glass outmasses steel in a nuclear reactor, but not concrete, and has a lower carbon footprint than concrete and is reusable.
Wind uses copper and niobium, neither of which are essential to the concept. The copper is currently more than steam generation, but some can and is being swapped for abundant aluminium. Magnet free stators are being worked on extensively and are close to cost competitive. Steel use of the largest turbines is competitive with nuclear so iron alloying materials are a wash.
Nuclear uses zirconium, uranium, cadmium, silver, and a variety of other exotic elements as well as the copper for the steam turbines. It is difficult to find out how much, but back of the envelope (0.1% of the fuel assembly being control rod so 0.2g/GJ) would indicate it's more constrained by silver and cadmium than PV is by silver. Plus it is high level waste at end of life and you need it all up front.
The only question is whether the concrete in wind is worth the CO2 as this is the only resource where nuclear wins.
My guess is he's talking about Lithium and if so that's not concern trolling, Lithium mining is very expensive and if we want to go full renewable we'll need some major storage capacity. There's obviously ways around that, hydro storage being the most obvious, but it is something to think about.
The question was too vague to guess what it was about, if anything. It presupposes there is some resource used for renewables that is scarce and for which there is no viable substitute. Without identifying any, it is just trolling: there must be trouble somewhere, what can you come up with for me to carp about?
Lithium is about electric cars, not about renewable energy production.
To the popular imagination, it is easy to make a popular misconception linking renewable energy to rare earth minerals, because for good or for ill electric cars are a dominant facet of green technology. There is a not uncommon narrative that "electric cars are actually bad for the environment because they require scarce metals." News stories abound.
Rude pedantic ill-tempered dismissals of conversation as "carping" discredit a good cause more than a thousand fusion startups do. Perhaps if you want to win hearts and minds, engaging in both education and a little empathy would do wonders for your position. And to the betterment of the discourse hereabouts.
"Rare-earth" metals, are not, in fact, scarce. Insisting otherwise is misinformed at best, or disingenuous in your case, because you have already been told otherwise.
No and no. Solar panels use a little bit of silver and more copper, and no rarer materials.
There are numerous battery chemistries. None competing for utility-scale use involve any rare materials or substantial carbon emission. Likely chemistries include iron/air, zinc/bromine, and manganese/calcium.
And the overwhelming majority of utility storage built will not be "batteries" at all. Compressed air, liquified air, synthetic ammonia, electrolysed hydrogen, pumped hydro, and buoyancy will probably all be used in various places. Just now, almost all is pumped hydro.
Most future storage will be constructed after the majority of energy produced is from renewable sources.
It's already solved insofar as a fission or fusion heated steam engines can be solved.
Pumped hydro and caes is scalable at lower prices than fission could achieve. DT fusion will be much lower power density with much more exotic materials and much higher maintenance burden.
It's just that renewables have to live in the real world where customers aren't strongarmed into paying $200/MWh for 50 years to pay for them to do whatever they want. As such work needs to be done to make solar/wind+storage economically dominate gas because governments are not powerful enough to make fossil fuels pay for their externalities.
Energy storage is a simple matter of civil engineering: a big job to construct enough, but requiring no new technology.
We are not building it now because it would be stupid to build storage there is no renewable capacity to charge up from. Money is overwhelmingly better spent today on renewable generating capacity.
By the time we need to build storage, it will be much cheaper than if built today.
Large scale storage is not cost effective with current tech. It is not just a civic engineering problem.
Solar power is very cheap, but a complete 24/7 solution requires batteries. Those are much more expensive than the panels. A better battery is all we need. Panels are good enough already.
The overwhelming majority of storage used will not be batteries, unless some new chemistry's cost is very low.
Large-scale storage will be very cheap, on par with panels. It really is just civil engineering. Any competent civil engineer can sketch a practical, cheap storage system using only century-old tech.
Hand-wringing over utility-scale storage amounts to concern trolling.
Not the person you're replying to but pumped hydro is the most primitive I know of.
Also: why must the highly variable renewables share the grid with highly variable demand, use them to make hydrogen (only when the sun is shining/wind is blowing), feed that into a totally separate power plant, simple to manage - if renewables really get cheap who cares if it's inefficient.
Hydrogen will be one storage medium, mostly stored underground where geology favors it. Tanked anhydrous ammonia will be common, with more ordered from tropical solar farms when local tankage runs low. Underground and underwater compressed air will also be common. Liquified air might be.
Not the OP but dams and resevoirs is what he is talking about, I assume. Pump water uphill while the sun is out, let it feed back downhill and generate power overnight. It is century old stuff and it is very much validated to work.
Once we solve the battery problem solar and wind become enough to power humanity.