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| The issue is not just CO<sub>2</sub> production, biodiversity loss and the nitrogen cycle are also major issues. However for the purpose of this Wiki we will focus on CO<sub>2</sub> production as this is an indirect measure of over consumption.
| | [[File:Sustainable Transition is Complicated.png|thumb|'''Figure 1'''. Carbon Tunnel Vision.]][[File:Planetary boundaries.png|alt=Planetary Boundaries framework (2022) showing 5 boundaries transgressed.|thumb|400x400px|'''Figure 2.''' Planetary Boundaries framework (2022) - climate change is only one of the 5 boundaries transgressed.<ref name=":1">'''Underestimating the Challenges of Avoiding a Ghastly Future'''. Front. Conserv. Sci. Published on 13 January 2021, accessed on 19 June 2022 via: [https://www.frontiersin.org/articles/10.3389/fcosc.2020.615419/full https://doi.org/10.3389/fcosc.2020.615419]</ref>]] |
| [[File:Planetary Boundaries.png|alt=Planetary boundaries|thumb|The main aspects of planetary ecological issues.]] | | '''It's becoming increasingly clear that our singular home—Earth—is under severe strain due to our excessive consumption. In the 1960s, our demands were about three-quarters of what the Earth could replenish in a year. By 2016, we were consuming at a rate of 170 percent of the planet's yearly regenerative capacity<ref name=":1" />.''' |
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| Since the industrial revolution, people have been [[wikipedia:Combustion|burning]] an increasing amount of [http://energyliteracy.com stuff]. From little fires in cars to big fires in power plants, we are putting so much of these [https://www.esrl.noaa.gov/gmd/ccgg/trends gases] into the sky that we are changing the thermal properties of our atmosphere, trapping ever more heat. This is the greenhouse effect, which is the main contributor to climate change.<p>Beyond power and transportation, there are less obvious [https://ourworldindata.org/co2-and-other-greenhouse-gas-emissions#emissions-by-sector emissions sources as well]: </p>
| | We now find ourselves in a [[Ecological Crisis Timeline|great race]]: Will we reach a [[social tipping point]] to reduce our impact before we hit irreversible [[global ecological tipping point]]? While [[CO2|CO<sub>2</sub>]] emissions often take the spotlight (as shown in '''Figure 1'''), there are nine key environmental limits to consider (illustrated in '''Figure 2'''). Alarmingly, we've already transgressed five of these: |
| | *'''Biodiversity loss''' - there has been a 68% average decline in the population sizes of mammals, birds, amphibians, reptiles, and fish between 1970 and 2016<ref>'''Nature’s Dangerous Decline ‘Unprecedented’; Species Extinction Rates ‘Accelerating’''' May 2019. https://ipbes.net/news/Media-Release-Global-Assessment</ref>. |
| | *'''Nitrogen cycle''' - ammonia factories (used for water purification, plastics, fabrics, pesticides and dyes) supplement the enzymatic magic of microbial nitrogen fixation with the brute forces of temperature and pressure, extracting close to 100 million metric tons of nitrogen from the atmosphere each year. This results in the creation of Nitrous Oxide which is 200 times more potent as a greenhouse gas than [[CO2|CO<sub>2</sub>]]<ref>'''Effects of Nitrogen Fertilizer Types on Nitrous Oxide Emissions'''. Martin Burger and Rodney T. Venterea Understanding Greenhouse Gas Emissions from Agricultural Management. January 1, 2011 , 179-202 [https://pubs.acs.org/doi/abs/10.1021/bk-2011-1072.ch011 DOI:10.1021/bk-2011-1072.ch011]</ref>. |
| | *'''Deforestation''' - more than half the world’s tropical forests have been destroyed since the 1960s<ref>'''Deforestation and forest degradation.''' International Union for Conservation of Nature. Published 2021, February. Accessed via https://www.iucn.org/resources/issues-briefs/deforestation-and-forest-degradation</ref>. |
| | * '''Ocean acidification''' - more [[CO2|CO<sub>2</sub>]] in the atmosphere means more acidity in the oceans<ref>'''Ocean acidification''' - National Oceanic and Atmospheric Administration U.S. Department of Commerce. Last updated April 1, 2020, accessed on 1 May 2023 via [https://www.noaa.gov/education/resource-collections/ocean-coasts/ocean-acidification - https://www.noaa.gov/education/resource-collections/ocean-coasts/ocean-acidification]</ref>. |
| | * '''Microplastics via overconsumption''' - ''posing a significant threat to the environment, including the wildlife and the ecosystem as a whole''<ref name=":0">'''Avoiding a ‘Ghastly Future’:''' Yale Environment 360: Hard Truths on the State of the Planet. Accessed on 3rd March 2022 via:https://e360.yale.edu/features/avoiding-a-ghastly-future-hard-truths-on-the-state-of-the-planet</ref>. |
| | * '''Climate change''' - s''ince records began in 1880, nineteen of the twenty hottest years have occurred since 2000''<ref>'''NASA, Global Temperature'''. Live data source can be obtained via: https://climate.nasa.gov/vital-signs/global-temperature/</ref>''. More recently, the 7 hottest days on Earth in the last 100,000+ years all happened in the first week of July 2023''<ref>'''Climate Reanalyser dataset''', Climate Change Institute, University of Maine: Two meter temperature world Graph. https://climatereanalyzer.org/clim/t2_daily/</ref>''.'' |
| | *'''Ozone depletion, the phosphorus cycle...''' |
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| * <p>cement production</p>
| | == '''''Counterarguments''''' == |
| * <p>steel production</p>
| | Much of this information is hard to digest as [[cognitive dissonance]] would say most of it is some sort of conspiracy or not their problem, below we address each counterargument with some rationale. |
| * <p>agricultural emissions (soil nitrous oxide, animal methane)</p>
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| * <p>[https://www.iea.org/reports/methane-tracker">methane industrial and permafrost leaks], etc. </p>
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| * <p>You can explore the [http://energyliteracy.com/ full range here]. </p><p>Some sectors have clear paths to reduce emissions electric [https://www.iea.org/reports/global-ev-outlook-2019 vehicles], solar/wind/nuclear, some will be [https://techcrunch.com/2019/02/15/how-to-decarbonize-america-and-the-world slower or more complex to decarbonize]: </p>
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| * <p>[https://www.iea.org/reports/tracking-transport-2019/aviation air travel] </p>
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| * <p>[https://www.iea.org/reports/tracking-industry-2019 industrial emissions]</p>
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| * <p>Some agricultural emissions, methane.</p><p>[https://www.carbonbrief.org/qa-how-do-climate-models-work Climate models describe]how much warming we can expect in different [https://skepticalscience.com/rcp.php emissions reductions scenarios]. 1.5 degrees C is now an incredibly optimistic target that would require unprecedented reduction, 2 degrees is considered difficult but in reach, 3+ degrees would be a worst case scenario. These scenarios are described by "Representative Concentration Pathways" (<a href="http://stripe.com/environment">intro</a>, <a href="https://en.wikipedia.org/wiki/Representative_Concentration_Pathway">more detail</a>). There is <a href="http://unfccc.int/paris_agreement/items/9485.php">international agreement</a> around 2 degrees C as maximum acceptable risk.</p><p>With that in mind; there are two general approaches to keep warming to below a certain level:</p><ol><li>Reducing emissions</li><li>Removing previous emissions from the sky</li></ol><p><b>If you remember one thing from this piece, it should be that we </b><a href="https://cicero.oslo.no/no/posts/nyheter/carbon-capture-and-storage-is-necessary-to-keep-global-warming-below-2c"><b>need to do both</b></a><b>. Gone are the days where optimistic emissions reductions kept us below a 2-degree warming target.</b></p><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://lh6.googleusercontent.com/Cbz7qQg7HFLJpxhwW3cYEzgBopoXmf70bnvrfycGg-VBpwtiBGu3X1Wgwp4k22G9W-xEa9h4a3S5HldoOZEUpNOSJwjLCHWyOuvWukc2MYAsvfc2NR8eSy5K0r0WPzpVw2kRl0j8" class="kg-image" width="100%"><figcaption>Figure S.1 from <a href="https://www.nap.edu/read/25259">Negative Emissions Technologies and Reliable Sequestration</a> (2019)</figcaption></figure><p><b>To keep below two degrees, we will need to dramatically reduce current emissions and simultaneously remove 10-15 gigatons of CO<sub>2</sub>/yr from the atmosphere by 2050 and scale that to about 20+ gigatons annually by 2100. Depending on how quickly we reduce emissions, the amount we need to remove from the atmosphere scales proportionally.</b></p><p>Greenhouse gas emissions are described in units of tons. It’s hard to think about how much “a ton of gas” really is -- this is how big, at surface temperature and pressure:</p><figure class="kg-card kg-image-card"><img src="https://lh4.googleusercontent.com/pSUji2nvLfeE9hR0oljOYmLjvXjuFcGSZab_yGDmcy1acMq-qrsC-5r4enjUoE0dmuQKoZ-ZgVI9-DWQKMHtq_ZvCd8kUXtHzgMCC_4kDpSOZDbemgPo68V0i1DEWsAjRg7TxCRG" class="kg-image" width="100%"></figure><p>Here’s a <a href="https://www.youtube.com/watch?v=DtqSIplGXOA">nostalgically animated video</a> visualizing a bunch of these one-ton balls in New York City.</p><p>If you’re in the US, you’re responsible for emitting about 19 tons of greenhouse gases a year. <a href="http://projectwren.com/">Wren</a> has a nice calculator that asks you about your commuting habits, flights, and diet to estimate your total GHG emissions. <a href="https://erikareinhardt.com/personal-climate-action">Erika Reinhardt wrote a detailed guide</a> on how you can reduce your emissions. With that in mind, see emissions per capita:</p><!--kg-card-begin: html-->
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| <iframe src="https://ourworldindata.org/grapher/co-emissions-per-capita" style="width: 100%; height: 600px; border: 0px none;"></iframe><!--kg-card-end: html--><p>You may also hear people talk about “400 parts per million CO<sub>2</sub>” or similar. This maps directly to the amount of gas emitted: when emissionsmix into the atmosphere, we reference concentrationsof the emitted gas as a portion of the atmosphere. This is like stirring sugar into a cup of coffee. Climate modeling is based on these concentrations. For a bit more on how this measurement works, see <i>Basic intro to units and measurement</i>.</p><!--kg-card-begin: html-->
| | === "Its a conspiracy." === |
| | Climate change is being studied by thousands of independent scientists across the world, they separately [[Critical analysis|critically analyse]] each other's work through the use of third party verified scientific journals. It would be logistically impossible for all of these researchers to coordinate and participate in a global conspiracy. |
| | ==="We will innovate out of the crisis."=== |
| | This is called the ''[[Ecomodernism|ecomodernist]] argument'' or ''technoutopian fallacy'', it has been around for centuries. Think about it this way... Imagine you decided to start smoking, a pack a day, maybe two. I might say but that's bad! It will kill you! then you *shrug* and say medicine will find a cure, just as it always has. ''The underlying message here is if you have been diagnosed with lung cancer the first thing you should do is to stop smoking.'' |
| | === “It’s the government’s problem.”=== |
| | Climate change is a catastrophic failure by governments. But we are voters, and governments act on our behalf. Many of us are drivers, flyers, and meat-eaters. Morally speaking, we can share responsibility for harms we are part of or those we fail to prevent between us. I’m not saying you (or I) should feel guilty about this unfolding global disaster, but we should feel ashamed. We should act. |
| | ==="Capitalism has brought a massive increase in the standard of living for all, how can you argue against it?"=== |
| | There is no doubt that capitalism has brought incredible stuff but it has brought us thus far. We now know that infinite growth in a closed system won't work. We need to see this in the context of the [[Sunk Cost Fallacy|sunk cost fallacy]]. |
| | ==="China is responsible for this mess, not us!"=== |
| | This one is so crazy we have given it its own [[China is responsible for the issues not us.|page]]. |
| | ===“It’s too expensive!”=== |
| | This is the so-called ''economic argument'' against mitigating climate change: that it’s cheaper to adjust to a hotter planet. Even if this were factually unassailable (spoiler alert: it’s not), it would be morally flawed. It relies on what philosophers call utilitarianism – the view that we should maximise overall welfare (often, in practice, overall money) even if some people suffer desperately along the way. That’s in direct contradiction to the most basic intuition of common sense morality. It disregards human rights. |
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| <iframe src="https://ourworldindata.org/grapher/co2-concentration-long-term" style="width: 100%; height: 600px; border: 0px none;"></iframe><!--kg-card-end: html--><p>For context (thanks to <a href="https://cnce.engineering.asu.edu/klaus-lackner/">Klaus Lackner</a> for the following distillation), <a href="https://www.esrl.noaa.gov/gmd/ccgg/trends/global.html">1 ppm</a> is worth about 7.5 Gigaton of CO<sub>2</sub>. But roughly half of it mixes into the surface ocean and some goes into the biosphere. So the net result is that it takes about 15 Gigaton of CO<sub>2</sub> to raise the atmospheric concentration by 1 ppm. We <a href="https://www.esrl.noaa.gov/gmd/ccgg/trends/gr.html">raise it by about 2.5 ppm</a> per year.</p><hr><h1 id="basic-intro-to-units-and-measurement">Basic intro to units and measurement</h1><h2 id="measuring-greenhouse-gases">Measuring greenhouse gases</h2><p>Greenhouse gases are released by burning stuff as well as the product of other chemical reactions in industry. Generally, we’re talking about mostly carbon dioxide (<b>CO<sub>2</sub></b>), methane (natural gas) (<b>CH<sub>4</sub></b>), and nitrous oxide (<b>N<sub>2</sub>O</b>). N<sub>2</sub>O and CH<sub>4</sub> are <a href="https://en.wikipedia.org/wiki/Global_warming_potential%23Global_Temperature_change_Potential_(GTP)">more potent greenhouse gases</a>, but they occur in an order of magnitude less quantity than CO<sub>2</sub>, so removing them is generally much harder. Methane also has a much shorter half life in the atmosphere than CO<sub>2</sub>.</p><h2 id="here-are-the-units-you-ll-usually-see-">Here are the units you’ll usually see:</h2><h3 id="tons-of-co2">Tons of CO<sub>2</sub></h3><p>Literally just a ton of CO<sub>2</sub> by mass. This is the most common unit. It is often unclear whether someone means metric or imperial tons, which is annoying.</p><h3 id="tons-of-co2e">Tons of CO<sub>2</sub>E</h3><p>The E means “equivalent”, you’ll often see this when reading about offsets or macro-scale emissions comparisons. “Equivalent” means another greenhouse gas,<a href="https://en.wikipedia.org/wiki/Global_warming_potential%23Global_Temperature_change_Potential_(GTP)"> normalized to the warming potential of CO<sub>2</sub></a>. As calculated, methane is about <a href="https://www.epa.gov/ghgemissions/understanding-global-warming-potentials">28-36x equivalent (GWP 100)</a>, so 1 ton of methane would count as 28-36 tons CO<sub>2</sub>E.</p><p><i>(Update March 2: my original methane GWP value was incorrect, fixed now, thanks <a href="https://snarfed.org">Ryan Barrett</a> for flagging)</i></p><h3 id="tons-of-c">Tons of C</h3><p>This is mostly used when talking about sinking carbon in plants and soils, and it just means we only measure the C in the CO<sub>2</sub>, which maps 3:11 by molar mass. (Because the two Oxygen atoms each have a mass of 16)</p><h3 id="-mega-tons-giga-tons-of-any-of-these">(Mega)tons, (giga)tons of any of these</h3><p>Megaton = one million tons; Gigaton = one billion tons.</p><h2 id="measuring-greenhouse-gases-when-they-re-mixed-into-the-sky">Measuring greenhouse gases when they’re mixed into the sky</h2><p>The atmosphere is made of a mixture of gases:</p><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://lh3.googleusercontent.com/1pH_QSrDc-I9ljY0oV0g7P7ULBFYTSmb2MeFOaCgsZT5Gt2OTwqCPfanli7t7Ima7BX1SJ3J1zQINuDN_wu4DkVa5sHQupmWU0FchMvlfSorns5b-TsrRP5Y_N4UiqS-wQdq7pHJ" class="kg-image"><figcaption>Figure source: <a href="https://en.wikipedia.org/wiki/Atmosphere_of_Earth">Wikipedia Atmosphere of Earth</a></figcaption></figure><p>Greenhouse gases are a <b>super small part of it</b>, so instead of describing tiny absolute percentages, we use these units to describe how much:</p><h3 id="parts-per-million-ppm-">Parts per million (PPM)</h3><ul><li>Used mostly for CO2</li></ul><h3 id="parts-per-billion-ppb-">Parts per billion (PPB)</h3><ul><li>Used mostly for CH<sub>4</sub>, CFCs, and other trace gases.</li></ul><p>This is what we mean by methane being far more dilute than CO<sub>2</sub> (and therefore unrealistic to capture) -- we need to measure it in parts per <i>billion</i>.</p><p>This sense of scale helps explain why removing CO<sub>2</sub> is an expensive proposition, thermodynamically and hence monetarily: it’s an extremely dilute (parts per million!) gas in solution — we’re talking about separating a tiny fraction of the air from the rest of the air.</p><p>Finally, taking a step back: the sensitivity of this system is really incredible -- we’re talking about changing the lives of people around the world by <b>adding less than a basis point to the absolute concentration of a trace gas</b>. It’s <i>wild</i>.</p><hr><h1 id="do-we-really-need-to-remove-co2">Do we really need to remove CO<sub>2</sub>?</h1><p>In the 90s, negative emissions were <a href="https://en.wikipedia.org/wiki/Overton_window">not mainstream</a> apart from early research by <a href="https://en.wikipedia.org/wiki/David_Keith_(scientist)">David Keith</a>, <a href="https://en.wikipedia.org/wiki/Klaus_Lackner">Klaus Lackne</a>r, and others.</p><p>There was some combination of optimism that the problem wasn’t so bad, that the world would decarbonize at a sufficient rate that negative emissions wouldn’t be necessary, and that a policy framework would force action (large scale carbon price/cap and trade, which still doesn’t exist worldwide). This was all combined with fears that negative emissions present a moral hazard by giving ourselves an “out” for crucial emissions reduction work. A good summary of the history is <a href="https://www.amazon.com/Carbon-Capture-Press-Essential-Knowledge/dp/0262535750">here</a>.</p><p>In an attempt to hit a 2 degree warming target, the <a href="https://unfccc.int/process-and-meetings/the-paris-agreement/the-paris-agreement">Paris agreement</a> calls on countries to set “Nationally Determined Contributions”, or <a href="https://unfccc.int/process-and-meetings/the-paris-agreement/nationally-determined-contributions-ndcs">NDCs</a> -- commitments to a specific amount of emissions reduction over the coming decades. <b>But these commitments are not even close to enough:</b></p><!--kg-card-begin: html-->
| | Even if we swallowed this pill, it takes another questionable assumption to make the anti-mitigation sums add up. These economic arguments, says the philosopher Simon Caney, assume that future people’s pain, even their deaths, count for less in the cost-benefit calculations if these are further in the future. That isn’t standard economic discounting; it’s discounting the lives of our descendants. |
| | ===“I’m already vegan and don’t fly.” === |
| | This one is the flipside to “it’s all the government’s fault”: putting it all on individuals. That’s inefficient, unfair, and doesn’t work anyway. Going car-free is harder without a good public transport system; leaving mitigation to individuals means putting all the burden on those who happen to make the effort. And individual carbon-cutting, although important, isn’t enough. It won’t avert this catastrophe without governments on board or fossil fuel giants being held accountable. Faced with institutional failure, we shouldn’t feel powerless, but we should all be climate activists, using our own actions to bring about change from above. |
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| <iframe scrolling="no" frameborder="0" marginheight="0px" marginwidth="0px" style="background: #fff; display: initial; margin: 0 auto;" src="https://cbhighcharts2019.s3.eu-west-2.amazonaws.com/UNEP+Emissions+Gap/emissions_gap.html" width="100%" height="600px"></iframe><!--kg-card-end: html--><h4 id="there-are-two-complementary-scary-things-about-this-chart-">There are two complementary scary things about this chart:</h4><ul><li>All existing Paris commitments (“NDCs” in the above figure) don’t get us even close to a 2 degree trajectory</li><li>Countries are <a href="https://climateactiontracker.org/countries/">not even close to on track to hit even these commitments</a>. This is an incredible collective action problem — each individual country faces minimal/zero “official” consequences for failing to do so.</li></ul><h3 id="here-s-what-the-emissions-gap-looks-like-for-a-1-5-degree-target-source-">Here’s what the <a href="https://www.unenvironment.org/interactive/emissions-gap-report/2019/">emissions gap</a> looks like for a 1.5 degree target (<a href="https://www.carbonbrief.org/unep-1-5c-climate-target-slipping-out-of-reach">source</a>):</h3><!--kg-card-begin: html-->
| | ===“It's too late, I won’t make a difference.”=== |
| | This is termed the ''singularity argument''. A counterargument to which is: ''What’s the alternative?'' Sitting on the sidelines, while others right this collective wrong? That’s not fair on us. The "don't bother keep consuming" narrative is a contagious and profitable message that continually tries to demoralize and demotivate any and all momentum and benefits a very select few. |
| | ===“Lying in front of lorries isn’t my thing.”=== |
| | So don’t do that! But perhaps look past the [[framing]] that makes you uncomfortable and ask yourself why anyone would feel desperate enough to glue themselves to a road. It’s not because they enjoy it. Then ask what it is that you will do. Write to your MP? Wave banners outside parliament? Demand that your bank or pension fund divest from fossil fuels? Donate to climate justice NGOs? [[Help|Help us on BurnZero?]]. Do what you’re good at, as part of a bigger picture. |
| | ==='''“I’ve got enough to do already!”'''=== |
| | Climate justice isn’t some esoteric goal. It’s about living in a way that doesn’t kill people: doesn’t drown them, burn their homes or give them malaria. So how much money or time or emotional effort should each of us put in for this basic collective morality? I don’t have a final answer because the ethical debate is continuing. But I have an answer that will do for now, for those living comfortably in rich countries. However much we should do to avert this tragedy, it’s more than most of us do now. |
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| <iframe scrolling="no" frameborder="0" marginheight="0px" marginwidth="0px" style="background: #fff; display: initial; margin: 0 auto;" src="https://cbhighcharts2019.s3.eu-west-2.amazonaws.com/UNEP+Emissions+Gap/peaking_year_15c.html" width="100%" height="500px"></iframe><!--kg-card-end: html--><h3 id="and-for-a-2-degree-target-source-">And for a 2 degree target (<a href="https://www.carbonbrief.org/unep-1-5c-climate-target-slipping-out-of-reach">source</a>):</h3><!--kg-card-begin: html-->
| | == Root Cause == |
| | [[File:Root-cause-analysis.png|alt=Root-cause-analysis|thumb|'''Figure 3.''' Root-cause-analysis]] |
| | In the study of medicine, when a symptom develops, a bad doctor will only treat the symptoms. A good doctor will treat the symptoms whilst looking for the root cause (See '''Figure 3'''). |
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| <iframe scrolling="no" frameborder="0" marginheight="0px" marginwidth="0px" style="background: #fff; display: initial; margin: 0 auto;" src="https://cbhighcharts2019.s3.eu-west-2.amazonaws.com/UNEP+Emissions+Gap/peaking_year_2c.html" width="100%" height="500px"></iframe><!--kg-card-end: html--><h3 id="putting-this-all-together-is-this-figure-">Putting this all together is this figure:</h3><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://lh6.googleusercontent.com/Cbz7qQg7HFLJpxhwW3cYEzgBopoXmf70bnvrfycGg-VBpwtiBGu3X1Wgwp4k22G9W-xEa9h4a3S5HldoOZEUpNOSJwjLCHWyOuvWukc2MYAsvfc2NR8eSy5K0r0WPzpVw2kRl0j8" class="kg-image"><figcaption>Figure S.1 from <a href="https://www.nap.edu/read/25259">Negative Emissions Technologies and Reliable Sequestration</a> (2019)</figcaption></figure><p>Compounding the urgency, that research into negative emissions technologies (NETs) have been <b>dramatically underfunded in proportion to their importance</b><i>. </i>To quote the National Academies (emphasis mine):</p><blockquote>“...the federal government spent more than $22 billion on renewable energy research and development from 1978 to 2013. <b>NETs have not received comparable public investment</b> despite expectations that they might provide ~30 percent of the net emissions reductions required this century (i.e., maxima of 20 Gt/y CO<sub>2</sub> of negative emissions and 50 Gt/y CO<sub>2</sub> of mitigation in Figure S.1). <b>NETs are essential to offset greenhouse gas emissions that cannot be eliminated</b>, such as a large fraction of agricultural nitrous oxide and methane emissions.”</blockquote><hr><h1 id="how-to-take-co2-out-of-the-sky">How to take CO<sub>2</sub> out of the sky</h1><p>For a more comprehensive but still accessible overview, I recommend <a href="https://longitudinal.blog/co2-series-part-2-co2-removal/">Adam Marblestone’s Climate Technology Primer</a> and primary sources in my <a href="https://www.orbuch.com/nets-reading-list">Negative Emissions Reading List</a>, <b>especially the <a href="https://www.nap.edu/read/25259/chapter/2">Summary section</a> of the National Academies Report</b>.</p><p><a href="http://stripe.com/blog/negative-emissions-commitment">Stripe’s Negative Emissions Commitment</a> blogpost includes a brief overview of these and other technologies as well as some important context on adoption curves.</p><h3 id="briefly-there-are-plant-based-mineral-based-and-chemical-options-">Briefly: there are plant-based, mineral-based, and chemical options.</h3><p>Plant based solutions leverage a plant’s capacity to capture carbon via photosynthesis and the energy of the sun. Solutions in this category include (re)forestation, soil carbon sequestration, algae/kelp farming, and bio-energy with carbon capture and storage (often referred to as BECCS, this is basically a biomass power plant that burns wood and then is fitted with a carbon capture device to handle the smoke aka “<a href="https://en.wikipedia.org/wiki/Flue_gas">flue gas</a>”).</p><p>Mineral-based solutions include speeding the weathering of naturally occurring rocks, e.g. <a href="https://projectvesta.org/">Olivine</a>.</p><p>Chemical solutions include <a href="https://en.wikipedia.org/wiki/Direct_air_capture">Direct Air Capture</a> (typically coupled with <a href="https://www.epa.gov/uic/background-information-about-geologic-sequestration">geologic storage</a>, the capture aspect is often referred to as DAC), where a big machine sucks CO<sub>2</sub> out of the air; providing gaseous concentrated CO<sub>2</sub> that can then be <a href="https://www.carbfix.com">injected underground</a> for permanent storage.</p><figure class="kg-card kg-image-card kg-width-wide kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/image.png" class="kg-image"><figcaption>Figure 1.6 from <a href="https://www.nap.edu/read/25259">Negative Emissions Technologies and Reliable Sequestration</a> (2019)</figcaption></figure><p>These solutions all have different technical tradeoffs, potentials for scale, costs, adoption curves, and more.</p><figure class="kg-card kg-image-card kg-width-wide kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/IPCC-Soil-Sequestration-Chart.png" class="kg-image"><figcaption>This figure references a 1.5 degree target, and these boxes are a bit oversimplified, but it is good context</figcaption></figure><hr><h1 id="overview-of-approaches">Overview of approaches</h1><h2 id="trees-and-forests">Trees and forests</h2><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://images.unsplash.com/photo-1441974231531-c6227db76b6e?ixlib=rb-1.2.1&amp;q=80&amp;fm=jpg&amp;crop=entropy&amp;cs=tinysrgb&amp;w=2000&amp;fit=max&amp;ixid=eyJhcHBfaWQiOjExNzczfQ" class="kg-image" alt="Beautiful woodland path"><figcaption>Photo by <a href="https://unsplash.com/@szmigieldesign?utm_source=ghost&amp;utm_medium=referral&amp;utm_campaign=api-credit">Lukasz Szmigiel</a> / <a href="https://unsplash.com/?utm_source=ghost&amp;utm_medium=referral&amp;utm_campaign=api-credit">Unsplash</a></figcaption></figure><p>Trees and plants are incredible at carbon capture, doing so for <a href="https://en.wikipedia.org/wiki/Photosynthesis">“free” via the energy of the sun</a> despite how dilute CO<sub>2</sub> is in the atmosphere. The CO<sub>2</sub> trees absorb doesn’t magically go away. Instead, the C literally becomes part of the biomass of the tree. When a tree burns down, the carbon it absorbed is released right back into the air. For permanent sequestration, we’ll need to do something with the biomass of the forest. This could include making it into wooden building materials, biochar fertilizer, or dropping the biomass in the ocean. Or, if the forest is well managed, it can grow for centuries; and we can consider the sequestration “durable” as long as that management persists and is monitored.</p><p>To understand how much carbon is captured, scientists build models that relate easy-to-measure physical properties like diameter and height to the actual above-ground dry weight of a tree, about 50% of which is carbon. These are known as the <a href="https://www.fs.usda.gov/treesearch/pubs/6996">allometric equations</a>. More modern techniques <a href="https://pachama.com/">leveraging remote sensing and LIDAR</a> are being explored to do the same thing with fewer ground measurements.</p><p>Forests take up land that may be more economical if used for other things. Forests are dark colored and may actually decrease <a href="https://en.wikipedia.org/wiki/Albedo">albedo</a> (light-colored-ness -> heat reflectance from the sun), somewhat decreasing their utility (paper is <a href="https://journals.ametsoc.org/doi/10.1175/JCLI-D-18-0812.1">here</a> and <a href="http://faculty.washington.edu/aswann/">here’s</a> a lab working on albedo). There may also be impacts on the biodiversity of the ecosystem the land would otherwise be used for.</p><p><i>For more detail, I recommend the </i><a href="https://rmi.org/wp-content/uploads/2018/11/RMI_Negative_Emissions_Scenarios_Report_2018.pdf"><i>Rocky Mountain Institute’s overview report</i></a><i> on land-based negative emissions solutions, as well as </i><a href="https://www.wri.org/publication/land-carbon-removal-usa"><i>WRI’s land carbon removal overview</i></a><i>. </i></p><h2 id="direct-air-capture-dac-sequestration">Direct air capture (DAC) + sequestration</h2><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/10climeworksplantgreenhousebackgroundcopyrightclimeworksphotobyjuliadunlop.jpg" class="kg-image"><figcaption><a href="http://climeworks.com">Climeworks</a> DAC facility outside of Zurich, Switzerland</figcaption></figure><p>Traditional direct air capture facilities pass atmospheric air through a “sorbent” that absorbs, concentrates, and then controls release of CO2. <b>For a detailed but still accessible overview of the field, see<a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00010/full"> The Role of Direct Air Capture in Mitigation of Anthropogenic Greenhouse Gas Emissions.</a></b></p><p>Companies currently working on this include <a href="http://climeworks.com">Climeworks</a>, <a href="https://carbonengineering.com">Carbon Engineering</a>, and <a href="https://globalthermostat.com">Global Thermostat</a>. Because CO<sub>2</sub> is so dilute (about 0.04% in atmospheric air), this process is energy intensive (22kJ/mol). Hence, Lifecycle Analysis is very important. For an example methodology, see <a href="https://www.cell.com/joule/pdf/S2542-4351(18)30225-3.pdf">Keith 2018</a> which describes Carbon Engineerings technical approach.</p><p>There are also some new DAC approaches, currently in the research phase, e.g. electro-swing adsorption (<a href="http://news.mit.edu/2019/mit-engineers-develop-new-way-remove-carbon-dioxide-air-1025">news article with a good summary</a>, <a href="https://pubs.rsc.org/en/content/articlelanding/2019/ee/c9ee02412c#!divAbstract">source paper</a>). These are promising but quite early!</p><p><b>In any case, the result of DAC is pure gaseous CO<sub>2</sub>, which can be either <i>utilized </i>or <i>sequestered</i>.</b></p><h4 id="sequestration">Sequestration</h4><p>Sequestering it means permanently removing the CO<sub>2</sub> from the carbon cycle, and literally reducing the concentration of CO<sub>2</sub> in the atmosphere. This can be done by injecting the CO<sub>2</sub> injected underground into an oil well, salt dome, or saline aquifer.</p><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/fclim-01-00010-g004-1.jpg" class="kg-image"><figcaption>Figure Source:<a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00010/full"> The Role of Direct Air Capture in Mitigation of Anthropogenic Greenhouse Gas Emissions</a></figcaption></figure><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/Hellisheidi_Geothermal_Power_Plant-6.png" class="kg-image"><figcaption><a href="https://www.carbfix.com">Carbfix</a>s CO2 injection site at the Hellisheiði Geothermal Power Plant outside of Reykjavík Iceland</figcaption></figure><p>It’s fairly straightforward to measure how much CO<sub>2</sub> is being pumped into geologic storage, and there are generally accepted practices in the oil industry to demonstrate secure storage. See the <i>Geologic sequestration - "in situ" </i>subsection of the <i>Enhanced weathering and carbon mineralization </i>section later down this blog post for more details.</p><h4 id="utilization">Utilization</h4><p>Alternatively, this CO<sub>2</sub> can also be <i>utilized</i>. Some utilization mechanisms can be considered negative emissions/long-term sequestration, eg using the CO<sub>2</sub> to <a href="http://www.carboncure.com">cure cement</a>. Other use cases include making <a href="https://www.prometheusfuels.com">fuels</a> and <a href="http://www.opus-12.com">chemicals</a>. The fuels case is interesting, in that the emissions from the fuel wouldn’t cause an absolute increase in atmospheric CO<sub>2</sub> like it would if you pulled the fuel out of the ground. In a sense, you’re burning and “unburning” the fuel via capture, concentration, and fuel reformation.</p><p>I will note that none of these utilization solutions currently use direct air captured CO<sub>2</sub> – they all <a href="https://www.globalccsinstitute.com/why-ccs/what-is-ccs/capture/">capture</a> the CO<sub>2</sub> via the <a href="https://en.wikipedia.org/wiki/Flue_gas">flue gas</a> of a power plant or similar. Conceptually, they could just as well use a DAC-provided CO<sub>2</sub> stream, it is just prohibitively expensive at this point.</p><h2 id="soils">Soils</h2><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://images.unsplash.com/photo-1523349312806-f5dde0a01c32?ixlib=rb-1.2.1&amp;q=80&amp;fm=jpg&amp;crop=entropy&amp;cs=tinysrgb&amp;w=2000&amp;fit=max&amp;ixid=eyJhcHBfaWQiOjExNzczfQ" class="kg-image"><figcaption>Photo by <a href="https://unsplash.com/@markusspiske?utm_source=ghost&amp;utm_medium=referral&amp;utm_campaign=api-credit">Markus Spiske</a> / <a href="https://unsplash.com/?utm_source=ghost&amp;utm_medium=referral&amp;utm_campaign=api-credit">Unsplash</a></figcaption></figure><p>Soil carbon sequestration methods aim to encourage modified agricultural techniques that increase the carbon sequestered in soil without reducing or otherwise affecting agricultural yield. <b>For a deeper overview, I highly recommend </b><a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00008/full"><b>Soil C Sequestration as a Biological Negative Emission Strategy</b></a><b>.</b></p><p>These “<a href="https://www.climaterealityproject.org/blog/what-regenerative-agriculture">regenerative</a>” mechanisms include no-till farming, using cover crops, and reducing usage of nitrogen fertilizers can enable storage in soil of some of the plant’s carbon volume.</p><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/fclim-01-00008-t001-1.jpg" class="kg-image"><figcaption>Figure Source: <a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00008/full">Soil C Sequestration as a Biological Negative Emission Strategy</a></figcaption></figure><p><a href="https://csiropedia.csiro.au/wp-content/uploads/2016/06/SAF-SCaRP-methods.pdf">Measuring soil carbon</a> can be complex and has <a href="http://sci-hub.tw/10.1071/SR14339">high variance</a>: there’s the carbon in the biomass of the plant roots, and then the carbon expelled by the roots that can become stable in the soil as "<a href="https://source.colostate.edu/soil-carbon-is-a-valuable-resource-but-all-soil-carbon-is-not-created-equal/">Soil Organic Carbon</a>". Ground measurements are expensive (you take a core sample of the soil and stick it in a spectrometer, which is not a thing that farmers have lying around), and it’s still very early for soil carbon remote sensing.</p><p>Remote sensing is tough with soil because you do not just care about the carbon content of the topsoil, you care about the distribution of carbon vertically down the soil column for a couple feet – generally the deeper the carbon is, the more durably it is stored.</p><p>An alternate approach is "<a href="https://sci-hub.tw/10.1016/S1002-0160(13)60035-1">inverse modeling</a>", where you try to extrapolate the soil organic carbon (SOC) based on the plant growth. More plant growth generally means more SOC, but is not nearly a perfect correlate (precipitation, temperature, fertilizer use, crop type etc all confound, they also influence SOC but often with different statistical power).</p><p>Even if measured and modeled well, it can be hard to guarantee the long-term storage since farming and soil turnover practices could change in the future.</p><p><i> There are lots of labs working on soil stuff, if you are curious to learn more: </i><a href="https://soilcrop.agsci.colostate.edu">Colorado State University</a><i> is known for being a great soil program (they maintain <a href="http://comet-farm.com">COMET-Farm</a>, the canonical farm soil carbon monitoring tool). CSIRO (the Australian govt research agency) is also very well respected and doing <a href="https://csiropedia.csiro.au/soil-carbon-research-program/">really interesting work</a> in this field. Thanks to both of these groups for explaining soil things to me! Also take a look the <a href="https://rmi.org/wp-content/uploads/2018/11/RMI_Negative_Emissions_Scenarios_Report_2018.pdf">Rocky Mountain Institute’s overview report</a> on land-based negative emissions solutions, as well as <a href="https://www.wri.org/publication/land-carbon-removal-usa">WRI’s land carbon removal overview</a>.</i></p><h2 id="doing-things-with-biomass-bio-energy-with-carbon-capture-and-storage-beccs-and-biochar">Doing things with biomass: Bio energy with carbon capture and storage (BECCS) and Biochar</h2><h3 id="beccs">BECCS</h3><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/4756-1-full.jpg" class="kg-image"><figcaption>This is just a regular biomass power plant, no carbon capture and storage (CCS), but you get the idea</figcaption></figure><p>The idea of biomass power in general is that instead of burning coal or natural gas to turn a turbine, you burn biomass (which, because it is biomass, is made of carbon that used to be in the atmosphere).</p><p>Hence BECCS, as <a href="https://www.draxbiomass.com">generally proposed</a>, takes the “get the capture for free!” idea of plant-based carbon capture and combines it with "sequester the flue gas CO<sub>2</sub>" idea that’s often applied to the CO<sub>2</sub> resulting from DAC.</p><p>BECCS strengths and weaknesses are similar to that of forests, where trees and grasses continue to be amazing at “free” carbon capture. The <a href="https://www.nature.com/articles/s41467-018-05340-z">land use needed may be quite large</a>, and likely more agriculturally intense. BECCS requires a very high volume of biomass (and hence has high sequestration potential, but is only currently deployed at very limited scale).</p><p>Depending on how you have combusted or <a href="https://en.wikipedia.org/wiki/Pyrolysis">pyrolyzed</a> biomass, you either end up with a stream of flue gas from which you can concentrate the CO<sub>2</sub> and do geologic storage/utilization/anything else you would do with flue gas, or you are able to keep the C in the biomass via pyrolysis and output Biochar (see below) – this is what some new BECCS companies like <a href="https://www.charmindustrial.com">Charm</a> do.</p><h3 id="biochar">Biochar</h3><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/Carbo-Culture-Biochar-in-hands-1.png" class="kg-image"><figcaption>Image via <a href="https://www.orbuch.com/carbon-removal/carboculture.com">CarboCulture</a></figcaption></figure><p>Another option is taking biomass and making <a href="https://en.wikipedia.org/wiki/Biochar">biochar</a>, generally via <a href="https://en.wikipedia.org/wiki/Pyrolysis">pyrolysis</a>. The idea here is that you heat biomass to a high temperature in a low-oxygen environment; producing biochar: a chalky black material that is nearly pure carbon.</p><p>Biochar is used as a fertilizer and soil additive: it seems like it might improve fertility, <a href="https://www.nature.com/articles/srep25127">increase soil organic carbon (SOC)</a>, and <a href="https://sci-hub.tw/10.1016/j.ecoenv.2017.02.028">reduce soil heavy metal concentrations</a>. <b>For a more detailed overview, see the "Biochar Additions" section of<a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00008/full"> Soil C Sequestration as a Biological Negative Emission Strategy</a>.</b></p><p>Properly produced biochar has the<a href="https://onlinelibrary.wiley.com/doi/full/10.1111/gcbb.12266"> potential to remain durable</a> (keep the C sequestered) in soil for an extended period; however its durability is subject to similar environmental conditions as Soil Organic Carbon, particularly precipitation and soil water content as it relates to microbial decay. It may also have <a href="https://acsess.onlinelibrary.wiley.com/doi/abs/10.2134/jeq2016.10.0396">positive effects by reducing</a> soil N<sub>2</sub>O emissions (another potent greenhouse gas).</p><h2 id="enhanced-weathering-and-carbon-mineralization">Enhanced weathering and carbon mineralization</h2><p><b>For a more technical overview of this topic, I highly recommend </b><a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00009/full"><b>An Overview of the Status and Challenges of CO</b></a><sub><a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00009/full"><b>2</b></a></sub><a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00009/full"><b>Storage in Minerals and Geological Formations</b></a><b>.</b></p><h3 id="enhanced-weathering-ex-situ">Enhanced weathering – "ex situ"</h3><p><a href="https://en.wikipedia.org/wiki/Ultramafic_rock">Common rocks</a> form carbonate minerals when exposed to CO<sub>2</sub>; often even at atmospheric concentrations; permanently binding the C as a mineral (eg CaCO<sub>3</sub> calcium carbonate).</p><p>On geologic timescales, <a href="https://en.wikipedia.org/wiki/Carbonate–silicate_cycle">this process</a> could restore earth to pre-industrial CO<sub>2</sub> levels. The idea behind "enhanced weathering" is to dramatically accelerate this natural process. <a href="http://projectvesta.org">Project Vestas</a> website provides an accessible walkthrough to this idea. This is sometimes referred to as "ex situ" mineralization because you are mining rocks and putting them through a sped-up carbon mineralization process aboveground.</p><figure class="kg-card kg-gallery-card kg-width-wide kg-card-hascaption"><div class="kg-gallery-container"><div class="kg-gallery-row"><div class="kg-gallery-image" style="flex: 1.11538 1 0%;"><img src="https://www.orbuch.com/content/images/2020/02/Screen-Shot-2020-02-25-at-11.23.49-AM.png" width="1276" height="1144"></div><div class="kg-gallery-image" style="flex: 1.39866 1 0%;"><img src="https://www.orbuch.com/content/images/2020/02/Screen-Shot-2020-02-25-at-11.23.58-AM.png" width="1256" height="898"></div></div></div><figcaption><a href="https://www.earth-syst-dynam-discuss.net/2/551/2011/esdd-2-551-2011-print.pdf">Figures Source</a></figcaption></figure><p>Rocks such as <a href="https://en.wikipedia.org/wiki/Olivine">olivine</a> and <a href="https://en.wikipedia.org/wiki/Serpentinite">serpentinite</a> are particularly effective at CO<sub>2</sub> binding. The amount of carbon captured is generally proportional to the amount of surface area exposed to air, so we want a low-energy way to grind them to the right particle size to optimally bind carbon. <a href="https://www.frontiersin.org/articles/10.3389/fclim.2019.00007/full">More research is needed into the exact kinetics of the mineralization process, other risks (heavy metal release; ecosystem impacts of distributing vast quantities of small rock particles on land or in oceans; etc)</a>; but it is a really interesting idea.</p><h3 id="geologic-sequestration-in-situ">Geologic sequestration - "in situ"</h3><figure class="kg-card kg-image-card kg-card-hascaption"><img src="https://www.orbuch.com/content/images/2020/02/borkjarni_0.jpg" class="kg-image"><figcaption>Carbonate mineral formed on basalt from Carbfixs geothemal injection site in Iceland</figcaption></figure><p>You can think of "in-situ" mineralization as the geologic sequestration component that is crucial to DAC systems.</p><p>It happens when you inject a stream of CO<sub>2</sub> into the right sorts of geologic formations, and <a href="https://science.sciencemag.org/content/352/6291/1312">permanently stores the CO<sub>2</sub> in a minera</a>l. Its called "in-situ" because you are injecting CO<sub>2</sub> to where the rock already is, instead of bringing the rock above ground and exposing it to atmospheric air.</p><hr><h1 id="lifecycle-analysis-and-tradeoffs-of-carbon-removal-approaches">Lifecycle analysis and tradeoffs of carbon removal approaches</h1><p>It’s important to interpret all carbon removal solutions through a lens of a full lifecycle analysis, which can help answer the question: <b>is the entire operation of a given negative emissions solution net-negative?</b></p><p>For BECCS, for example, this analysis would include the greenhouse gas emissions to grow the biomass, the emissions of building the BECCS plant, the emissions of transporting the biomass to the plant, any loss of CO<sub>2</sub> to inefficiencies in the carbon capture system, and the emissions associated with the energy to run the big machine to pump the CO<sub>2</sub> underground.</p><p>All of this would need to<b> add up to less</b> than the volume of CO<sub>2</sub> sequestered -- ideally much less.</p><p>Alongside lifecycle analysis, there are a number of dimensions to evaluate carbon removal solutions. Many of these are an oversimplification; but may be helpful to think about the problem space (it’s extremely difficult or sometimes impossible to be sure about many of these questions):</p><ul><li><b>Efficiency</b> of capture</li></ul><blockquote>Does the energy to run a carbon capture machine emit more CO<sub>2</sub> than the amount we’re capturing (carbon negative lifecycle)?</blockquote><blockquote>How might this change over the coming decades, and how does that affect the cost?</blockquote><ul><li><b>Permanence</b> of storage</li></ul><blockquote>Once it’s captured, what do we need to do to keep it from re-entering the atmosphere? For how long? How much does it cost to do so?</blockquote><ul><li>Ease of <b>measurability/verifiability</b></li></ul><blockquote>Are we sure about exactly how much we’re sequestering?</blockquote><blockquote>Are we sure it won’t leak, or we’ll know right away if it does?</blockquote><blockquote>Who and how will we penalize if this happens?</blockquote><ul><li><b>Opportunity cost / moral hazard</b></li></ul><blockquote>What would we use this land for if we didn’t plant a forest on it?</blockquote><blockquote>How do we know the next land developer won’t burn it down?</blockquote><blockquote>Might this technology slow emissions reduction?</blockquote><ul><li><b>Potential for scale</b></li></ul><blockquote>What’s the upper bound of how much a CO<sub>2</sub> removal technology could sequester? What are the error bars on that estimate?</blockquote><blockquote>How much does a given technology cost today? Is there a path for it to be way cheaper in the coming decades?</blockquote><blockquote>How might innovation and adoption curves inflect over time; either for this technology directly or in its supply chain?</blockquote><ul><li><b>Other constraints or tail risks</b> (often risks to permanence or issues exposed in lifecycle analysis)</li></ul><blockquote>Does this area have the right geology to support pumping CO<sub>2</sub> into the ground?</blockquote><blockquote>What happens to this forest if there’s a regime change or land use regulation change?</blockquote><blockquote>What if the currency in country X crashes, and farmers need more land?</blockquote><blockquote>What if drought/floods caused by a changing climate make this land no longer suitable for the thing we were hoping to do?</blockquote><blockquote>What if X technology doesn’t get cheaper as expected/at the expected rate?</blockquote><hr><h1 id="interesting-and-relevant-things-i-didn-t-discuss-in-this-post">Interesting and relevant things I did not discuss in this post</h1><p>Here’s a small sample of topics relevant/adjacent to concepts discussed here that I’d like to learn more about. If any of these are particularly interesting to you, <a href="http://twitter.com/orbuch">tweet</a> (@orbuch) or email (ryan dot orbuch at gmail) me! You can also think of these as requests for blog posts from people with much more expertise in this field:</p><ul><li>Carbon capture and utilization -- point-source capture/traditional CCS, “carbon-to-value”, “air-to-fuels” and more</li><li>Solar radiation management -- stratospheric sulfate aerosol injection and/or marine cloud brightening as a strategy to buy us more time for emissions reduction</li><li>Traditional carbon offsets; their strengths and weaknesses; what we should learn from them to scale negative emissions purchasing</li><li>Ocean fertilization, ocean liming, direct ocean carbon capture, other ocean stuff</li><li>Unit economics and cost/adoption curves of these carbon sequestration options in detail</li><li>The policy and subsidy landscape around carbon sequestration: 45Q; the California LCFS; the European Emissions Trading System, etc.</li><li>Project finance and how it works for negative emissions and energy projects, how it fits with and differs from other funding sources (VC, private equity, tax equity etc)</li><li>Bioengineering approaches: modifying plants to make them better at capturing/storing carbon; engineering proteins for use in DAC sorbents, etc</li></ul><hr><h1 id="conclusion">Conclusion</h1><p>Here’s what I hope you remember from this piece:</p><ul><li>10-gigaton-scale negative emissions are necessary in essentially every emissions reduction scenario. We have no choice but to fund, research, and deploy them if we’re serious about keeping warming to 2 degrees; or close to it. We are not even close to on track.</li><li>Negative emissions have been dramatically underfunded in proportion to their importance. This needs to be fixed if we’re going to have a shot at reducing the cost enough to make 10-gigaton-scale deployment possible by midcentury. It will take likely take years or decades for basic research and pilot projects to scale and get cheap enough; so we need to start right now.</li><li>It’s very unlikely any one category of technology, or any one natural approach, will scale enough. We should think of a portfolio across all the approaches outlined here, as well as more I didn’t discuss or have yet to be discovered.</li><li>We face the defining problem of our generation; of the entire human project thus far. Climate spans physics, chemistry, ecology, geology, policy, technology, land use, human rights, and more. It’s time we take this seriously as a gigantic opportunity for human progress, and rally to solve it!</li></ul><hr><p>Many people provided feedback on this post, and many more spent time with me over the last few months to help me learn about this field, check my assumptions, and frame my thinking. Thanks in particular to Jeremy Freeman, Christian Anderson, Clay Dumas, Sarah Sclarsic, Peter Reinhardt, Adam Marblestone, Maddie Hall, Klaus Lackner, Nat Keohane, Jennifer Wilcox, Jane Zelikova, Jason Jacobs, April Underwood, Celine Halioua, Florent Crivello, Steve Pacala, Brian Heligman, Michael Nielsen, Jose Luis Ricon, Steve Hamburg, Erika Reinhardt, Alexey Guzey, Ramez Naam, Raylene Yung, Noah Deich, Andrew Bergman, Phil Renforth, Greg Dipple, Giana Amandour, Mason Hartman, Landon Brand, Julio Freedman, Zara Heureux, Jeremy Büttner, Nan Ransohoff, Tamara Winter, and many many more than I could mention here!</p><p>One of the reasons I’ve had so much fun learning about climate is because the people working on it are really great!</p><img src="https://burnzero.com/images/logo.jpg" alt="Snow" style="width:400"><div class="row"><div class="column">
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