By now, the looming dangers of climate change are clear to anyone who’s been paying attention, covered extensively in both academic literature and the popular press.
But what about solutions?
For all the hand-wringing on climate change over the years, discussion of solutions remains puzzlingly anemic and fractured. A few high-profile approaches, mainly around renewable energy and electric cars, dominate discussion and modeling. But there’s been no real way for ordinary people to get an understanding of what they can do and what impact it can have. There remains no single, comprehensive, reliable compendium of carbon-reduction solutions across sectors.
At least until now.
It seems Paul Hawken got tired of waiting.
Hawken is a legend in environmental circles. Since the early 1980s, he has been starting green businesses, writing books on ecological commerce (President Bill Clinton called Hawken’s Natural Capitalism one of the five most important books in the world), consulting with businesses and governments, speaking to civic groups, and collecting honorary doctorates (six so far).
A few years ago, he set out to pull together the careful coverage of solutions that had so long been lacking. With the help of a little funding, he and a team of several dozen research fellows set out to “map, measure, and model” the 100 most substantive solutions to climate change, using only peer-reviewed research.
The result, released last month, is called Drawdown: The Most Comprehensive Plan EverProposed to Reverse Global Warming.
Unlike most popular books on climate change, it is not a polemic or a collection of anecdotes and exhortations. In fact, with the exception of a few thoughtful essays scattered throughout, it’s basically a reference book: a list of solutions, ranked by potential carbon impact, each with cost estimates and a short description. A set of scenarios show the cumulative potential.
The number one solution, in terms of potential impact? A combination of educating girlsand family planning, which together could reduce 120 gigatons of CO2-equivalent by 2050 — more than on- and offshore wind power combined (99 GT).
(Important note: The above comparisons are true in Drawdown’s central, “probable” scenario. There are also more ambitious scenarios, in which each solution is pushed to its full potential. In the “optimum” scenario, onshore wind rises to crush all competitors, reducing 139 GT. All scenarios use only existing, commercialized technologies, so they should be considered conservative. All the solutions, data, and references are available at drawdown.org.)
I spoke with Hawken over a beer when he passed through Seattle on his book tour. He told me the book is already in its third printing, confirming our mutual sense that the public is hungry for this kind of practical wisdom. An edited transcript of our conversation follows, with occasional editorial comments in [brackets].
For the record, explain the term “drawdown.”
Drawdown is the point in time when greenhouse gas concentrations peak in the atmosphere and begin to go down on a year-to-year basis.
[Drawdown’s “plausible” scenario does not reach drawdown. Its second, “drawdown” scenario does. Its third, “optimum” scenario, which maxes out all available technologies, accelerates drawdown.]
So all these models we see in the popular press, the ones that hit, for example, 80 percent carbon reductions by 2050 — none of those actually reach drawdown?
And not only that, they’re about energy — they’re all energy models. There’s an assumption that if you get 100 percent renewable [energy], you basically have a hall pass to the 22nd century. That’s simply not true. It’s a scientific howler. It’s extremely important that we [get to 100 percent renewables], but to put all of it on energy …
[Drawdown has seven categories of solutions: energy, food, women and girls, buildings and cities, land use, transport, and materials. There’s also a “coming attractions” category of not-yet-commercialized technologies, but they are not included in the scenarios.]
How did the book get started?
I hadn’t thought about solutions much until I saw the wedges, in 2001.
[In 2001, scientists at Princeton’s Carbon Mitigation Initiative became famous for proposing a set of “climate stabilization wedges” — efficiency, wind, solar, etc. — to bring emissions down beneath global targets.]
I looked at those and said “whoa, whoa, whoa.” Two things are lacking.
The first is affordability and agency. They couldn’t be done by you and me, except drive less, maybe put a solar panel on our roof.
The second is that 11 of the 15 could only be done by big corporations — primarily energy utility and car companies — but they were so deeply underwater financially that it was not going to happen. It could happen now, but at that time it was not viable.
So … now I am depressed. [laughter] The science was clear, but the solutions were just dramatically not.
And so I finally decided to do Drawdown: name the goal and then map, measure, and model, see if it’s achievable. And away we went, for almost three years, with 70 Drawdown research fellows from 22 countries and six continents.
We went in fairly confident about what the top solutions would be. We were wrong — which is validating, in a way. We have a methodology that forfends against bias.
One thing that jumps out is how different this list looks from what gets discussed most in the media — wind, solar, CCS. Did you go in expecting your list to look more like conventional wisdom?
We thought at least the top of the list would — solar, wind, wind, solar. Because that’s what you hear from Charles Ferguson, Al Gore, [Jeffrey] Sachs, or Christiana Figueres. They’re all saying the same thing.
It’s understandable — 62 percent of the [greenhouse gas] molecules up there came from fossil fuel combustion, so you just invert it, right? It makes sense. It just doesn’t work out that way.
If you take solar, which is eight and 10 [on the list], and wind, which is two and 22, and you combine them, they are definitely near the top. But you can’t model on- and off-shore wind the same, because the economics are vastly different. And you can’t model rooftop and solar farms in the same model. So in some cases we broke things up that people think of as aggregated.
But even then, the number one solution is educating girls and family planning.
How do you put numbers on that?
We took the numbers from other agencies — from World Bank, WHO, IPCC. What they are is the delta between the median high population projections of the UN in 2050 and that reduction alone. There are so many ancillary benefits and impacts of 1.1 billion less people, though.
But it is the 1.1 billion fewer people that is doing the carbon work?
Are there other benign ways of influencing population growth that you considered?
There’s a lack of original science.
Every carbon number [in the book] is peer-reviewed data. We don’t use anecdotal data, or “we think,” or “we’re seeing.” Everything is peer reviewed. If there’s no peer-reviewed data, we can’t model it. And on the economic side, which is more difficult and gnarly, there’s no such thing as peer reviewed data in most cases.
We do lit reviews, tech reviews — we’ve got a couple thousand notes and three thousand references for the content.
We had a guy who’s presenting Drawdown to the [IPCC] Sixth Assessment, the Third Working Group. One of the scientists there took a poke at regenerative agriculture and said, “Well, that’s just climate smart agriculture [CSA], we know about that already.” I wrote back and said, “Show me the model.”
It’s a generality. It doesn’t mean anything. Multistrata agroforestry, fantastic, show me a model. Silvopasture — show me the science. In the process of covering land use, we had to identify what had actually been studied. So we have 22 land-use solutions. We’re splitters, in order to get accurate data.
If you had to guess, what’s the biggest potential contributor that you had to leave out for lack of data?
Because it reduces population?
No, no, no — just the footprint of maintaining standing armies and militaries around the world. It must be extraordinary.
Oh, the carbon benefit of…
Of peace. Yeah. There is one.
How big a role does carbon capture and sequestration (CCS) play in your schema?
None. It’s unaffordable. It doesn’t work. It has to work first, and then has to be affordable. Using carbon capture in Saskatchewan for depleted oil wells isn’t exactly a solution, especially when it’s only 40 percent capture and the company’s depending on the province to subsidize it. There are better results coming out of Texas. We’re watching it.
You can’t achieve drawdown unless you sequester [carbon], but right now the only way we know how to do it in a reliable way is photosynthesis. I mean, there are science experiments going on, but it’s not commercial and it’s not practical.
By the way, we’re doing D2 — Drawdown Two. And it’s all coming attractions that weren’t in D1 — 60 more of them, things that are nascent, on the horizon or just below the horizon. They are game-changers, a lot of them. Some of them will fail. It’s hard to say which will or won’t.
Give me an example.
Direct-air water capture — from low-humidity, not high humidity, environments. You get carbon capture in plant life where you couldn’t before. It could be agriculture, could be perennial, could be afforestation, could be a combination.
You have this effect of moisture just streaming over every Western landscape in the world, usually bypassing it. What could you do with that water?
You have three scenarios. The main one you call the “plausible scenario.”
We modeled the solutions, we scaled them in a rigorous but reasonable way, as they’re all scaling now, using other literature to predict. That’s the first scenario — we think that’s happening. But it does not achieve drawdown.
That’s just based on what’s currently happening, though?
And no new technology. Not one single new technology. That’s why we had the coming attractions; it’s unrealistic to think that this is our portfolio for the next 30 years. It’s not true. That’s why the next book is important — one out of five or six of these [future solutions] is really going to make a difference.
I guess what trips me up is that the scenario you’re calling “plausible” involves reductions in carbon that most modeling outfits would characterize as wildly ambitious.
Our models include a lot of things that were excluded from other models. One is land use. It’s given passing reference, but hasn’t been given much credibility by the IPCC.
They don’t include, for example, farmland restoration — over a billion hectares of abandoned land all over the world. We know how to regenerate that, using animals, using cover, using no-till. Is there a transition cost? Yeah. But it’s a big sink.
It is conventional wisdom that we don’t have any hope on climate change unless we get serious about it — go on war footing. That seems difficult to do without the US federal government.
First of all, let’s be honest: The US has never led in this area. Ever. When they’ve tried on an executive level, they’ve never been supported by Congress. States have led, cities have led, but never the federal government.
Now the federal government is what it is. When [Trump] was elected, I went over every one [of the Drawdown solutions]. I said, “What can the [US federal] government do?” And it really isn’t that much.
I don’t want to in any way whistle past the graveyard of the enormous damage and harm President Trump can do, in terms of security and war and suffering. It’s just that people in the United States think that they’re the leaders on this stuff. They’re not. It’s Germany, China, France, Denmark.
They’re not cueing off the Trump administration. The rest of the world doesn’t take him seriously on this stuff.
This table provides the detailed results of the Plausible Scenario, which models the growth solutions on the Drawdown list based on a reasonable, but vigorous rate from 2020-2050. Results depicted represent a comparison to a reference case that assumes 2014 levels of adoption continue in proportion to the growth in global markets.
NOTE: Energy Storage (utility-scale & distributed), Grid Flexibility, Microgrids, Net Zero Buildings, and Retrofitting were not modeled independently to avoid double counting impacts from other solutions.
|Rank||Solution||Sector||TOTAL ATMOSPHERIC CO2-EQ REDUCTION (GT)||NET COST (BILLIONS US $)||SAVINGS (BILLIONS US $)|
|2||Wind Turbines (Onshore)||Energy||84.60||$1,225.37||$7,425.00|
|3||Reduced Food Waste||Food||70.53||N/A||N/A|
|5||Tropical Forests||Land Use||61.23||N/A||N/A|
|6||Educating Girls||Women and Girls||59.60||N/A||N/A|
|7||Family Planning||Women and Girls||59.60||N/A||N/A|
|12||Temperate Forests||Land Use||22.61||N/A||N/A|
|14||Tropical Staple Trees||Food||20.19||$120.07||$626.97|
|22||Wind Turbines (Offshore)||Energy||14.10||$572.40||$274.57|
|24||Improved Rice Cultivation||Food||11.34||N/A||$519.06|
|27||District Heating||Buildings and Cities||9.38||$457.10||$3,543.50|
|29||Wave and Tidal||Energy||9.20||$411.84||$-1,004.70|
|30||Methane Digesters (Large)||Energy||8.40||$201.41||$148.83|
|31||Insulation||Buildings and Cities||8.27||$3,655.92||$2,513.33|
|33||LED Lighting (Household)||Buildings and Cities||7.81||$323.52||$1,729.54|
|38||Forest Protection||Land Use||6.20||N/A||N/A|
|39||Indigenous Peoples’ Land Management||Land Use||6.19||N/A||N/A|
|42||Heat Pumps||Buildings and Cities||5.20||$118.71||$1,546.66|
|44||LED Lighting (Commercial)||Buildings and Cities||5.04||$-205.05||$1,089.63|
|45||Building Automation||Buildings and Cities||4.62||$68.12||$880.55|
|46||Water Saving – Home||Materials||4.61||$72.44||$1,800.12|
|51||Perennial Biomass||Land Use||3.33||$77.94||$541.89|
|52||Coastal Wetland||Land Use||3.19||N/A||N/A|
|53||System of Rice Intensification||Food||3.13||N/A||$677.83|
|54||Walkable Cities||Buildings and Cities||2.92||N/A||$3,278.24|
|57||Smart Thermostats||Buildings and Cities||2.62||$-74.16||$640.10|
|58||Landfill Methane||Buildings and Cities||2.50||$-1.82||$67.57|
|59||Bike Infrastructure||Buildings and Cities||2.31||$-2,026.97||$400.47|
|61||Smart Glass||Buildings and Cities||2.19||$932.30||$325.10|
|62||Women Smallholders||Women and Girls||2.06||N/A||$87.60|
|64||Methane Digesters (Small)||Energy||1.90||$15.50||$13.90|
|71||Water Distribution||Buildings and Cities||0.87||$137.37||$903.11|
|73||Green Roofs||Buildings and Cities||0.77||$1,393.29||$988.46|
|77||Energy Storage (Distributed)||Energy||N/A||N/A||N/A|
|77||Energy Storage (Utilities)||Energy||N/A||N/A||N/A|
|79||Net Zero Buildings||Buildings and Cities||N/A||N/A||N/A|
|80||Retrofitting||Buildings and Cities||N/A||N/A||N/A|