Lets spread the second stage limestone (Quick Lime I assume) over the land to elevate the soil pH and provide calcium and Carbonate to the soil to improve the soil life. We could bring back the soil to a 7.4 pH as recommended by KSU and the natural pH of Mamals. Pit Run, and low quality Ag Lime cost about $80 per ton in the PNW….why not build lime and pull carbon out of the atmosphere?

Any takers on this process?

Good lime is not easily found economically in the Pacific Northwest and the Midwest in certain locations.

The processor could be located in central part of a trade region…no more than 1 hour out and back. This could solve the acidic soil problem in many locations around the corn belt and the pacific Northwest….we quit mining out of the ground and pull the C, out of the air. The calcium hydroxide is the problem since it is mined from the earth and takes heat to make it. Same with the Potassium Hydroxide…a spend process I believe.

There you have it….$80 a ton for lime in Whitman County Washington….and of the highest quality..….and a big savings in energy staying away from the third step….the calciner takes about 10 Mega Watts per day in a cement plant scenario….at 8 cents a KW that is $800 using electricity. How much does it cost per ton of calcined lime to CO2….that is a lot of money. GJS

This might work…if you can find a good source of Calcium Hydroxide that could be railed in with the Potassium Hydroxide coming to the plant on the same rail link. GJS

This is not a slow process, We can do it in 10 years by stopping the tillage Going with Green Play Ammonia. , we have the technology and it is Quadruple play….Soil Quality, Stored Soil Carbon, Higher Yields and Less Erosion and ….No-tilling 400 million acres, applying Green Ammonia, No-till, Cover Cropping….and a lot faster than building plants that have no value other than pulling CO2 and filling the vadoze. Green Play Ammonia, Builds Soils, Stores water where it falls, controls Gulf Hypoxia and Great Lakes pollution such as Lake Erie. GJS

The scale of the challenge for carbon removal using technologies like DAC, rather than plants, is no less gargantuan. Gambhir's paper calculates that simply keeping pace with global CO2 emissions – currently 36 gigatonnes per year – would mean building in the region of 30,000 large-scale DAC plants, more than three for every coal-fired power station operating in the world today. Each plant would cost up to $500m (£362m) to build – coming in at a cost of up to $15 trillion (£11tn).

Climeworks' facility near Zurich, Switzerland, sells the CO2 it captures to nearby vegetable growers for their greenhouses (Credit: Alamy)

Estimates of how much it costs to capture a tonne of CO2 from the air vary widely, ranging from $100 to $1,000 (£72 to £720) per tonne. Oldham says that most figures are unduly pessimistic – he is confident that Climate Engineering can fix a tonne of carbon for as little as $94 (£68), especially once it becomes a widespread industrial process.

A bigger issue is figuring out where to send the bill. Incredibly, saving the world turns out to be a pretty hard sell, commercially speaking. Direct air capture does result in one valuable commodity, though: thousands of tonnes of compressed CO2. This can be combined with hydrogen to make synthetic, carbon-neutral fuel. That could then be sold or burned in the gas furnaces of the calciner (where the emissions would be captured and the cycle continue once again). This is the fossil fuel industry solution.

Surprisingly, one of the biggest customers for compressed CO2 is the fossil fuel industry

As oil and gas wells run dry, it's not uncommon to squeeze the remaining oil out of the ground by pressuring the reservoir using steam or gas in a process called enhanced oil recovery. Carbon dioxide is a popular choice for this, and comes with additional benefit of locking that carbon underground, completing the final stage of carbon capture and storage. Occidental Petroleum, which has partnered with Carbon Engineering to build a full-scale DAC plant in Texas, uses 50 million tonnes of CO2 every year in enhanced oil recovery. Each tonne of CO2 used in this way is worth about $225 (£163) in tax credits alone. Tax credits for a process that is way out of the ball game….Somebody got hoodwinked…..that means we save 2.7 tons of carbon per ton of ammonia….that is $607 we can earn if that same accountant is available. GJS

Lets move to renewables as quick as we can….Who wants to run the oil and gas wells dry…..we will save the oil and gas wells for another time…..the 2nd act in 3021. GJS

It's perhaps fitting that the CO2 in our air is eventually being returned underground to the oil fields from whence it came, although maybe ironic that the only way to finance this is in the pursuit of yet more oil. Occidental and others hope that by pumping CO2 into the ground, they can drastically reduce the carbon impact of that oil: a typical enhanced-recovery operation sequesters one tonne of CO2 for every 1.5 tonnes it ultimately releases in fresh oil. So while the process reduces the emissions associated with oil, it doesn't balance the books.

Enhancing the growth of vegetables in greenhouses is one application for the CO2 captured from the air by DAC (Credit: Alamy)

"DAC is always going to cost money, and unless you're paid to do it, there is no financial incentive," says Chris Goodall, author of What We Need To Do Now: For A Zero Carbon Future. "Climeworks can sell credits to virtuous people, write contracts with Microsoft and Stripe to take a few hundred tonnes a year out of the atmosphere, but this needs to be scaled up a millionfold, and that requires someone to pay for it.

"There are subsidies for electric cars, cheap financing for solar plants, but you don't see these for DAC," says Oldham. "There is so much focus on emission reduction, but there isn't the same degree of focus on the rest of the problem, the volume of CO2 in the atmosphere. The big impediment for DAC is that thinking isn't in policy."

Zelikova believes that DAC will follow a similar path to other climate technologies, and become more affordable. "We have well-developed cost curves showing how technology can go down in cost really quickly," says Zelikova. "We surmounted similar hurdles with wind and solar. The biggest thing is to deploy them as much as possible. It's important for government to support commercialisation – it has a role as a first customer, and a customer with very deep pockets."
No government Money until we take care of better alternatives, Mr.Zelikova…There are better and quicker ways to do it. GJS

Goodall advocates for a global carbon tax, which would make it expensive to emit carbon unless offsets were purchased. But he recognises this is still a politically unpalatable option. Nobody wants to pay higher taxes, especially if the externalities of our high-energy lifestyles – increasing wildfires, droughts, floods, sea level rise – are seen as being shouldered by somebody else.

Zelikova adds we also need broader conversation in society about how much these efforts should cost. "There is an enormous cost in climate change, in induced or exacerbated natural disasters. We need to do away with idea that DAC should be cheap." I think this is about his money and not yours and my money? GJS

Even if we agree to build 30,000 industrial scale DAC plants, find the chemical materials to run them, and the money to pay for it all, we won't be out of the woods yet. In fact, we might end up in a worse position than before, thanks to a phenomenon known as mitigation deterrence.

Facilities in Iceland are among those aiming to mineralise CO2, to lock it out of circulation in the atmosphere as a long-term solution (Credit: Sandra O Snaebjornsdottir)

"If you think DAC is going to be there in the medium- to long-term, you will not do as much near-term emissions reduction," explains Gambhir. "If the scale-up goes wrong – if it turns out to be difficult to produce the sorbent, or that it degrades more quickly, if it's trickier technologically, if turns out to be more expensive than expected, then in a sense by not acting quickly in the near-term, you've effectively locked yourself into a higher temperature pathway." That is bad risk….when we know how to do it with other ways that are time proven….No-till, Green Play Ammonia, Cover Cropping, Rotation, storing water where it fails with root systems and soil structure. GJS.

Critics of DAC point out that much of its appeal lies in the promise of a hypothetical technology that allows us to continue living our carbon-rich lifestyles. Yet Oldham argues that for some hard-to-decarbonise industries, such as aviation, offsets that fund DAC might be the most viable option. "If it's cheaper and easier to pull carbon out of air than to stop going up in the air, maybe that is what DAC plays in emission control."

Gambhir argues that it's not an "either-or" situation. "We need to rapidly reduce emissions in the near-term, but at same time, determinedly develop DAC to work out for sure if it's going to be there for us in the future." Zelikova agrees: "It's a 'yes, and' situation," she says. "DAC is a critical tool to balance out the carbon budget, so what we can't eliminate today can be removed later."

As Oldham seeks to scale up Carbon Engineering, the biggest fundamental factor is proving large scale DAC is "feasible, affordable and available". If he's successful, the future of our planet’s climate may once again be decided in the oil fields of Texas.

In Nebraska if you are off base your teacher will tell you. "Somebody is smoking ditch weed." There are much better choices. GJS March 14, 2021.