Carbon Dioxide Removal from our oceans. Can we achieve 20 BILLION tonnes per year?

"Are you going to clean that up?"
Applies to the whole world, really...

It would have been useful if the cost for this scheme was expressed in $/ton of CO2 sequestration. As it presented, I can't tell if this is a cheap or expensive way to approach this problem.

hol-up. 1.4 trillion for a world wide effect?
That's dirt cheap. The US, China, or the EU could do it unilaterally if they wanted.
If the price tag were to get split up internationally, This could definitely get done.

As part of this, I would highly recommend looking into GreenWave and the work Bren Smith is doing in growing a large community of small-scale farmers that carbon sequester via seaweed growth alongside mussels and oysters as a business model.

One simple thing we should all be repeating over and over is that warm oceans hold less carbon than cold ones. We accelerate return of our absorbed pollution by tolerating more warming.

The Netherlands, Holland, have been fighting the encroachment of the sea for many years. They have windmills for pumping water. More recently they have invested in electricity generating wind turbines.
It would be interesting to investigate if the calcium carbonate could be used to automatically build sea defences as it was being created.
I'm sure the Netherlands government would be interested in investigating the possibility of doing this if they have not already done so!

Thank you for putting this out there! I love this technique a lot, especially because you could produce carbon neutral cement with all that limestone.
By producing and selling the hydrogen and the cement, a plant could help offset its costs.

I've heard this one before.
Technologically possible solution. No mechanism in capitalism to incentivize it. No major government willing to go against the short-term interests of capital.

As always, no silver bullet. We don't necessarily need $2 trillion of these systems. They have to be part of a larger system of multiple approaches combined to achieve the same effect.

This general process has fascinated me for a while (its very similar to the Biorock/Seacrete/Electrified Reef system). The primary magnesium mineral product created is hydromagnesite, which is used in fire suppression systems. If there were a market for the minerals being generated by this capture process, it would go a long way toward spurring adoption. I just wrote an article about how you could use the mineral as a coating around magnesium powder as a way to safely use the metal as an energy carrier and hydrogen producer.

I am wondering if the carbon removed from ocean water in the process at the start of your story has any use as an agricultural input. Calcium carbonate Calcium bicarbonate ......apparently I need about 1 ton per ac on my 160ac patch of dirt. If it is the same or a like chemical compound there might be a commercial use for the stuff. Certainly a better use than just dropping it back into the oceans IMO
Sea weed/kelp is a wonderful fertilizer too.....and it seem so be cheaper and thus easier to start up/ramp up than building these plants to remove carbon from the oceans
At the end of the day yes we will need to work with nature. Sea weed/kelp might just be the natural way to go all the way around might as well make it a win [no trillion dollar cost] win [less inputs steel concrete copper etc etc] win a marketable product that will both help solve food insecurity as more and more of our agricultural zones are hit by drought

What about making building materials out of the solidified carbon end product? Then it could be sold, at least partly offsetting the cost of solidifying it.

Let’s do water capture, biological water capture and air capture.
If one of them is shown to be having unforeseen consequences, ramp up the other two.

I like this better than anything that keeps CO2 as a gas, that can leak out eventually. Also the infrastructure would be used even after we get to "net zero", to clean up the mess and reduce ocean's acidity. I don't think we would do it on such a massive scale though, it seems more logical to bet on 10 different things at a 10 times smaller scale each. But like was said in the video, what's really needed is to really invest in large scale prototypes to see if it works or not, even taking some degree of gamble in the process.

For me, the greatest challenge is the greed included int our economic model! As you mentionned it, if our governments announce the use of such methods, soon we would see some "Greenwashing" tempting to say that we all can continue to consume at the same rate!

_"Our Spaceship's about to crash!_
_"Look at the instruments. Data are clear!"_
_We need to deploy the parachute NOW!"_
- --"Ah, no. The button's all the way over there. And parachutes cost money. Think about the effects on our budget. Plus effort? Be sensible."
_"But the spaceship costs a LOT more money than a parachute! And we need to be alive to produce either!"_
---"Ah, but that only costs money in the FUTURE. Just sit tight. If it makes you feel better, we'll adopt a "concerned" outlook. Oh look, there's my house."
... This is a recurring feeling regarding climate change. A not-so Merry-Go-Round. I really hope people will start moving in an actual direction. We need to be building all of these, as prototypes, and see which one works.

Thanks for the informative video!
Wow, it really is a lot cheaper to avoid emitting a tonne of carbon, than to emit and then sequester it...
We *really* need international carbon pricing

Everyone: The problem with solving the climate crisis is financial.
The super rich: Yeah it sure is. Too bad about that.
Everyone: But like we could do it if we abolished the profit incentive, right? The materials and willpower are there, just not the money.
The super rich: Hey hey hey! Let's not get extremist here, it's not like the end of the world is the end of the world!

Assuming this technology becomes widely implemented, might it be worthwhile to transport the solid carbon to land areas, such as, but not necessarily limited to, deserts, in order to build up or restore some of these depleted soils so that plant life can once again gain a foothold and contribute to removing CO2 from the atmosphere? I'm thinking this solid carbon could be used in "Green Belt" initiatives around the world.

I just love Daveday, I mean Sunday's 👍😂 even after a devastating few days on a personal level, your video engages, educates and entertains me in such a way that just for that few moments, I can feel positive about mankind and the efforts of so many unheralded individuals, who are working away tirelessly trying to save our planet 👍😊👌Thank you for your positive weekly messages Dave and for your wonderful dry humour 😂 keep up the brilliant work my friend 👍😊👌

Seems that the best way is to simply stop burning stuff in the first place.

Thank you so much for you work! You give me a little bit of hope back with each video, in a mature, balanced way. There seems to be a way out, perhaps.

Thanks for the video!
I'm curious about how the chlorine could be removed and neutralised, it seams a big thing to me.

Ok, so, chemistry and all that again... Chemist here, having some notes. You correctly pointed out that by electrolysis of saltwater, chlorine would be produced, which is supposed to be absorbed by active carbon and removed from the process. Coating the anode would not change anything about that. So, besides the fact that this would hardly work to keep the chlorine bound for ever, I don't think you made any calculations about how many Active Carbon would be needed to do that. Because for each CO2 (from carbonic acid, H2CO3) to absorb, two hydrogens would be generated, and thus, one molecule of Chlorine (Cl2) would be formed. As Carbonate and Cl2 have _roughly_ the same mass, it means: To bind 20 billion tons of carbonate, you'd produce 20 billion tons of Chlorine gas (actually even more) per year, which has to be absorbed. And to do so with active carbon, this could easily add up to 100 billion tons or more of toxic waste. Where do you get that active carbon from? Coking wood and producing even more CO2? And where would you put all that toxic waste?
So, I think it's easy to see that this approach is not useful by any means. Except...
...yes, except there will be a way _not_ to produce Chlorine by the electrolysis, but Oxygen! This would need a very special anode material which maybe has yet to be developed. But without that, the electrolysis approach will end up in a bigger catastrophe than it is allegedly acting against.

Would this limestone rock be able to be used in making cement?? Maybe seaweeds and shellfish are a more sustainable and helpful approach?

So, carbon capture from the ocean can potentially be done cheaper than direct air capture, I always suspected this to be the case, now just need to figure out the best method to implement it without harming various aquatic ecosystems.
At the same time, I feel it is a bit naïve to believe that reducing overall energy expenditure by society is a genuine avenue that can realistically be pursued. Yes, there is room for gains in per capita efficiencies, but asking people to give up on amenities and restricting the developing world from access to standard comforts is not going to go over well. To truly transition off of oil I think it is likely that we would need to radically expand clean energy production to the point where it dwarfs that which we currently gain from geologically sourced oil and other hydrocarbons.

I always find your videos very interesting!
You mention cleaning up chlorine produced from electrolysis of seawater on an industrial scale.
I've had this idea for years but came up against the amount of chlorine produced when applying electrolysis to sea water.
My thoughts were, how can we convert into energy, the extreme pressures created at depth by water.
What I came up with was, electrolysis of water at depth would naturally produce gases under pressure.
If the oxygen component was allowed to expand as it reached the surface it would increase in volume and could be used to drive turbines to produce electricity which would be feed back down into the electrolysis process
If the energy required was greater than what the oxygen turbines could produce, this could be supplement by other green energy or even a proportion of the hydrogen produced from the electrolysis.
The result would be green hydrogen and if use at sea, chlorine, which would need to be processed.
I also wondered if this whole process could be tacked onto fresh water hydro projects, if they had sufficient fall and pressure. Which would eliminate the chlorine problem.
Keep up the excellent work, you are making a difference!

Thank you for this video! You cover the subject so well it's hard to find anything to talk about. ;)
It sounds wonderful. An industrial, _realistic_ way to remove huge amounts of CO2 from the ocean, and eventually the air as well. Unlike other methods of carbon sequestration this taps into a natural planetary cycle, so there's a place for the carbon to go where it won't immediately come back up again. I'm suspicious of carbon capture methods that try to stuff billions of tons of gas back into geologic formations - because that kind of storage gets less efficient the more you do it. As the CO2 concentration increases it will find or force open every small crack and come back to the surface. By contrast this single step carbon process locks the carbon into mineral form and sends the rocks tumbling to the bottom of the sea, where they can be slowly covered by sand and remain locked away for a future geologic era.
If it's purely an economic problem, surely we can solve that. The problem of course is that it didn't cost anything to emit all those greenhouse gases into the atmosphere for all those years, and we have to pay those costs now in the form of mitigation strategies. Our economic system isn't really set up for transactions where the costs come due a hundred years after the profits. But the money was there for Covid, like you said. And this is an even bigger problem. Surely some way can be found to find the funds, perhaps involving carbon taxes so we can control future emissions as well.

This method would cause a depletion of minerals in the ocean such as magnesium and calcium, which might affect sea life negatively. However, I'm not sure that the scale of the depletion would have a barely noticeable, moderate, or disastrous affect.
As with many of these proposals, we should consider doing *all* of the reasonably good ones, not just putting all of our eggs in one basket, and then praying for divine providence that the side affects on the ecosystem, economy, etc. are not too devasting... if we have a many-pronged approach, we can shut down those that are causing large problems, while still having other effective solutions operational.

Would be good to see an update on this based on some of the work Heimdall have been doing. Looks like they're estimating $450/ton of CO2 removal.

An advantage of the solid production is that it is easy for the bean counters to measure. An observable process also helps the multitudes who don't trust nature to do it's thing in private.

Please continue to investigate the incredible and almost infinite potential of soil to act as a carbon/CO2 sponge. ( Regenerative agriculture. )

Ok... I quote "It will consume more than 20PWh (T=10^15) of electricity". In 2018 world's electricity consumption was 22 315 TWh (T=10^12), there is a small gap of roughly 1000 between these 2 figures... It means that to implement this "solution" we need to increase the world electricity production by 1000... See where I'm going with this?

Why don't we use seaweed? It grows insanely quickly, it provides habitat for marine life, it can be harvested as food or fertilizer, it sucks out CO2 from the oceans to deacidify the oceans, and it pumps in oxygen into the sea.

Yeah, after that 3rd Working Group video you put out a couple of weeks ago Dave, anytime I hear R&D I immediately jump to thinking that wind and solar rollout should be the primary emphasis of financial investment.
I do think that climate change still requires a "silver buckshot" approach, but the majority project we should all be implementing, at least in terms of energy, is wind and solar installation, whether residential, commercial, or utility-wide.
I think the point about stacking this ocean scrubbing tech with water desalination plants makes things very financially feasible, compared to having exclusive facilities. Coastline is expensive, as many diverse interests act to make claim to that finite resource.
I also echo the worry about geoengineering and the prospect that IF and when we get CO2 emissions to Net Zero and work back the clock to pre-industrial levels, *we need to be very careful in not tipping the scales too far in the opposite direction by not emitting enough/capturing too much CO2 for what the global ecosystem needs.*
We need to reach a steady state equilibrium where CO2, and all other GHGs, are monitored, and develop protocols and policies for knowing when to engage emissions or capture technologies to counterbalance disturbances to the system.
Those protocols and policies are light-years away, relatively speaking, but we can't lose sight of the other side of the pendulum that we call climate change.

Absolutely spot-on take on this: Yes, we need CDR but must not use it as a reason to delay ramping down the use of combustion fuels. There is something poetic about sending carbon back to a geological store, that's where a lot of the CO2 in the air came from (coal).

Excellent. The concept can be expanded to include fission nuclear power to run it and adding ability to filter lithium, uranium, and so on from the sea water as it is processed.

Thank you. I have worked on CCS/U. I still didn't read the paper, but this technology sounds much better than all the other CCS/U methods I'm familiar with. However, only after a pilot plant is operating for a year or so, could we asses its practicality.

This is the most detailed and honest solution description I've seen so far. It is also the most realistic technical solution. As far as the cost goes, as long as we value our survival in monetary terms we cannot afford to survive. I suspect this one will get built at least in prototype and perhaps on a larger scale though maybe not until we stop worrying about the economic cost. Of course, you could compare its cost with the cost of not doing it and get a very reasonable ROI. This is definitely a keeper though I think more work needs to be done on the Chlorine and Hydrogen waste issue, and how to distribue the calcium carbonate so that it doesn't just accumulate in the extraction area. Imaging tons of this stuff just clogging up the intake pipes.

Maybe it's more circular economic to do carbon sequestration in the form of sargassum algae blooms increasing due to climate change. Only if we harvest the Sargassum Algae which has many uses such as animal feed (and as side effect reduces methane gas emissions from cattle)

Wonderful. Another high-tech, vast-cost, CO2 sequestration method that requires thousands more electric power plants to operate, while at the same time ignoring the most powerful sequestration engine on Earth that requires zero electric power: photosynthesis. It ignores the global train-wreck agricultural system that destroys natural carbon sequestration in organic matter in soil (roots and microbiota) and replaces it all with petrochemicals. It ignores the fact that regenerative agriculture is as productive as petrochemical agriculture yet requires far fewer inputs.
Do the brilliant high tech nerds pay any attention at all to the world around them?

What is the ecological impact of removing magnesium and calcium from the ocean?

So using the figures at the 8:09 time on the video, it would take about 2,200 kWh to convert 1 ton. 2,200 kWh will take a moderately efficient EV ~15,000km. Also 2,200 kWh equals the energy in 1.5 barrels of oil so the oil equivalent necessary to remove 10Gt of CO2 annually would be 15 billion barrels of oil.
The current worldwide oil production is ~ 35 billion barrels. Clearly there is no easy way to pull CO2 from the biosphere!

So the question is how many kWh are required to pull 1 ton of CO2 from the sea water?

Aquatic life does SO well in Carbonic Acid.

I imagine setting up this process on all existing oil rigs around the globe so as not to concentrate it on coasts. Decommissioning the rigs from drilling oil obviously as well 😋

Sadly, this UCLA idea actually makes ocean acidification worse. A single dissolved calcium ion ties up 2 carbon dioxide ions as dissolved calcium bicarbonate. When calcium carbonate it's precipitated, one of the carbonic acid molecules is left behind, thereby increasing the concentration of unassociated carbonic acid remaining in the seawater, reducing the buffering and making ocean acidification worse. A better solution is to actually fix the carbon biologically offshore and ensure that it sinks past 1,000 m depth at a high carbon to phosphorus ratio, thereby ensuring a net export of carbon to the abyssal ocean.

Random comment for channel interaction.

Prior to the Industrial Revolution, total atmospheric CO2 was stable at about 280 ppm. As of 2021, CO2 constitutes about 0.042% by volume of the atmosphere, (equal to 420 ppm) which corresponds to approximately 3'290 billion tonnes of CO2, containing approximately 896 billion tonnes of carbon. To remove the total excess CO2 emitted by humans currently in the atmosphere in the past 200 years, 2'190 billion tonnes, based on this mineralization method and the numbers the study provided (2 pWh per 1 gigatonne CO2), would require 4'390 petawatt-hours of zero-carbon energy.
To produce this much power, at current efficiencies based on a large PV power plant in Abu Dhabi built in 2020, would require a 60'000 gigawatt average output solar plant producing power 8 hours a day for 25 years, (175 pWh per year, 7 times greater than worldwide electricity production in 2020!). The total area of solar power would need to entirely cover 409'000km2, an area the size of California or Sweden; again, operating without interruption during daylight for 25 years. Even more eye-opening is calculating the area required to produce this enormous amount of energy in just a single calendar year: it would require a contiguous solar farm larger than the entire landmass of the United States, somehow at an average annual solar intensity equal to that of the Arabian Peninsula.
A 60'000 gigawatt output of solar PV is 70 times larger than the total installed capacity of solar PV on Earth as of 2021 (849 gigawatts). Again, this is JUST the power needed to run the mineralization plants, 24 hours a day for 25 years, to remove all excess human-emitted CO2 (from the ocean rather than the atmosphere). A solar farm at least 70 times larger than all solar currently installed on the planet.
Put simply, we would need total quantity of PV solar plants 26'700 times larger than the largest current single solar PV plant in the world (Bhadla Solar Park in India, 2.2GW).
These figures do not of course account for future CO2 emission or any other climate-change contributing substances e.g. methane.
That is one tall order.

It seems that humans have destroyed mangrove forests and kelp regions all over the world. Those would be the ideal areas to begin. Plus there is nothing wrong with a varied approach that uses multiple measures that would each only have a marginal effect. As times goes by consequences would be apparent and efforts could be dialed up or dialed down to fit the circumstances.

outrageous. Look what we have done to ourselves, we have pained ourselves into the corner and now have become desperate to find a solution that never existed. Well the ending is what it is THE END.

I always appreciate your videos because they provide interesting perspectives. But this time you have gotten it wrong.
There is a serious flaw in this argument: precipitation CaCO3 for seawater is actually releasing extra CO2. Ca++ + 2HCO3- = CaCO3 + H2O + CO2
My former post has obviously not been published because I had added a link to prove my point. So I will try again without using a link but only the content.
Let me also add that chlorine is not 'absorbed' by activated carbon but converted into acid (HCl) and CO2. That is not a win-win but lose-lose situation as the extra acid in large scale will reduce the pH sea water even more.
There is a common misconception:
Almost everyone seems to think that limestone deposition, which is a sink of oceanic bicarbonate, must also be a sink of atmospheric CO2, when in fact it is a source!
I cannot publish the link, but I can show your the text and anybody interested can find the original by googling for specific word combinations.
Ca++ + 2HCO3- = CaCO3 + H2O + CO2
This is an interesting point because limestone deposition is, along with volcanic outgassing, the major source of atmospheric CO2 on a geological time scale, while dissolution of limestone, along with weathering of aluminosilicate minerals, is the major sink. This is widely misunderstood by those not knowledgeable about the chemistry of the carbon cycle. Almost everyone seems to think that limestone deposition, which is a sink of oceanic bicarbonate, must also be a sink of atmospheric CO2, when in fact it is a source! This common error is due to the fact that bicarbonate is the major form of inorganic carbon in the ocean, and because the ocean is a pH-buffered chemical system. In effect for each molecule of bicarbonate precipitated as limestone one molecule is released as CO2 in order to maintain charge and pH balance. Therefore brucite formation at the expense of aragonite has a net effect of reducing the effects of ocean acidification caused by increased CO2 in the atmosphere.
However, to put this into perspective, about half of all the net limestone burial in the ocean used to take place in coral reefs (Milliman, 1993), at least back when coral reefs were healthy and growing, before global warming, new diseases, and pollution killed most of them. About an order of magnitude more limestone was formed by planktonic organisms, but almost all of that dissolves when their microscopic skeletons fall into deep water, where they dissolve because of the lower temperature, higher pressure, and the higher acidity of deep waters caused by decomposition of organic matter that is formed at the ocean surface by photosynthesis and falls to the deep sea where it is oxidized by decomposing organisms and bacteria. However, the rate at which we are now adding CO2 to the atmosphere from fossil fuel combustion is about 100 times greater than the natural sources from global limestone burial (Ware et al., 1991), indicating how greatly human pollution has overwhelmed natural sources. Consequently global ocean acidification caused by fossil fuel-caused CO2 buildup cannot be effectively countered by manipulating limestone deposition, unless fossil fuel CO2 sources are greatly reduced and a mechanism is developed to directly remove CO2 from the atmosphere. If allowed to build up in the atmosphere, fossil fuel CO2 will only be very slowly neutralized over hundreds of millennia to millions of years by dissolution of terrestrial limestone rocks on land and marine limestone sediments.

At one time they pondered spreading iron filings into the oceans to increase plankton which in turn absorbs CO2 if l remember correctly. Wonder what happened to that.

Another great video that. Is among your best. I am encourage by the UCLA work. Your reporting is importantly spreading the information to those who need some encores about Climate Charge. Thank You!!!

John Martin, 1988: "Give me half a tanker of iron, and I will give you an ice age."
This seems like a VERY expensive, highly technological solution to a problem algae might be able to solve for nearly free.
Adding iron to ocean ecosystems causes algae blooms, the algae absorbs CO2, dies, and sinks to the bottom (the same mechanism that makes limestone). The only real argument against trying iron is, "We don't know how long the carbon stays sequestered. It may not be permanent." So what? Iron is cheap - if we have to do it again in 300 years, fine.
Several years ago Greenpeace blockaded a ship in port to keep it from conducting a small-scale test. Why? Because they were afraid it would work.

Yet another example of “fossil fuel industry causes problem -> government needs to pay for it to get fixed”
The fossil fuel industry should be taxed for every penny these plants cost!

1500 MWh for 660 ton CO2 means ~440 gr CO2/kWh, which is similar to the emissions of a Gas power plant.
So basically the energy required by this technology for sequestration is the same that would emit the same amount of CO2 in a gas power plant, which is not too bad.

Have there been any considerations of using the sCS2 sequestered carbon products of limestone and magnesite as green(er) building materials? Could there be some financial offset in utilizing these products of the process instead of just sinking them to the ocean floor?

Ok... Slow down there... This is a remarkably dumb idea... If the earth is heating up, some of that heat ends up in the ocean. The solubility of CO2 in the ocean decreases as temperature increases. I don't think you could have it both ways, CO2 in the atmosphere causing catastrophic global warming and catastrophic CO2 levels in the water. Besides, can you demonstrate how much CO2 in the water is bad? What amount of CO2 is the right level? Carbon dioxide is used by the lowest trophic layers of the ocean food chain. If you screw up with that, you collapse the ocean biomes. By that measure, how much CO2 anywhere is good or bad? You certainly need SOME CO2 or the plants stop growing. That means all the vegetarians die. Now, I would be ok seeing as I eat vegetarians, especially the grass fed ones, so I would be ok for a while longer than most of you all, but I kinda like trees.

This is an interesting idea;however, there are a few concerns that I have not seen any discussion. If we take calcium (~400 ppm in seawater) and magnesium (~1200 ppm in seawater) , we will be removing a beneficial mix of minerals that are used by many marine animals and plants. We need to be careful not to create another problem. Also, many have suggested using the solids for concrete. Again this is an interesting idea; however, to make concrete, you take calcium carbonate, heat it up using natural gas to drive off, what for it, carbon dioxide. You have actually added more CO2 to the atmosphere. In addition, much of the solids generated would contain magnesium carbonate, which will affect the quality of the concrete to some degree.

You don't need to find money.
Monetarily Sovereign Nations that issue their own currencies (eg: US, Canada, Japan, China) create money simply by Federal Spending and destroy it by taxation.
#MMT

Thank you for an interesting video. I wonder what effect that process may have on the ocean's bicarbonate-borate buffering system that maintains ocean pH around 8.3 or so? It seems from nothing but a quick think that it would have a major effect on pH, at least in the locale of the plant where CO2 removal was taking place. And, then there is the resulting imbalance of ions in the outflow that may have adverse affects on both biotic and abiotic components. Also, I'm leery that activated charcoal would be up to the task of removing the significant amount of Cl that would be generated. Nonetheless, I'm encouraged that people are thinking about ways to sequester carbon. I only hope it happens sooner rather than never.

@Dave Borlace I don't know if you read all these, but I have done a load of research Ch I to desalination, reverse osmosis dialysis can remove about 25% of the cost of desalination via producing energy via the salinity differential of briny and non salty water... Adding a further 9% saving would lead to a 34% reduction on costs. Whether this can be done with renewable or SMR nuclear technology is only theory at this point.

Imagine if governments redirect the "defense" budgets to defending against global warming...

It's always good to just have a think! 😃

This is promising. Biological carbon capture seems good, but... We do have to remember decaying plants release Nitrogen, which kills fishes. So some of each then? Are we really in danger of removing too much C02?

I would say that expense doesn't matter as CO2 emissions are still rising at this time. No one seems to care about the cost of war and the emissions from all of the militaries in the world. I'm close to the end of my life so I'm just watching anymore. It is obvious that unless something like this ocean carbon capture isn't done we have maybe until 2040 and it'll be past the point of no return. Does anyone realize what that means? There will be no recovery possible as CO2 capture systems will lose their functions. Seems like stopping all wars and banning all militaries 'NOW" would be a start but what chance of that!

It's so encouraging to see research into such matters is being undertaken. This tech seems to make sense on many levels. Thanks JHAT for keeping us in the loop!!

Fascinating process, that reminds me of the process of geology relative to the calcium carbonate creature's de-acidifying the the ocean's in the cretaceous, over hundreds of million's of year's(and reminds one of the white cliff's of dover).i collect fossil sponges from the thames river in London,and not only do they exhibit calcitonin growth,but trace element's I believe came from volcanoes/ and land run off,that made the ocean's too acid.maybe there are other recombining of element's like nitrogen(from farming),or other chemical reactions with iron,or copper,nickel and tin industrie's that could also be "permanently laid down in rock

I wonder if the leftover limestone can also be used to help promote coral reef growth and general ecosystem rehabilitation

The first thing to do is reduce our carbon output and we're not really trying very hard. We should drive cars that weigh less and drag less, modern cars are very slippery but because they're huge they cause more drag overall. Add to that the fact they weigh at least twice as much as they did 40 years ago and even with the spectacular efficencies of modern engines they still use a lot of fuel and that means a lot of CO2. Vw built a diesel car years ago that would carry 2 people and do 300 miles per gallon but it was a short production run and therefore cost a fortune but could have been rolled out but everyone likes driving big tall vehicles..... I see the future in biological methods of carbon capture, let the sun do the work.

Very good video - gives me great hope (apart from the human race inevitably wrecking everything in their usual way because it's inconvenient to believe that climate change is real).

The problems wrought by technology on ecology are solved primarily by ecology not by more technology. The channel does short shrift to nature. So does news ad popular culture. And ecology is a devalued science.

This is an very win win situation...love it!
Knowing concrete industry is one of the CO² unfriendly industry's , and limestone can actualy been used for concrete production ☆♡
Grts from the netherlands
Johny geerts

Man made carbon capturing infrastructure won't be economically viable. We should try the biological method of algae, kelp , mangroves and good old trees on land.

For once, I can agree. CO2 removal (alongside with oxygenation of the oxygene deserts) is the most efficient way to slow down climate change and it's impact on marine life.

sadly, I suspect we will simply have to try it and see which method works best, otherwise by the time the computer models have figured it out, we may be well past the tipping point.

I would like to see all those ten's of trillions of dollars be directed toward individual people. Proper incentives would allow more people to implement electric vehicles, solar power and other renewables. This could help carbon capture become "personal" to many more millions of humans, and thus create a stronger "virtuous cycle".

Seawater and atmospheric carbon capture should still be last ditch efforts to mitigate the worst effects of global warming. I can't help but think that the money which would be spent on those methods would be better spent on a faster transition to green energy generation and storage solutions. At first glance, it does look like the seawater carbon capture might be preferable to atmospheric capture. In both cases though, it is a case of the cat (carbon) being already out of the bag (released into the environment).

This has far more legs than most of the Carbon Capture ideas suggested to date 👍

Sure you're scientists and not just ideologists? Are you referencing the algore hockey stick prediction? Critical thinking just a thing of the past?

What unsettles me about dumping CO2 as-is or as part of some more convoluted chemical lingo stuff is that it's not removing just the carbon but also oxygen... is that really a good idea? We're actively borking the chemical balance of the atmosphere by digging up and burning hydrocarbons, don't we need to get rid of Carbon and Hydrogen and KEEP the Oxygen for our air to remain friendly to human life?

Ok so marine organisms are already having a hard time fixing Calcium out of sea water for their shells so now they are talking about removing huge concentrations of Calcium along with the CO2. So how does this help those same marine organisms that we rely on for maintaining the ecosystems.

Great video.
A durable solution will likely not involve mass behavior change (“business as usual”) - unless the alternative is easier than what we do now. The only exception to this (that I can think of) is the ‘don’t litter’ campaigns in the 70s.
As an aside - It would be interesting (in future videos) if you did an in depth comparison to similar global problems where we’ve had success in reducing impacts. i.e. global food shortages, pollution of waterways…
All “non-individual-level” solutions (As you often point out) have a downside. Reducing CO2 production means nuclear power or human engineered geo-thermal wells or massive batteries (all with significant downsides). By contrast, individual behavior changes could, technically, have little to no downsides. The problem is, they are virtually impossible en masse.
To me behavior change is a losing argument. Any real solution will require industrial level efforts in energy production or CO2 capture and as little change to “business as usual” as practical. i.e. Jets will still use fossil fuels for the next 50+ years.
Thank you for all your hard/thought provoking work, your videos are fantastic!

I've been researching this electrolysis technology to grow coral frags faster - similar to BioRock

'It just requires the political will". There's a phrase that shows up the fundamental undemocratic nature of the world's political systems. If it represented the majority opinion of most countries' populations, the will would have been there 20 years ago.

It would be better to grow kelp and sequester CO2 from it, considering it is one of the fastest-growing plants in the world this seems like a better solution...

Thanks Dave. Another well explained presentation with a message that everybody needs to understand - and you are very good at making it unbderstandable

....always blessed by 'just have a think' info, you are a gifted presenter, thank you for sharing ...richard

Thank you

I like a lot about this process. But it's not perfect or complete -- note that the remaining *cleaned* water is also at a lower pH, meaning it is more acidic and less able to pull or hold additional CO2 from the atmosphere. The calcium or magnesium that were in the buffering solution have now precipitated. I believe this clever system also needs to be coupled with a way to provide additional Mg or Ca back into the ocean. Something like that done in Project Vesta, with their beautiful olivine beaches, or done by Greg Rau of Planetary tech, or even the alkaline output of the systems proposed by Ebb Carbon. These are all fascinating area for research. I wish you guys the best.

Interesting.. I wonder if the volume of byproduct is enough to help shore up some islands that are in danger of disappearing as sea levels rise. There is definitely areas of the world that could use this to build resiliency in their systems. Combined with things like electric reefs/biorock it might be enough of a sequestration+regeneration combination to save the oceans. Doubly so if the limestone sequestration process incorporates a micro/nanoplastic filtration mechanism before the water and limestone gets dumped back into the sea.

Ooh, I like the new logo! 😲

If you could extract lithium during the process, you may even make money on the deal.

The problem is mankind doesn't learn from its mistakes, it learns from what happens when it ignores its mistakes

always different, always good. Your choice of content is varied enough to capture the interest of a great many people...thanks

People mention concrete, but someone else in the comments pointed out that heating it up releases gases, so what about bricks for construction?

I think another simple and cheap way could be storing dry compressed seaweed.

Couldn't something similar be done with fresh water too, like in the Great Lakes or in a river? There are freshwater snails and mussels that have shells made of calcium carbonate, and if they can do it, so can we.

Any pilot plants planned? Can't seem to find a commercial operation for SCS2.