I’ve never understood carbon capture and storage. I never went past high school and that was about 50 years ago. But I still remember the key principles behind why perpetual motion will never be a thing.
Unless there is an energy producing reaction that binds CO2 or separates the carbon from the oxygen without producing nasty byproducts, carbon capture and storage cannot work without pouring more energy into the project than what we gained from the release of the CO2.
Just imagine what anything else looks like. For every fossil fueled power plant that has ever existed, we need to build at least one larger non-carbon plant to power the capture and storage. There are several ways to reduce the fraction of our power that goes into capture and storage:
- Take more time to remove than it took to add
- Remove less than we added
- Find a less energy intensive method of binding the CO2 (that is we don’t need to turn the CO2 back into a fuel; is creating calcium carbonate an option?)
But no matter how you slice it, removing enough quickly enough will still require a large fraction of our power generation capacity.
The initiatives cannot be anything other than a shell game designed to hide the underlying perpetual motion machine.
Theoretically carbon capture can work, but just like you said, it takes additional energy to capture carbon, and that amount is more than what it takes to produce the needed electricity if you’re using a carbon based energy source.
That said, if you go for something like nuclear, than you do get a clean source of energy that can be used to capture existing carbon. But we’re already at the point where our energy infrastructure is inadequate for just electrifying what we currently have, and in a few years the Pickering plant is going to have to shut down due to being so old (though apparently the government is trying to delay it as there’s no plans for building a new plant of any sort to replace the Pickering plant).
So even in the best case scenario, it’ll be more than a decade before any sort of large scale carbon capture scheme can even be started, as that’s how long it’ll take to build enough new plants to cover existing demand, let alone accounting for future demand.
I should have clarified that I know it can work, but not as the perpetual motion kind of system most people seem to envisage or that most projects I’m aware of seem to promote.
Everyone seems to think that carbon capture can be this little add-on when it actually needs to be a bare minimum of 1/3 our total energy production to have a meaningful impact over typical human time scales (a century or 2). Making things more complicated, none of that carbon capture energy can come from carbon fuels. I just don’t see how we can do both at the same time, except as research projects to set the stage for when have gone a lot further in decarbonising our production for consumption.
I hate the term clean energy for nuclear ! It is not clean energy ! Where do you put the waste ? If it’s so clean I guess you dont mind if we use YOUR backyard to put the waste ?
The don’t ever say clean anything ever again.
Manufacturing ANYTHING generates waste. By this logic nothing is clean.
Dig a big enough hole, build a proper structure for containing it, and implement the proper containment procedures and sure, my backyard is fine.
Yes, a few tons of high level nuclear waste from every reactor ever made each year is comparable to covering an entire farm for old windmill blades and burnt out solar panels aren’t comparable. Especially since nuclear waste can easily be recycled into new fuel while supposed “green energy” waste can’t.
You need to see it as removing the carbon generated by industries that can’t be powered by clean energy, not removing carbon generated by polluting electric facilities.
Ship transportation will probably never be converted to battery power, so running wind farms just to remove the equivalent quantity of carbon released by ships from the atmosphere is a net positive.
Fair enough, but that strikes me as picking away at the edges of the problem. Maritime shipping represents about 3% of the total.. If research projects can offset that in ways that can be scaled up when we’re ready, then that’s great. But offsetting 3% here and 3% there doesn’t accomplish much when net negative is where we need to be.
We need those projects and we need to describe their results in terms that garner and maintain support. That doesn’t mean we should be diverting more than a few percent of our green energy to capture and storage at the expense of rolling out non-carbon energy production and eliminating carbon-based heating (and personal transportation?).
Trees are a lot slower at sequestration than most people think. They are also don’t provide long-term sequestration, because they burn or rot somewhere along the line. Given that most existing forests are on land otherwise unsuitable for agriculture, every extra tree we plant takes cropland out of circulation. Without a way to take biomass out of the carbon cycle, it will never be more than carbon neutral.
The goal with trees is to grow them and not wait for them to rot, but instead use them as building material where the carbon they captured can be “frozen in place” for potentially hundreds of years and replant new trees in their place.
Places that produce electricity via polluting means shouldn’t be investing in carbon capture but instead trying to make that production green to begin with, but places like Quebec where all electricity comes from renewables should invest in it to cancel the use of non renewables in other fields.
Okay, those tactics seem sound.
On the subject of wood specifically, I’ve read a few articles in the last decade or so about techniques for treating and using wood in ways that have the potential to dramatically reduce our use of concrete. Given the carbon footprint of cement, that seems like a positive development.
What? Green hydrogen seems very likely as an alternative for shipping.
I think air/spacecraft are the harder problems to solve.
Green Hydrogen doesn’t involve carbon capture. It’s sourced from clean energy in the first place. I hope we do see it produce fuel cells that can be used for shipping.
It’s unfortunately “Blue” or “Grey” Hydrogen that the fossil fuel purveyors are pushing to make themselves look like they care about the environment, though. Non-green versions do involve inefficient attempts at carbon capture. If you see someone talking about carbons and hydrogen, they’re not talking about Green Hydrogen.
Yes it doesn’t involve carbon capture, I was just replying to the comment that shipping needs carbon capture because of the fuel it uses. You don’t need carbon capture if you change the fuel source which is entirely feasible for shipping.
The problem with hydrogen is its volatility, explosivity and transportability. In gaseous form it tries to escape from everywhere, when it leaks it can lead to big explosions, to transport it you need to keep it in liquid form which requires spending a whole lot of energy to keep it in that form or it needs to be at extreme pressure and, well, see number one.
In liquid form it also has less potential energy by volume than petrol, which means that for the same distance you need to use more space for fuel and less for actual cargo OR you need to fill up more often but then good luck making sure everywhere you fill up it’s clean energy that’s used to produce it.
Hydrogen is problematic, but all the points you’ve made are just typical disinformation on the matter.
First of all, hydrogen tanks don’t explode. Even if you set fire on them, they’ll simply leak and that leak will burn like a pressurized flame until the tank empties. Second, you can’t really transport hydrogen in liquid form, as the boiling temperature for it is far too low (33K). They’re always transported in gaseous form right now under high pressure, which is worse I’ll admit. The energy needed to pressurize hydrogen though, isn’t that much worse than LNG, since natural gas suffers all the same limitations as hydrogen as you’ve proposed.
In addition, the appeal of hydrogen isn’t the energy potential per volume of fuel, but that it is quick to fill a tank compared to charging a battery.
The real downsides of hydrogen is that it is so small, it gets in between the molecules that make up any tank, making them brittle over time. Hydrogen tanks simply don’t last very long, and are expensive to make if you have to replace them yearly. In addition, we haven’t discovered a way to produce hydrogen at an economic level yet. The energy required to produce hydrogen far too high as it is, putting it at something like 20% or so.
Thus, the downsides of hydrogen isn’t safety, but simply that it’s very expensive from making it all the way to storing it.
But in this discussion we’re talking about using it for cargo ships specifically… That means hydrogen tanks in an enclosed environment if an accident ever happens and compressed it has even less energy by volume.
The volume doesn’t matter. Hydrogen can’t ignite without the presence of oxygen in the first place, and there isn’t any inside the tank. A new fully pressurized hydrogen tank is no more dangerous than a propane or natural gas tank. And we already ship natural gas in this state on specialized container ships.
Depends on how you do the capture. If you need to engineer the system and feed it energy in a form that we can instead use to power other stuff, then yeah, it doesn’t make sense. But if you for example, plant a tree, then that tree would use energy from the sun that you wouldn’t otherwise be able to use as easily.
The carbon captured by the tree will be released when it eventually rots or burns. That’s why it’s called the “carbon cycle”.
If you want to reduce carbon in our atmosphere, you need to capture and store that carbon in a way that won’t be released again for thousands of years or more.
It’s a delaying tactic to try and slow the coming effects while we get a better idea.
I’m not sure how it works as a delaying tactic when the energy requirements of anything meaningful just delay migrating our grid, heating, and transportation off of fossil fuels.
By all means, divert some our energy into research projects, but I don’t think we can expect to be in a position to do meaningful capture and storage for 2 or 3 decades.
This is the best summary I could come up with:
Kao and his team will be monitoring earthquake activity from underground carbon storage facilities over five years, studying the possible effects of the injections and analyzing what can be done to mitigate or eliminate those risks.
“This is an important issue because if the induced earthquakes happen to be a significant one that actually becomes large enough for the local communities to feel it or even have some damage … then the regulatory agencies will have to shut the injection operation down.”
Earthquakes caused by injecting a liquid underground — also known as induced seismicity — have been well documented in the U.S. and Canada when it comes to fracking and wastewater disposal, including by Kao in B.C.
If a major earthquake ruptures through cap rock atop of a carbon storage area, it could create a pathway for injected CO2 to escape, he said.
Erik Nickel is the chief operating officer of the Petroleum Technology Research Centre, which oversees the Aquistore carbon storage facility in Estevan, Sask.
“It would make a lot of sense to include us in there because of our history of not really having much seismic activity,” Nickel said, adding the site sits on flatlands and is not near the boundary of tectonic plates.
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Stop making mimes nervious.
