The military coup in Niger has raised concerns about uranium mining in the country by the French group Orano, and the consequences for France's energy independence.
Batteries are great for short term storage (Hours to Days), but the further you are from the equator, the more you need seasonal storage.
Hydrogen possibly fits part of that, if it is produced by electrolysis when wind / solar are in surplus.
Problems are:
how to store it, it leaks through most storage containers, requires vast amounts of energy to liquify and
The round trip from Electricity via H2 to Electricity is very inefficient.
Natural gas has certainly increased the cost of grey hydrogen lately.
If the problem is the cost of electricity, that’s easily solved by producing mainly when there’s a surplus of green electricity. However, if the cost is the capital outlay, that’s harder. Which is it?
Of course, we can and must require by law that all new capacity be green. Current incentives also include blue, but there is more green hydrogen actually being built.
@MattMastodon@BrianSmith950@Ardubal@Pampa@AlexisFR@Wirrvogel@Sodis IIRC most studies show that long term storage is only a few percent of total energy, certainly well under 10%. So it is a viable option - if you can get past leaks, and other problems (e.g. the temptation to burn it, producing NOx pollution). And can store vast amounts of energy relatively cheaply.
Nuclear is of course a viable option. There are a few others e.g. iron-air batteries, or just building a lot more renewables than we need. Lithium is only helpful for short to medium term storage.
Re synthetic fuels, so far extremely expensive and limited scale. Might possibly be used for aviation in the long run (but it’s easier just to fly less, and we still need a reliable, safe solution to the contrails problem). Maybe shipping too (possibly as ammonia).
@MattMastodon@BrianSmith950@Ardubal@Pampa@AlexisFR@Wirrvogel@Sodis Here’s a study from a while back about how much storage is actually needed, using the example of Australia. You can get to ~98% with relatively little storage. For the remaining 2%, you need to think about more difficult options - demand side measures, nuclear, long term storage, etc.
In terms of filling in the gaps in #energy production we could do some fun maths. Imagine massive #renewable overcapacity and see what storage we need.
Just move the yellow and green lines up x3. This is a typical summer week but we could also look at winter months (less #solar more #wind?)
Also the study I posted about Australia. There was another one but I lost it on Twitter. You can get *most* of the way with a few *hours* storage, not weeks.
On the other hand if you try to reach 100% with minimal demand side interventions even in emergencies, you end up building way more (~3x) renewables than you ideally need. Which has a cost - rare earths etc.
But there are plenty of options for managing intermittency. All of them have problems or costs though. Which is one reason I’m not strongly opposed to nuclear, for instance, but nor am I terribly enthusiastic about its ability to deliver quickly enough.
@MattMastodon @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis
Batteries are great for short term storage (Hours to Days), but the further you are from the equator, the more you need seasonal storage.
Hydrogen possibly fits part of that, if it is produced by electrolysis when wind / solar are in surplus.
Problems are:
how to store it, it leaks through most storage containers, requires vast amounts of energy to liquify and
The round trip from Electricity via H2 to Electricity is very inefficient.
@MattMastodon @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis
A thought,
I wouldn’t completely write methane, LPG , or any other petrochemical, off yet, as a seasonal storage medium.
They are a lot easier to store and transport than H2.
They can be produced from green H2 + captured CO2
https://en.wikipedia.org/wiki/Methanation
We have a lot of existing infrastructure which can use them.
That is of course If we can produce enough surplus Solar / Wind to make them.
https://www.power-technology.com/features/eth-zurich-fuel-air-and-sunlight/
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@MattMastodon @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis There seems to be a lot of uncertainty around the cost of green hydrogen. The first three Google links differ wildly on it.
Natural gas has certainly increased the cost of grey hydrogen lately.
If the problem is the cost of electricity, that’s easily solved by producing mainly when there’s a surplus of green electricity. However, if the cost is the capital outlay, that’s harder. Which is it?
Of course, we can and must require by law that all new capacity be green. Current incentives also include blue, but there is more green hydrogen actually being built.
@MattMastodon @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis The problem with using it for long term electricity storage is leaks, of course. It’s a weak greenhouse gas.
https://www.theguardian.com/environment/2022/jun/17/pollutionwatch-hydrogen-power-climate-leaks
@MattMastodon @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis IIRC most studies show that long term storage is only a few percent of total energy, certainly well under 10%. So it is a viable option - if you can get past leaks, and other problems (e.g. the temptation to burn it, producing NOx pollution). And can store vast amounts of energy relatively cheaply.
Nuclear is of course a viable option. There are a few others e.g. iron-air batteries, or just building a lot more renewables than we need. Lithium is only helpful for short to medium term storage.
Re synthetic fuels, so far extremely expensive and limited scale. Might possibly be used for aviation in the long run (but it’s easier just to fly less, and we still need a reliable, safe solution to the contrails problem). Maybe shipping too (possibly as ammonia).
@MattMastodon @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis Here’s a study from a while back about how much storage is actually needed, using the example of Australia. You can get to ~98% with relatively little storage. For the remaining 2%, you need to think about more difficult options - demand side measures, nuclear, long term storage, etc.
https://reneweconomy.com.au/a-near-100-per-cent-renewables-grid-is-well-within-reach-and-with-little-storage/
@matthewtoad43 @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis
In terms of filling in the gaps in #energy production we could do some fun maths. Imagine massive #renewable overcapacity and see what storage we need.
Just move the yellow and green lines up x3. This is a typical summer week but we could also look at winter months (less #solar more #wind?)
@MattMastodon @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis Well, California has done a lot of the work for you. Have a look at their charts, including multiple GW of battery storage.
Also the study I posted about Australia. There was another one but I lost it on Twitter. You can get *most* of the way with a few *hours* storage, not weeks.
@MattMastodon @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis What that means is if you’re going the long term storage / hydrogen or iron-air batteries route, the inefficiency doesn’t matter (but the capital cost does).
On the other hand if you try to reach 100% with minimal demand side interventions even in emergencies, you end up building way more (~3x) renewables than you ideally need. Which has a cost - rare earths etc.
But there are plenty of options for managing intermittency. All of them have problems or costs though. Which is one reason I’m not strongly opposed to nuclear, for instance, but nor am I terribly enthusiastic about its ability to deliver quickly enough.
@matthewtoad43 @MattMastodon @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis
Might be this one. (Haven’t found him directly on Mastodon yet)
Shows how we can get by in Australia with just 5 hours storage. Uses real time data.
https://bird.makeup/users/davidosmond8/statuses/1686581904823484416
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@MattMastodon @BrianSmith950 @Ardubal @Pampa @AlexisFR @Wirrvogel @Sodis There is commercial production of green hydrogen today, but it requires a subsidy. The cost of grey hydrogen does not reflect the damage it causes.