|An Illustrated Guide to the Science of Global Warming Impacts: How We Know Inaction Is the Gravest Threat Humanity Faces
Humanity’s Choice (via M.I.T.): Inaction (“No Policy”) eliminates most of the uncertainty about whether future warming will be catastrophic. Aggressive emissions reductions greatly improves humanity’s chances.
In this post, I will summarize what the recent scientific literature says are the key impacts we face in the coming decades if we stay anywhere near our current emissions path. These include:
Remember, these will all be happening simultaneously and getting worse decade after decade. Equally tragic, a 2009 NOAA-led study found the worst impacts would be “largely irreversible for 1000 years.”
The single biggest failure of messaging by climate scientists (until very recently) has been the failure to explain to the public, opinion makers, and the media that business-as-usual warming results in simultaneous, ever-worsening impacts that, individually, are each beyond catastrophic, but combined are unimaginablly horrific. For these impacts, terms like “global warming” and “climate change” are essentially euphemisms. That is why I have preferred the term “Hell and High Water.”
By virtue of their success in promoting doubt and inaction, the climate science deniers and disinformers have, tragically and ironically, turned the worst-case scenario into business as usual.
Business as usual typically means continuing at recent growth rates of carbon dioxide emissions, which we now know would likely take us to atmospheric concentrations of CO2 greater than 850 ppm if not above 1000 ppm (see U.S. media largely ignores latest warning from climate scientists: “Recent observations confirm … the worst-case IPCC scenario trajectories are being realised”). Annual emissions now exceed 10 billion metric tons of carbon (~37 billions metric tons of CO2). Emissions have been rising about 3% per year for the past decade.
What is less well understood is that even a very strong mitigation effort that kept carbon emissions this century to 11 billion tons a year on average would still probably take us to 1000 ppm (A1FI scenario) — a little noted conclusion of the 2007 Intergovernmental Panel on Climate Change (IPCC) report (see “Nature publishes my climate analysis and solution“).
Until recently, the scientific community has spent little time modeling the impacts of a tripling (~830 ppm) or quadrupling (~1100 ppm) carbon dioxide concentrations from preindustrial levels. In part, I think, that’s because they never believed humanity would be so self-destructive as to ignore their science-based warnings and simply continue on its unsustainable path. In part, they lowballed the difficult-to-model amplifying feedbacks in the carbon cycle.
So I pieced together those impacts from available studies and from discussions with leading climate scientists for my 2006 book, Hell and High Water. But now the scientific literature on what we face is much richer — as climate scientists have sobered up to their painful role as modern-day Cassandra’s (see Lonnie Thompson on why climatologists are speaking out: “Virtually all of us are now convinced that global warming poses a clear and present danger to civilization”).
In a 2010 AAAS presentation, the late William R. Freudenburg of UC Santa Barbara discussed his research on “the Asymmetry of Scientific Challenge“: New scientific findings since the 2007 IPCC report are found to be more than twenty times as likely to indicate that global climate disruption is “worse than previously expected,” rather than “not as bad as previously expected.”
This post will review the latest findings. It will serve as a foundation for a multi-part series that attempts to clear up some of the confusion over the supposed high degree of “uncertainty” surrounding climate impacts. That series will make clear that we have an unusually high degree of certainty around future climate impacts if we stay anywhere near our current emissions path.
This post covers more than 60 recent scientific studies along with numerous review pieces that themselves each cover a large segment of the recent literature. Please add links to more studies in the comments.
We will see why inaction on climate change is “incompatible with organized global community, is likely to be beyond ‘adaptation’, is devastating to the majority of ecosystems & has a high probability of not being stable (i.e. 4°C [7F] would be an interim temperature on the way to a much higher equilibrium level),” according to Professor Kevin Anderson, director of the Tyndall Centre for Climate Change in Britain (see here).
Three of the best recent analyses of what we are headed towards can be found here:
As Dr. Vicky Pope, Head of Climate Change Advice for the Met Office’s Hadley Centre has explained:
… where no action is taken to check the rise in Greenhouse gas emissions, temperatures would most likely rise by more than 5°C by the end of the century. This would lead to significant risks of severe and irreversible impacts.
That likely rise corresponds to roughly 9°F globally and typically 40% higher than that over inland mid-latitudes (i.e. much of this country) — or well over 10°F.
[Note: The MIT rise is compared to 1980-1999 levels — see study here). So you can add at least 0.5 C and 1.0°F for comparison with pre-industrial temperatures.]
Many other highly credible bodies share this conclusion, including the once-staid and conservative International Energy Agency (see IEA’s Bombshell Warning: We’re Headed Toward 11°F Global Warming and “Delaying Action Is a False Economy”).
Based on two studies in the last few years:
By century’s end, extreme temperatures of up to 122°F would threaten most of the central, southern, and western U.S. Even worse, Houston and Washington, DC could experience temperatures exceeding 98°F for some 60 days a year. Much of Arizona would be subjected to temperatures of 105°F or more for 98 days out of the year–14 full weeks.
Yet that conclusion is based on studies of only 700 ppm and 850 ppm, so it could get much hotter than that.
And the Hadley Center adds, “By the 2090s close to one-fifth of the world’s population will be exposed to ozone levels well above the World Health Organization recommended safe-health level.”
The MIT press release called for “rapid and massive” action to avoid this. Study co-author Ronald Prinn, the co-director of the Joint Program and director of MIT’s Center for Global Change Science, said, it is important “to base our opinions and policies on the peer-reviewed science…. There’s no way the world can or should take these risks.” Duh!
MIT put together a good figure that compares the temperatures we risk on our current do-nothing path with those we might expect if we took serious action [see top figure above]. Note that in the “no policy case” there is an extremely high probability of more than 4°C (7°F) global warming, and about a 25% chance of more than 6°C (11°F) global warming.
In a 2010 presentation, Climate scientist Katherine Hayhoe has a figure of what 1000 ppm would mean (derived from the 2010 NOAA-led report):
For more of the literature on U.S. warming, see “Mother Nature is Just Getting Warmed Up.”
The Hadley Center has a huge but useful figure which I will reproduce here:
Note again that this is not the worst-case scenario. It’s just business as usual out to 2100.
In the worst case, we get both continuing high levels of emissions and high carbon-cycle feedbacks. That possibility was discussed here:
This would be the worst-case for the 2060s, but is in any case, close to business as usual for 2090s:
This is a staggering 13-18°F over most of U.S. and 27°F in the Arctic.
And there is every reason to believe that the earth would just keep getting hotter and hotter:
Steve Easterbrook’s post “A first glimpse at model results for the next IPCC assessment” shows that for the scenario where there is 9°F warming by 2100, you get another 7°F warming by 2300. Of course, folks that aren’t motivated to avoid the civilization-destroying 9°F by 2100 won’t be moved by whatever happens after that.
Prolonged drought and Dust-bowlification — and its impact on food security — may well be the impact that harms the most number of people over the next few decades.
As far back as 1990, scientists at NASA’s Goddard Institute of Space Studies projected that severe to extreme drought in the United States, then happening every 20 years, could become an every-other-year phenomenon by mid-century [Rind et al., 1990].
A number of major recent studies have confirmed those early findings. They warn that the Southwest, parts of the Midwest, and many other highly populated parts of the globe are likely headed toward sustained — if not near permanent — drought and Dust Bowl-like conditions if we stay anywhere near our current emissions path (see “USGS on Dust-Bowlification“).
The Palmer Drought Severity Index (PDSI) in the 2060s and 2090s in a moderate emissions path. A ”reading of -4 or below is considered extreme drought.”
The PDSI in the Great Plains during the Dust Bowl apparently spiked very briefly to -6, but otherwise rarely exceeded -3 for the decade (see here). The study finds:
The large-scale pattern shown in Figure 11 [of which the figure above is part] appears to be a robust response to increased GHGs. This is very alarming because if the drying is anything resembling Figure 11, a very large population will be severely affected in the coming decades over the whole United States, southern Europe, Southeast Asia, Brazil, Chile, Australia, and most of Africa.
The National Center for Atmospheric Research notes “By the end of the century, many populated areas, including parts of the United States and much of he Mediterranean and Africa, could face readings in the range of -4 to -10. Such decadal averages would be almost unprecedented.”
For the record, the NCAR study merely models the IPCC’s “moderate” A1B scenario — atmospheric concentrations of CO2 around 520 ppm in 2050 and 700 in 2100. We’re currently headed much higher by century’s end, but I’m sure with an aggressive program of energy R&D we could keep that to, say 800 ppm.
The projection of extended if not endless drought for the US Southwest (and parts of the Great Plains) has been studied a great deal:
The serious hydrological changes and impacts known to have occurred in both historic and prehistoric times over North America reflect large-scale changes in the climate system that can develop in a matter of years and, in the case of the more severe past megadroughts, persist for decades. Such hydrological changes fit the definition of abrupt change because they occur faster than the time scales needed for human and natural systems to adapt, leading to substantial disruptions in those systems. In the Southwest, for example, the models project a permanent drying by the mid-21st century that reaches the level of aridity seen in historical droughts, and a quarter of the projections may reach this level of aridity much earlier.
An unprecedented combination of heat plus decades of drought could be in store for the Southwest sometime this century, suggests new research from a University of Arizona-led team”….
“The bottom line is, we could have a Medieval-style drought with even warmer temperatures,” [lead author Connie] Woodhouse said.
The literature makes clear future droughts will be fundamentally different from all previous droughts that humanity has experienced because they will be very hot weather droughts (see Must-have PPT: The “global-change-type drought” and the future of extreme weather).
Another 2011 study, “The Last Drop: Climate Change and the Southwest Water Crisis,” that actually looks in some detail at the scientific literature for just one region, finds that drought and reduced precipitation in the U.S. SW alone could cost up to $1 trillion by century’s end.
Finally, while the Dust Bowl lasted under a decade, the NOAA-led study found permanent Dust Bowls in Southwest and around the globe on our current emissions trajectory would be irreversible for many, many centuries:
Again, this is all just business as usual.
From a worst-case perspective, Princeton has done an analysis on “Century-scale change in water availability: CO2-quadrupling experiment,” which is to say 1100 ppm. The grim result: Most of the South and Southwest ultimately sees a 20% to 50% (!) decline in soil moisture.
Finally, the heat and drought drives wildfires. Here’s a National Academies figure from a presentation made by the President’s science adviser Dr. John Holdren in Oslo in 2010, about conditions projected for mid-century:
SEA LEVEL RISE
The 2007 IPCC Fourth Assessment Report (AR4) report ignored dynamic ice-sheet disintegration, which was already happening (see Nature: “Dynamic thinning of Greenland and Antarctic ice-sheet ocean margins is more sensitive, pervasive, enduring and important than previously realized”). The IPCC therefore low-balled sea level rise estimates, suggesting seas might rise “only” a foot or two this century, greatly delighting the anti-science crowd (see here)
Within a year, even a major report signed off on by the Bush administration itself was forced to concede that the IPCC numbers were simply too out of date to be quoted anymore (see US Geological Survey stunner: Sea-level rise in 2100 will likely “substantially exceed” IPCC projections).
A dozen major studies since the IPCC report have concluded that we face much higher sea level rise this century:
Four studies in 2012 provide yet more cause for concern
Needless to say, a sea level rise of one meter by 2100 (nearly 40 inches) would be an unmitigated catastrophe for the planet, even if sea levels didn’t keep rising several inches a decade for centuries, which they inevitably would. The first meter of SLR would flood 17% of Bangladesh, displacing tens of millions of people, and reducing its rice-farming land by 50 percent. Globally, it would create more than 100 million environmental refugees and inundate over 13,000 square miles of this country. Southern Louisiana and South Florida would inevitably be abandoned.
SPECIES LOSS ON LAND AND SEA
In 2007, the IPCC warned that as global average temperature increase exceeds about 3.5°C [relative to 1980 to 1999], model projections suggest significant extinctions (40-70% of species assessed) around the globe. That is a temperature rise over pre-industrial levels of a bit more than 4.0°C. So a 5.5°C rise would likely put extinctions beyond the high end of that range.
Many more studies have raised similar concerns:
And, of course, “When CO2 levels in the atmosphere reach about 500 parts per million, you put calcification out of business in the oceans.” There aren’t many studies of what happens to the oceans as we get toward 800 to 1000 ppm, but it appears likely that much of the world’s oceans, especially in the southern hemisphere, become inhospitable to many forms of marine life. A 2005 Nature study concluded these “detrimental” conditions “could develop within decades, not centuries as suggested previously.”
As for the worst-case scenario, we have:
Yes, some scientists disputed the analysis, but I have seen no refutation in the scientific literature.
If we go to 800 ppm — let alone 1000 ppm or higher — we are far outside the bounds of simple linear projection. Some of the worst impacts may not be obvious — and there may be unexpected negative synergies. The best evidence that will happen is the fact that it is already happened with even a small amount of warming we have seen to date.
“The pine beetle infestation is the first major climate change crisis in Canada” notes Doug McArthur, a professor at Simon Fraser University in Vancouver. The pests are “projected to kill 80 per cent of merchantable and susceptible lodgepole pine” in parts of British Columbia within 10 years — and that’s why the harvest levels in the region have been “increased significantly.”
As quantified in the journal Nature, “Mountain pine beetle and forest carbon feedback to climate change,” (subs. req’d), which just looks at the current and future impact from the beetle’s warming-driven devastation in British Columbia:
… the cumulative impact of the beetle outbreak in the affected region during 2000–2020 will be 270 megatonnes (Mt) carbon (or 36 g carbon m-2 yr-1 on average over 374,000 km2 of forest). This impact converted the forest from a small net carbon sink to a large net carbon source.
No wonder the carbon sinks are saturating faster than we thought (see here) — unmodeled impacts of climate change are destroying them:
Insect outbreaks such as this represent an important mechanism by which climate change may undermine the ability of northern forests to take up and store atmospheric carbon, and such impacts should be accounted for in large-scale modelling analyses.
And the bark beetle is slamming the Western U.S. and Alaska, too (see “Oldest Utah newspaper: Bark-beetle driven wildfires are a vicious climate cycle“).
An April 2012 study explained, “Global Warming is Doubling Bark Beetle Mating, Boosting Tree Attacks Up To 60-Fold, Study Finds.”
The key point is this catastrophic climate change impact and its carbon-cycle feedback were not foreseen even a dozen years ago — which suggests future climate impacts will bring other equally unpleasant surprises, especially as we continue on our path of no resistance.
One of the basic predictions of climate science is that extreme weather will make the hydrological cycle more extreme. I’ve already discussed the extensive (and growing) literature on how dry areas will get drier. But wet areas will also get wetter:
1) Here we show that human-induced increases in greenhouse gases have contributed to the observed intensification of heavy precipitation events found over approximately two-thirds of data-covered parts of Northern Hemisphere land areas. These results are based on a comparison of observed and multi-model simulated changes in extreme precipitation over the latter half of the twentieth century analysed with an optimal fingerprinting technique.
Changes in extreme precipitation projected by models, and thus the impacts of future changes in extreme precipitation, may be underestimated because models seem to underestimate the observed increase in heavy precipitation with warming.
2) Occurring during the wettest autumn in England and Wales since records began in 1766 these floods damaged nearly 10,000 properties across that region, disrupted services severely, and caused insured losses estimated at £1.3 billion….
… it is very likely that global anthropogenic greenhouse gas emissions substantially increased the risk of flood occurrence in England and Wales in autumn 2000.
That post ended with its own review of the literature on the connection between global warming and extreme weather. Here are several more recent studies on how warming is already making our weather more extreme:
A new study by a Duke University-led team of climate scientists suggests that global warming is the main cause of a significant intensification in the North Atlantic Subtropical High (NASH) that in recent decades has more than doubled the frequency of abnormally wet or dry summer weather in the southeastern United States….
The models – known as Coupled Model Intercomparison Project Phase 3 (CMIP3) models – predict the NASH will continue to intensify and expand as concentrations of carbon dioxide and other greenhouse gases increase in Earth’s atmosphere in coming decades.”This intensification will further increase the likelihood of extreme summer precipitation variability – periods of drought or deluge – in southeastern states in coming decades,” Li says.
The team calculates that a 1 ºC increase in sea-surface temperatures would result in a 31% increase in the global frequency of category 4 and 5 storms per year: from 13 of those storms to 17. Since 1970, the tropical oceans have warmed on average by around 0.5 ºC. Computer models suggest they may warm by a further 2 ºC by 2100.
The very latest science suggests we may actually be in the midst of a quantum leap or step-function change in extreme weather because of warming-driven Arctic ice loss:
In over two decades of tracking world food prices, the U.N. Food and Agricultural Organization index has never stayed so high for so long.
This represents true suffering for hundreds of millions of people who live on the edge, for whom food is a large fraction of their income like, say, North Africa (see Expert consensus grows on contribution of record high food prices to Middle East unrest).
Population growth, dietary shifts, growing use of crops for biofuels, peaking conventional oil production and increases in extreme weather have all played a part. As the literature above makes clear, on our current emissions path, we face:
One analysis just of the impact of temperature rise on food finds “Half of world’s population could face climate-driven food crisis by 2100.” And this is just a 700 ppm analysis with no discussion of the impact of soil drying up or other well-understood climate impacts.
Two major Oxfam studies in the past 12 months show the impact global warming poses to food prices. First we had “Extreme Weather Has Helped Push Tens of Millions into ‘Hunger and Poverty’in ‘Grim Foretaste’ of Warmed World,” with this chart:
Further modeling the impact of warming-driven extreme weather shocks lead Oxfam to conclude corn prices could increase a staggering 500% by 2030:
The “additional price increase” percentage (olive green bars) is calculated off the original price increase.
For the foreseeable future, the “Climate Story of the Year is that Warming-Driven Drought and Extreme Weather Emerge as Key Threat to Global Food Security.”
DIRECT HEALTH IMPACTS
In 2011 the British Medical Journal warned that climate change “poses an immediate and grave threat, driving ill-health and increasing the risk of conflict, such that each feeds upon the other.” The UK’s Hadley Center notes that on our current one related impact, “By the 2090s close to one-fifth of the world’s population will be exposed to ozone levels well above the World Health Organization recommended safe-health level.”
A June 2011 peer-reviewed report released by the Union of Concerned Scientists (UCS) — “Climate Change and Your Health: Rising Temperatures, Worsening Ozone Pollution” — shows that the harm to Americans, especially children, from human-caused warming is upon us now.
A just-released September 2011 report by the European Lung Foundation finds:
Scientists are warning that death rates linked to climate change will increase in several European countries over the next 60 yrs.
Earlier this year, Climate Progress reported on what the top medical and health groups warn are the health risks Americans face from climate change:
The possibility that unrestricted emissions of greenhouse gases would not do unimaginable harm to humanity has become vanishingly small. That’s because:
And I haven’t even discussed the many, many studies that suggest in fact carbon-cycle feedbacks (like the defrosting tundra) are almost all positive (amplifying) and yet largely ignored in most climate models:
So it’s no surprise that many climate impacts are coming much faster than the models had predicted:
Arctic Sea Ice is melting much, much faster than even the best climate models had projected. The reason is most likely unmodeled amplifying feedbacks. Image via Arctic Sea Ice Blog.
Inaction means humanity’s self-destruction. We must pay any price or bear any burden to stop catastrophic climate change.
Climate Change 101 – Inaction is the greatest threat