carbon sequestration
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Reducing global greenhouse gas emissions is an important goal, but another challenge awaits: lowering the levels of CO2 and other substances already in the atmosphere. One promising approach turns the gas into an ordinary mineral through entirely natural processes; 44.01 hopes to perform this process at scale using vast deposits of precursor materials and a $5 million seed round to get the ball rolling.
The process of mineralizing CO2 is well known among geologists and climate scientists. A naturally occurring stone called peridotite reacts with the gas and water to produce calcite, another common and harmless mineral. In fact this has occurred at enormous scales throughout history, as witnessed by large streaks of calcite piercing peridotite deposits.
Peridotite is normally found miles below sea level, but on the easternmost tip of the Arabian peninsula, specifically the northern coast of Oman, tectonic action has raised hundreds of square miles of the stuff to the surface.
Talal Hasan was working in Oman’s sovereign investment arm when he read about the country’s coast having the largest “dead zone” in the world, a major contributor to which was CO2 emissions being absorbed by the sea and gathering there. Hasan, born into a family of environmentalists, looked into it and found that, amazingly, the problem and the solution were literally right next to each other: the country’s mountains of peridotite, which theoretically could hold billions of tons of CO2.
Around that time, in fact, The New York Times ran a photo essay about Oman’s potential miracle mineral, highlighting the research of Peter Kelemen and Juerg Matter into its potential. As the Times’ Henry Fountain wrote at the time:
If this natural process, called carbon mineralization, could be harnessed, accelerated and applied inexpensively on a huge scale — admittedly some very big “ifs” — it could help fight climate change.
That’s broadly speaking the plan proposed by Hasan and, actually, both Kelemen and Matter, who make up the startup’s “scientific committee.” 44.01 (the molecular weight of carbon dioxide, if you were wondering) aims to accomplish mineralization economically and safely with a few novel ideas.
First is the basic process of accelerating the natural reaction of the materials. It normally occurs over years as CO2 and water vapor interact with the rock — no energy needs to be applied to make the change, since the reaction actually results in a lower energy state.
“We’re speeding it up by injecting a higher CO2 content than you would get in the atmosphere,” said Hasan. “We have to drill an engineered borehole that’s targeted for mineralization and injection.”
The holes would maximize surface area, and highly carbonated water would be pumped in cyclically until the drilled peridotite is saturated. Importantly, there’s no catalyst or toxic additive, it’s just fizzy water, and if some were to leak or escape, it’s just a puff of CO2, like what you get when you open a bottle of soda.
Second is achieving this without negating the entire endeavor by having giant trucks and heavy machinery pumping out new CO2 as fast as they can pump in the old stuff. To that end Hasan said the company is working hard at the logistics side to create a biodiesel-based supply line (with Wakud) to truck in the raw material and power the machines at night, while solar would offset that fuel cost at night.
It sounds like a lot to build up, but Hasan points out that a lot of this is already done by the oil industry, which as you might guess is fairly ubiquitous in the region. “It’s similar to how they drill and explore, so there’s a lot of existing infrastructure for this,” he said, “but rather than pulling the hydrocarbon out, we’re pumping it back in.” Other mineralization efforts have broken ground on the concept, so to speak, such as a basalt-injection scheme up in Iceland, so it isn’t without precedent.
Third is sourcing the CO2 itself. The atmosphere is full of it, sure, but it’s not trivial to capture and compress enough to mineralize at industrial scales. So 44.01 is partnering with Climeworks and other carbon capture companies to provide an end point for their CO2 sequestration efforts.
Plenty of companies are working on direct capture of emissions, be they at the point of emission or elsewhere, but once they have a couple million tons of CO2, it’s not obvious what to do next. “We want to facilitate carbon capture companies, so we’re building the CO2 sinks here and operating a plug and play model. They come to our site, plug in, and using power on site, we can start taking it,” said Hasan.
How it would be paid for is a bit of an open question in the exact particulars, but what’s clear is a global corporate appetite for carbon offsetting. There’s a large voluntary market for carbon credits beyond the traditional and rather outdated carbon credits. 44.01 can sell large quantities of verified carbon removal, which is a step up from temporary sequestration or capture — though the financial instruments to do so are still being worked out. (DroneSeed is another company offering a service beyond offsets that hopes to take advantage of a new generation of emissions futures and other systems. It’s an evolving and highly complex overlapping area of international regulations, taxes and corporate policy.)
For now, however, the goal is simply to prove that the system works as expected at the scales hoped for. The seed money is nowhere near what would be needed to build the operation necessary, just a step in that direction to get the permits, studies and equipment necessary to properly perform demonstrations.
“We tried to get like-minded investors on board, people genuinely doing this for climate change,” said Hasan. “It makes things a lot easier on us when we’re measured on impact rather than financials.” (No doubt all startups hope for such understanding backers.)
Apollo Projects, a early-stage investment fund from Max and Sam Altman, led the round, and Breakthrough Energy Ventures participated. (Not listed in the press release but important to note, Hasan said, were small investments from families in Oman and environmental organizations in Europe.)
Oman may be the starting point, but Hasan hinted that another location would host the first commercial operations. While he declined to be specific, one glance at a map shows that the peridotite deposits spill over the northern border of Oman and into the eastern tip of the UAE, which no doubt is also interested in this budding industry and, of course, has more than enough money to finance it. We’ll know more once 44.01 completes its pilot work.
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Earlier this week, ExxonMobil, a company among the largest producers of greenhouse gas emissions and a longtime leader in the corporate fight against climate change regulations, called for a massive $100 billion project (backed in part by the government) to sequester hundreds of millions of metric tons of carbon dioxide in geologic formations off the Gulf of Mexico.
The gall of Exxon’s flag-planting request is matched only by the grit from startup companies that are already working on carbon capture and storage or carbon utilization projects and have announced significant milestones along their own path to commercialization even as Exxon was asking for handouts.
These are companies like Charm Industrial, which just completed the first pilot test of its technology through a contract with Stripe. That pilot project saw the company remove 416 tons of carbon dioxide equivalent from the atmosphere. That’s a small fraction of the hundred million tons Exxon thinks could be captured in its hypothetical sequestration project located off the Gulf Coast, but the difference between Exxon’s proposal and Charm’s sequestration project is that Charm has actually managed to already sequester the carbon.
The company’s technology, verified by outside observers like Shopify, Microsoft, CarbonPlan, CarbonDirect and others, converts biomass into an oil-like substance and then injects that goop underground — permanently sequestering the carbon dioxide, the company said.
Eventually, Charm would use its bio-based oil equivalent to produce “green hydrogen” and replace pumped or fracked hydrocarbons in industries that may still require combustible fuel for their operations.
While Charm is converting biomass into an oil-equivalent and pumping it back underground, other companies like CarbonCure, Blue Planet, Solidia, Forterra, CarbiCrete and Brimstone Energy are capturing carbon dioxide and fixing it in building materials.
“The easy way to think about CarbonCure is we have a mission to reduce 500 million tons per year by 2030. On the innovation side of things we really pioneered this area of science using CO2 in a value-added, hyper low-cost way in the value chain,” said CarbonCure founder and chief executive Rob Niven. “We look at CO2 as a value-added input into making concrete production. It has to raise profits.”
Niven stresses that CarbonCure, which recently won one half of the $20 million carbon capture XPrize alongside CarbonBuilt, is not a hypothetical solution for carbon dioxide removal. The company already has 330 plants operating around the world capturing carbon dioxide emissions and sequestering them in building materials.
Applications for carbon utilization are important to reduce the emissions footprints of industry, but for nations to achieve their climate objectives, the world needs to move to dramatically reduce its reliance on emissions spewing energy sources and simultaneously permanently draw down massive amounts of greenhouse gases that are already in the atmosphere.
It’s why the ExxonMobil call for a massive project to explore the permanent sequestration of carbon dioxide isn’t wrong, necessarily, just questionable coming from the source.
The U.S. Department of Energy does think that the Gulf Coast has geological formations that can store 500 billion metric tons of carbon dioxide (which the company says is more than 130 years of the country’s total industrial and power generation emissions). But in ExxonMobil’s calculation that’s a reason to continue with business-as-usual (actually with more government subsidies for its business).
Here’s how the company’s top executives explained it in the pages of The Wall Street Journal:
The Houston CCS Innovation Zone concept would require the “whole of government” approach to the climate challenge that President Biden has championed. Based on our experience with projects of this scale, we estimate the approach could generate tens of thousands of new jobs needed to make and install the equipment to capture the CO2 and transport it via a pipeline for storage. Such a project would also protect thousands of existing jobs in industries seeking to reduce emissions. In short, large-scale CCS would reduce emissions while protecting the economy.
These oil industry executives are playing into a false narrative that the switch to renewable energy and a greener economy will cost the U.S. jobs. It’s a fact that oil industry jobs will be erased, but those jobs will be replaced by other opportunities, according to research published in Scientific American.
“With the more aggressive $60 carbon tax, U.S. employment would still exceed the reference-case forecast, but the increase would be less than that of the $25 tax,” write authors Marilyn Brown and Majid Ahmadi. “The higher tax causes much larger supply-side job losses, but they are still smaller than the gains in energy-efficiency jobs motivated by higher energy prices. Overall, 35 million job years would be created between 2020 and 2050, with net job increases in almost all regions.”
ExxonMobil and the other oil majors definitely have a role to play in the new energy economy that’s being built worldwide, but the leading American oil companies are not going to be able to rest on their laurels or continue operating with a business-as-usual mindset. These companies run the risk of going the way of big coal — slowly sliding into obsolescence and potentially taking thousands of jobs and local economies down with them.
To avoid that, carbon sequestration is a part of the solution, but it’s one of many arrows in the quiver that oil companies need to deploy if they’re going to continue operating and adding value to shareholders. In other words, it’s not the last 130 years of emissions that ExxonMobil should be focused on, it’s the next 130 years that aim to be increasingly zero-emission.
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Now’s the time for sustainable investments to shine. There are billions of dollars in funding in both public and private markets dedicated to new sustainable investing and demand for consumers for a more conscious capitalism has never been stronger.
As founders and investors reawaken to a sustainable morning in America a few areas are going to demand hardware, software and business model innovations.
Some of these sectors have been on the investment radar for the past year or two and others are just beginning to capture investor attention, but they all have something in common: the investor appetite for new businesses addressing the food supply chain; energy management and construction for homes and offices; carbon sequestration and monitoring and management of offsets; and new biomaterials and processes for packaging and industrial chemicals replacements have never been stronger.
If we’re going to feed the world, let’s start with the food chain.
COVID-19, the disease caused by the SARS-CoV-2 virus, has exposed significant holes in the food supply. Companies like AppHarvest, which agreed to go public through a SPAC earlier this year are only one of several companies remaking agriculture through the application of technology. There’s also Plenty, Bowery Farms, Unfold, BrightFarms and Revol Greens, working to upend the agricultural supply chain. If those companies are looking at new ways of growing crops, companies like Apeel Sciences and Hazel Technologies are trying to find ways to preserve food from spoilage. Treasure8 is looking at ways to use food waste for new food and ingredients and they’re not alone.
Then there’s the protein replacement companies that we’ve written about previously. Impossible Foods, Beyond Meat, Memphis Meats, Mosa Meat, Nuggs, Future Meat Technologies, Shiok Meats (a seafood company) are devising methods to create meaty proteins less dependent on animal husbandry. Perfect Day and its competitors are doing the same for the dairy industry.
There’s also tremendous need for new protein sources to feed the animals that people around the world still like to eat. For this there’re companies like Ynsect, which is providing insect proteins for industrial fish farms, or Grubly Farms, which is providing feed to the families raising their own chickens.
For these opportunities that are raising hundreds of millions in financing there are others that require the kind of high margin software solutions that are yet to be developed. These are visual technologies for tracking, monitoring and managing food production; sensors for improving the storage and supply chain, software for managing production and tracking produce and products from the farm to the table. Venture investors are beginning to invest in these companies as well.
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Carbon Engineering, a Canadian company developing technology to remove carbon dioxide from the atmosphere and process it for use in enhanced oil recovery or in the creation of new synthetic fuels, has locked in financing from two big industry backers — Chevron and Occidental Petroleum — to bring its products to market.
The undisclosed amount of capital Carbon Engineering raised from the investment arms of two of the world’s largest oil and gas companies — Oxy Low Carbon Ventures and Chevron Technology Ventures — will be used to commercialize its technology at a time when legislation in California and British Columbia are making low-carbon fuels more economically viable, according to a statement from the company’s chief executive, Steve Oldham. The company had already managed to nab Microsoft co-founder Bill Gates as an investor.
Gates is one of several big-name backers to be drawn to renewable energy technologies in the face of a steadily warming planet that’s rapidly approaching a tipping point of no return when it comes to global climate change. Together with a group of other multi-billionaires, including Marc Benioff, Jeff Bezos, Michael Bloomberg, Richard Branson, Jack Ma, Masayoshi Son and Meg Whitman, Gates launched a $1 billion fund called Breakthrough Energy Ventures last year to back companies that are developing things like new energy storage and water production technologies.
The Squamish, B.C.-based Carbon Engineering isn’t in the Breakthrough portfolio, but is one of several companies working on making economically viable a technology called “direct air capture” of carbon dioxide.

At the company’s pilot plant in Squamish, air gets hoovered up by giant fans into a processing facility where it is treated with potassium hydroxide, which captures and holds the carbon dioxide. Then more chemicals and heat are added to the mix to create millions of small white pellets — which contain higher concentrations of the carbon dioxide.
After that, the pellets are heated again to create a gas that is almost pure carbon dioxide. That gas can be either sequestered underground (a proposition with no economic benefit for Carbon Engineering at the moment) or converted back into fuels or chemicals, or used in enhanced oil recovery.
Carbon Engineering and competitors like ClimeWorks or Global Thermostat claim they can remove carbon dioxide from the atmosphere for roughly $100 per ton, or a bit less once they can get to scale. To make money though, they’ll need to refine that carbon dioxide into some sort of product — likely a fuel, which will return that carbon to the atmosphere.
Other companies tackling carbon capture, like Newlight Technologies and Opus12, convert the carbon into plastics or chemicals, while companies like CarbonCure aim to turn the captured carbon into a cement replacement.
While these products from carbon emissions are available, they’re not yet commercially viable at a significant scale. Oldham told National Public Radio that the fuel Carbon Engineering manufactures is roughly 20 percent more expensive than regular gasoline.
That’s why states like California are putting incentives in place to offset the added costs of using these low-carbon products.
Carbon Engineering has already spent $30 million to develop its process, while Climeworks raised $31 million last year to develop its own version of this carbon capture technology.
Not all climate watchers are convinced that these kinds of negative emission technologies are the answer. They argue that it’s less expensive to use renewable energy and other carbon-free energy sources than to take carbon dioxide out of the air.
At this point, though, emission reductions may not be enough. Given the dire reports coming out of the Trump administration and the Intergovernmental Panel on Climate Change, it’s going to take pretty much a combination of everything that humanity’s got to avoid a pretty catastrophic fate for a pretty large portion of the world’s population.
Even the companies that have been notorious for their contributions to the climate crisis that the world faces are waking up to the need for decarbonization (even if it’s an open question of whether they’re being dragged to the table or sitting down of their own free will).
Oxy Low Carbon Ventures is a good example. Reading the writing on the wall, the firm has invested not just in Carbon Engineering, but another company called NET Power, which purports to have developed a power plant with zero emissions.
“It is a very important time for the air capture field right now,” said Oldham in a statement. “We’re seeing leading jurisdictions, like California and British Columbia, creating markets for low carbon fuels and technologies like DAC, through effective climate policy. These efficient market-based regulations, and action from energy industry leaders like Occidental and Chevron, show the power of policy in driving innovation and achieving emissions reductions while delivering reliable and affordable energy.”
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