Carbon Dioxide Removal (CDR)

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CDR is removal of CO2 from the atmosphere - an essential basket of technologies for achieving UN IPCC best outcomes to mitigate climate change. This is a community for discussing advances and issues of CDR.

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tldr several BILLION tons per year by 2050! Roughly equivalent to the total mass of all the cars in the world - every year.

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In a deal that could be worth $200 million, Microsoft announced that it is purchasing 315,000 metric tons of carbon removal over a multi-year period from climate tech startup Heirloom Carbon. It's one of the biggest deals of its kind, reports The Wall Street Journal (paywalled). GeekWire reports:

San Francisco-based Heirloom is harnessing a geologic approach to catching and holding carbon dioxide. Limestone naturally binds to carbon, but Heirloom's technology dramatically speeds up the process, cutting it from years to days. The startup operates the only U.S. facility permanently capturing carbon. Even more important than the volume of carbon to be removed is the deal's ability to unlock additional funding and investments to grow Heirloom's business and the sector more broadly.

Microsoft previously invested in Heirloom through its $1 billion Climate Innovation Fund. The new deal represents a financially empowering "bankable agreement," said Heirloom CEO Shashank Samala. "Bankable agreements of this magnitude enable Heirloom to raise project finance for our rapid scale-up, fueling exponential growth like what we've seen in the renewable energy industry," Samala said in a statement. The guaranteed cash flow can facilitate financing needed to build Heirloom's next two commercial sites.

The deal is also "an example of the impact of the Biden administration's 2021 infrastructure bill," notes the report. "[T]he purchase was tied to Heirloom being selected by the U.S. Department of Energy as one of the nation's direct air capture (DAC) hubs. It will receive $600 million of matching funding thanks to the designation."

Credit: https://slashdot.org/story/418838

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cross-posted from: https://mander.xyz/post/2421501

There seems to be a huge number of miscellaneous projects for a specific type of environmental restoration or some other activity that is specifically aimed at carbon sequestration. For example, seagrass restoration alone has a plethora(1,2,3). Is there a decent list of these projects? I found this cool list of CCS projects(4), but that’s different.

If such a list exists, I have another question: Is there an objective way to compare their effectiveness?

https://www.projectseagrass.org

https://www.medseafoundation.org/index.php/en/portfolio-ita-2/a-sea-forest-to-save-the-planet/34

https://www.seegraswiesen.de/en/

https://en.m.wikipedia.org/wiki/List_of_carbon_capture_and_storage_projects

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Net Zero is when the bathtub quits overflowing, CDR is how we mop up the water and pump out the flooded basement.

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The prospects for seaweed to be a key CDR method are still largely unknown. More investigation!

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submitted 1 year ago* (last edited 1 year ago) by GlennMagusHarvey@mander.xyz to c/cdr@slrpnk.net
 
 

cross-posted from: https://sopuli.xyz/post/656269

(This is my first time cross-posting something -- please advise me if I've done anything wrong!)

(crossposter's comment: Personally I suggest checking out the MIT Tech Review article on this first, which gives useful context.)

Taking rock (Olivine) and dumping it on the beach, so that the waves break it down, adjust ocean pH and mineralize the CO₂.

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cross-posted from: https://lemmy.ml/post/1451658

A new IIASA-led study explored fairness and feasibility in deep mitigation pathways with novel carbon dioxide removal, taking into account institutional capacity to implement mitigation measures.

Meeting the 1.5°C goal of the Paris Agreement will require ambitious climate action this decade. Difficult questions remain as to how warming can be limited within technical realities while respecting the common but differentiated responsibilities and respective capabilities of nations on the way to a sustainable future. Meeting this challenge requires substantial emissions reductions to reach net-zero emissions globally.

Among the new options being studied in scientific literature, engineered Carbon Dioxide Removal (CDR) like Direct Air Capture of CO2 with Carbon Capture and Storage (DACCS), is a potentially promising technology to help bridge this gap. DACCS captures carbon by passing ambient air over chemical solvents, which can be considered a form of CDR if the captured carbon is stored permanently underground. But whether these novel technologies can help make ambitious goals more attainable, or whether they can help reach them more equitably remains an open question.

In their study published in Environmental Research Letters, an interdisciplinary research group led by IIASA scientists developed new scenarios exploring fairness and feasibility in deep mitigation pathways, including novel CDR technologies. For the first time, the team implemented DACCS in a well-established integrated assessment model called MESSAGEix-GLOBIOM, and studied how this technology could impact global mitigation pathways under different scenarios of environmental policy effectiveness based on country-level governance indicators.

"In current policy debates, concerns about the political feasibility and fairness of the current generation of climate mitigation scenarios are raised, and DACCS is often proposed as a possible solution. In our study we quantified under what conditions and how DACCS might address those concerns," explains Elina Brutschin, a study coauthor and researcher in the Transformative Institutional and Social Solutions Research Group of the IIASA Energy, Climate, and Environment Program.

The researchers emphasize that the goal of limiting warming to 1.5°C does not change when considering novel forms of CDR. For a broader perspective on pathways to limit warming, the research team investigated how novel CDR interacts under different assumptions of technoeconomic progress and the evolution of regional institutional capacity. The researchers highlight the risks of dependency on unproven carbon removal while also discussing the role novel CDR and similar technologies could play in the future for developing countries.

The results indicate that novel CDR can keep pre-Paris climate targets within reach when accounting for such risks, but that increasing institutional capacity beyond historical trends is necessary for limiting warming to the Paris Agreement's 1.5°C goal, even with novel CDR processes. The study also suggests that substantially improving institutional capacity to implement environmental policies, regulations, and legislation is critical to keep warming below 2°C if new forms of CDR fail to emerge in the near future.

The authors further point out that, when accounting for the possible future evolution of novel CDR technologies combined with inherent risks, the 'fairness' of overall outcomes did not meaningfully improve. DACCS did not impact near-term required global mitigation ambition, and additional carbon removal in developed economies accounted for only a small component of the mitigation necessary to achieve stringent climate targets. This is because the removal of carbon dioxide in these areas does not compensate sufficiently for their historical emissions by mid-century.

The inability of DACCS to enhance the fairness of outcomes, like cumulative carbon emissions, in 1.5°C scenarios, emphasizes the notion that meeting global climate targets is a global effort requiring an 'all-of-the-above' mitigation strategy. There is no room for flexibility when it comes to reaching climate goals.

The results, however, show that engineered removals can play a role in making the post-peak temperature stabilization (or decline) phase more equitable. This means that the full timeframe under which accounting takes place is critical for exploring fair outcomes that are agreeable by most Parties to the United Nations Framework Convention on Climate Change (UNFCCC).

"Our results show that new technologies for removing carbon from the atmosphere can play a role in ambitious climate policy, but they won't be a silver bullet for solving the climate crisis. Developed countries especially need to cut emissions by more than half this decade, primarily by reducing existing sources of emissions while scaling up CDR technologies to be in line with the Paris Agreement," says study lead author Matthew Gidden, a researcher in the IIASA Energy, Climate, and Environment Program.

The researchers emphasize that there is a clear need for the modeling community to assess the role of novel CDR in a structured way to better understand robust outcomes and insights versus observations related to a given model framework or approach. Looking forward, these issues can be explicitly included in scenario design to arrive at more equitable outcomes while incorporating political realities of the capabilities of governments and institutions to enact strong climate policy.

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CDR approaches that rely on creating biomass remain viable for now. Increasing mature forests, increasing agricultural land's carbon content through improved farming techniques and biochar addition, increasing protection and expanding coastal wetlands, and storing biomass to reduce decomposition - these are all good biomass alternatives we should evaluate.

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One of the ways people try to frame the challenge of climate change mitigation is "natural" solutions vs. "technological" solutions. We all have this intuitive sense that nature operates in a kind of balance - and if we have inadvertently or knowingly upset that balance; maybe it will be like a porch swing - continue to sway for a while but gradually return to equilibrium.

And that is true in some sense. There is a vast amount of carbon in circulation on this planet - far more than the fossil-fuel-derived bit humanity has added. It has been in a somewhat steady equilibrium that drifts around over periods of tens- to hundreds-of-thousands of years. If we "walk away" then equilibrium will return over the next millenium or two. But the great species diversity we have now will be gone; some new species will no doubt arise if we REALLY walk away. The biosphere will adapt.

But if we want to retain what we have, the natural systems need help. Whether it is growing giant kelp in the tropics, grinding mountains to dust to accelerate rock weathering, erect great machines to clean the air, transforming our agriculture to sustainability, restoring and expanding the worlds forests, or most likely ALL of these and more - they will be human technologies; applications of science and engineering to transform the local environment and our own capabilities. So there is really no nature vs. technology issue - everything we do to restore the climate is rebalancing nature, and all of it will require us to use technology.

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Bio CDR Roadmap and webinar (homeworld.pubpub.org)
submitted 1 year ago* (last edited 1 year ago) by sockrates@slrpnk.net to c/cdr@slrpnk.net
 
 

From another community: Here is a Roadmap for Impact of Biotechnology in CDR! Please comment inline.

Webinar on June 28. Register here.

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As we devise systems of CO2 removal over the next decades, a key focus is how to create these systems to further the goal of social justice. Although big oil companies would like to see their infrastructure converted to greener, but still private and shareholder-benefiting; CDR projects offer many opportunities to directly improve the lives of local and under-served populations. When we sequester carbon in soil, that can benefit local farmers - by improving their land AND being a source of negative-emission revenue. As coastal areas flood and return to marine habitats, they can become public recreation and fishery support.

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when we're talking about carbon dioxide in the air, the idea that we might mean something different between capturing it and removing it seems unintuitive. And yet we have two quite different concepts in circulation these days. This community is about CDR which is carbon dioxide removal (from the air), but there is also CCS - carbon capture and storage, and a new term gaining currency CCUS - carbon capture, utilization and storage. In this context, capture means removing CO2 from a point source emission, rather than from the mixed atmosphere. The CO2 in a point source is much more concentrated, so different technologies apply. You don't go to a orthodontics conference to present your work on new contact lenses - so don't start talking about CCS here in the CDR community; we'll just look at you funny.