Long-Term Adaptations

Figure 1 – Scene from “The Martian”

I was considering using a more descriptive title for the coming series of blogs, inspired by a recent article in the New York Times (NYT) called, “How to Survive the Apocalypse?” The article starts as follows:

President Trump threatens to “totally destroy North Korea.” Another hurricane lashes out. A second monster earthquake jolts Mexico. Terrorists strike in London. And that’s just this past week or so.

Yes, the world is clearly coming to an end. But is there anything you can do to prepare?

Prudence won out and I decided on a much better-defined option. My last 7 blogs (August 29October 10, 2017) focused on the doomsday that business-as-usual scenarios are projected to bring about. Based on early signs already visible today, this catastrophe will come from human changes to the physical environment; the world is expected to reach full-force uninhabitability toward the end of the century.

My school’s Faculty Day in May featured a panel presentation, “The Role of Science in the Anthropocene.” The audience’s questions mirrored those posited in the NYT article: is there anything we can do to prepare? Or are we doomed? – in which case we should just try to enjoy our last days as happily as we can.

Almost every day now brings new calamities that originate from our changes to the physical environment. The most recent are the deadly fires throughout California. Similarly extensive fires have recently been recorded around the Mediterranean Sea and Australia. I am not alone in discussing the US government’s ineptitude in dealing with the physical calamities of climate change. I got sick of being depressed and decided to try to answer the question, “what can we do to prepare?”

The NYT piece was half-satirical and focused on how individuals could start to prepare their own disaster tool kits for local threats. My take will be more serious, collective, and global. The transition to doomsday that I am interested in is different from singular apocalyptic doomsday events such as a nuclear holocaust, the eruption of a super volcano, or the collision of a large asteroid. While we can obviously try to adapt to or mitigate most of those terrible occurrences, none of them is foreseen to impact us the way that climate change based on a business-as-usual scenario will. The eventual uninhabitability that will come from continuing our present changes to the chemistry of the atmosphere will occur gradually – within the span of a few human generations. We can still mitigate it considerably and at the same time try to develop technologies that will help us adapt.

In one of my earliest blogs, I defined the physics of sustainability (January 28, 2013):

I define sustainability as the condition that we have to develop here to flourish until we develop the technology for extraterrestrial travel that will allow us to move to another planet once we ruin our own.

In my opinion, the conditions to achieve this are very “straightforward.” They have to be able to answer two “simple” questions:

  • For how long? – Forever! To repeat President Obama’s language – We must act, knowing that today’s victories will be only partial, and that it will be up to those who stand here in four years, and forty years, and four hundred years hence to advance the timeless spirit once conferred to us in a spare Philadelphia hall

  • How to do it? – To achieve the sustainable objectives on this time scale, we will have to establish equilibrium with the physical environment and at the same time maximize individual opportunities for everybody on this planet

This will take time. A better definition would incorporate the options of attempting to establish livability wherever we can, including the soon-to-be-uninhabitable planet Earth.

How can we adapt to an uninhabitable planet? This is basically the same question as, “is there anything you can do to prepare?”

Well, what came to my mind was the movie, “The Martian” – with Matt Damon and Jessica Chastain – about an astronaut who got stuck on Mars and is trying to adapt. Figure 1 shows an example of his efforts. The movie was released toward the end of 2015 and received a Golden Globe Award for Best Picture in the category of Musical or Comedy. As Matt Damon said while receiving the award, it certainly was not a musical and the only funny thing about it was the category in which it was placed. It was a very serious, excellent movie. It described in great detail the work that the astronaut had to put into trying to survive on the uninhabitable surface of Mars.

David Wallace-Wells’ New York Magazine piece, which I discussed in my September 12, 2017 and subsequent blogs, presented decent qualitative descriptions of the main indicators of uninhabitability brought about by climate change:

  • Heat death
  • The end of food
  • Climate plagues
  • Unbreathable air
  • Perpetual war
  • Permanent economic collapse
  • Poisoned oceans

The end of the world as we know it will happen in phases. Some areas will become uninhabitable before others and that shift will likely be the main trigger for an indicator such as perpetual war. In a business-as-usual scenario, the transition will soon engulf the entire planet. How do we adapt to this kind of an environment? Perhaps we’ll simply have to take a page from Matt Damon and learn how to live happily while isolated from the environment. In the next few blogs I will go into more detail.

Be Sociable, Share!
Posted in administration, Anthropocene, Anthropogenic, Climate Change, Sustainability, Trump | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Doomsday: Local Timelines

The last few blogs focused on the ultimate consequences of continuing to make “progress” by relentlessly using the physical environment to serve humanity as if it were as a limitless resource. I tried to make the case that such efforts (business-as-usual scenarios) push the planet outside the window of habitability, with no place to go. The now fully-anticipated result is global doomsday. The expected timeline is uncertain but can be counted within a few hundred years. For people such as myself, who grew up exposed to thousands of years of history, these prospects are unacceptable – particularly because it is still within our power to prevent or at least considerably postpone this impact. Such an apocalyptic scenario obviously will not take place instantaneously on a global scale. It will start with a slowly expanding area of habitable local environments turning uninhabitable and their residents fleeing to friendlier places. Such a migration creates millions of environmental refugees and affect us all. This is not a speculation on an unknown future. It is already happening. This is the main reason that national security organizations are trying to understand the changes in the physical environment and how they affect its ability to support humans (See the “Global Trends 2035” blog, May 23, 2017).

In this blog I will try to quantify the criteria for local doomsdays with some concrete examples, starting with the concept of Wet Bulb temperature:

Wet Bulb Temperature – Twb

The Wet Bulb temperature is the adiabatic saturation temperature.

Wet Bulb temperature can be measured by using a thermometer with the bulb wrapped in wet muslin. The adiabatic evaporation of water from the thermometer bulb and the cooling effect is indicated by a “wet bulb temperature” lower than the “dry bulb temperature” in the air.

The rate of evaporation from the wet bandage on the bulb, and the temperature difference between the dry bulb and wet bulb, depends on the humidity of the air. The evaporation from the wet muslin is reduced when air contains more water vapor.

The Wet Bulb temperature is always between the Dry Bulb temperature and the Dew Point. For the wet bulb, there is a dynamic equilibrium between heat gained because the wet bulb is cooler than the surrounding air and heat lost because of evaporation. The wet bulb temperature is the temperature of an object that can be achieved through evaporative cooling, assuming good air flow and that the ambient air temperature remains the same.

Steven Sherwood and Matthew Huber wrote a paper, “An adaptability limit to climate change due to heat stress,” about the connections between Wet-Bulb temperatures and local limits of habitability. It was published in the Proceedings of the National Academy of Sciences (PNAS). Here is the abstract and some of their conclusions:


Despite the uncertainty in future climate-change impacts, it is often assumed that humans would be able to adapt to any possible warming. Here we argue that heat stress imposes a robust upper limit to such adaptation. Peak heat stress, quantified by the wet-bulb temperature TW, is surprisingly similar across diverse climates today. TW never exceeds 31 °C. Any exceedance of 35 °C for extended periods should induce hyperthermia in humans and other mammals, as dissipation of metabolic heat becomes impossible. While this never happens now, it would begin to occur with global-mean warming of about 7 °C, calling the habitability of some regions into question. With 11–12 °C warming, such regions would spread to encompass the majority of the human population as currently distributed. Eventual warmings of 12 °C are possible from fossil fuel burning. One implication is that recent estimates of the costs of unmitigated climate change are too low unless the range of possible warming can somehow be narrowed. Heat stress also may help explain trends in the mammalian fossil record.


We conclude that a global-mean warming of roughly 7 °C would create small zones where metabolic heat dissipation would for the first time become impossible, calling into question their suitability for human habitation. A warming of 11–12 °C would expand these zones to encompass most of today’s human population. This likely overestimates what could practically be tolerated: Our limit applies to a person out of the sun, in gale-force winds, doused with water, wearing no clothing, and not working. A global-mean warming of only 3–4 °C would in some locations halve the margin of safety (difference between TW max and 35 °C) that now leaves room for additional burdens or limitations to cooling. Considering the impacts of heat stress that occur already, this would certainly be unpleasant and costly if not debilitating. More detailed heat stress studies incorporating physiological response characteristics and adaptations would be necessary to investigate this.

If warmings of 10 °C were really to occur in next three centuries, the area of land likely rendered uninhabitable by heat stress would dwarf that affected by rising sea level. Heat stress thus deserves more attention as a climate-change impact.

The onset of TW max > 35 °C represents a well-defined reference point where devastating impacts on society seem assured even with adaptation efforts. This reference point constructs with assumptions now used in integrated assessment models. Warmings of 10 °C and above already occur in these models for some realizations of the future (33). The damages caused by 10 °C of warming are typically reckoned at 10–30% of world GDP (33, 34), roughly equivalent to a recession to economic conditions of roughly two decades earlier in time. While undesirable, this is hardly on par with a likely near-halving of habitable land, indicating that current assessments are underestimating the seriousness of climate change.

The paper by Eun-Soon Im et al. in Science Advances, 2017, 3(8), “Deadly heat waves projected in the densely populated agricultural regions of South Asia,” describes the evolving situation in South Asia. Here are a few key paragraphs from that paper that describe the main conclusions. They include the physiological criteria of the concept of hyperthermia, as mentioned in the previous paper:


The risk associated with any climate change impact reflects intensity of natural hazard and level of human vulnerability. Previous work has shown that a wet-bulb temperature of 35°C can be considered an upper limit on human survivability. On the basis of an ensemble of high-resolution climate change simulations, we project that extremes of wet-bulb temperature in South Asia are likely to approach and, in a few locations, exceed this critical threshold by the late 21st century under the business-as-usual scenario of future greenhouse gas emissions. The most intense hazard from extreme future heat waves is concentrated around densely populated agricultural regions of the Ganges and Indus river basins. Climate change, without mitigation, presents a serious and unique risk in South Asia, a region inhabited by about one-fifth of the global human population, due to an unprecedented combination of severe natural hazard and acute vulnerability


The risk of human illness and mortality increases in hot and humid weather associated with heat waves. Sherwood and Huber (1) proposed the concept of a human survivability threshold based on wet-bulb temperature (TW). TW is defined as the temperature that an air parcel would attain if cooled at constant pressure by evaporating water within it until saturation. It is a combined measure of temperature [that is, dry-bulb temperature (T)] and humidity (Q) that is always less than or equal to T. High values of TW imply hot and humid conditions and vice versa. The increase in TW reduces the differential between human body skin temperature and the inner temperature of the human body, which reduces the human body’s ability to cool itself (2). Because normal human body temperature is maintained within a very narrow limit of ±1°C (3), disruption of the body’s ability to regulate temperature can immediately impair physical and cognitive functions (4). If ambient air TW exceeds 35°C (typical human body skin temperature under warm conditions), metabolic heat can no longer be dissipated. Human exposure to TW of around 35°C for even a few hours will result in death even for the fittest of humans under shaded, well-ventilated conditions (1). While TW well below 35°C can pose dangerous conditions for most humans, 35°C can be considered an upper limit on human survivability in a natural (not air-conditioned) environment. Here, we consider maximum daily TW values averaged over a 6-hour window (TWmax), which is considered the maximum duration fit humans can survive at 35°C.


To study the potential impacts of climate change on human health due to extreme TW in South Asia, we apply the Massachusetts Institute of Technology Regional Climate Model (MRCM) (24) forced at the lateral and sea surface boundaries by output from three simulations from the Coupled Model Intercomparison Project Phase 5 (CMIP5) coupled Atmosphere-Ocean Global Climate Model (AOGCM) experiments (25). By conducting high-resolution simulations, we include detailed representations of topography and coastlines as well as detailed physical processes related to the land surface and atmospheric physics, which are lacking in coarser-resolution AOGCM simulations (26). On the basis of our comparison of MRCM simulations driven by three AOGCMs for the historical period 1976–2005 (HIST) against reanalysis and in situ observational data, MRCM shows reasonable performance in capturing the climatological and geographical features of mean and extreme TW over South Asia. Furthermore, the mean biases of MRCM simulations are statistically corrected at the daily time scale to enhance the reliability of future projections (see Materials and Methods). We project the potential impacts of future climate change toward the end of century (2071–2100), assuming two GHG concentration scenarios based on the RCP trajectories (27): RCP4.5 and RCP8.5. RCP8.5 represents a BAU scenario resulting in a global CMIP5 ensemble average surface temperature increase of approximately 4.5°C. RCP4.5 includes moderate mitigation resulting in approximately 2.25°C average warming, slightly higher than what has been pledged by the 2015 United Nations Conference on Climate Change (COP21).

On the basis of the simulation results, TWmax is projected to exceed the survivability threshold at a few locations in the Chota Nagpur Plateau, northeastern India, and Bangladesh and projected to approach the 35°C threshold under the RCP8.5 scenario by the end of the century over most of South Asia, including the Ganges river valley, northeastern India, Bangladesh, the eastern coast of India, Chota Nagpur Plateau, northern Sri Lanka, and the Indus valley of Pakistan (Fig. 2). Under the RCP4.5 scenario, no regions are projected to exceed 35°C; however, vast regions of South Asia are projected to experience episodes exceeding 31°C, which is considered extremely dangerous for most humans (see the Supplementary Materials). Less severe conditions, in general, are projected for the Deccan Plateau in India, the Himalayas, and western mountain ranges in Pakistan.

Many urban population centers in South Asia are projected to experience heat waves characterized by TWmax well beyond 31°C under RCP8.5 (Fig. 2). For example, in Lucknow (Uttar Pradesh) and Patna (Bihar), which have respective current metro populations of 2.9 and 2.2 million, TW reaches and exceeds the survivability threshold. In most locations, the 25-year annual TWmax event in the present climate, for instance, is projected to become approximately an every year occurrence under RCP8.5 and a 2-year event under RCP4.5 (Fig. 2 and fig. S1). In addition to the increase in TWmax under global warming, the urban heat island effect may increase the risk level of extreme heat, measured in terms of temperature, for high-density urban population exposure to poor living conditions. However, Shastri et al. (28) found that urban heat island intensity over many Indian urban centers is lower than in non-urban regions along the urban boundary during daytime in the pre-monsoon summer because of the relatively low vegetation cover in non-urban areas.

We all live “locally,” as do our friends and families. It is not surprising that we are most interested in the projections for climate change in our local environments. Uncertainties in long-term projections for local environments are much greater than those regarding global projections. However, our ability to mitigate and adapt to local environmental changes reflects our skills in making decisions with regard to other, global risks.

Some localities published their projections based on the highest global spatial resolution simulations that they could find, while others are conducting dedicated local simulations. Simulations, local or global, depend on how we run our lives. Usually we follow the IPCC’s practices and make our forecasts based on scenarios similar to those which it publishes.

If we live in big cities, websites like “Climate Central” are good sources to start with. Some of its guidelines are given below, along with a global map of the cities that the site covers:

Summers around the world are already warmer than they used to be, and they’re going to get dramatically hotter by century’s end if carbon pollution continues to rise. That problem will be felt most acutely in cities.

The world’s rapidly growing population coupled with the urban heat island effect — which can make cities up to 14°F (7.8°C) warmer than their leafy, rural counterparts —  add up to a recipe for dangerous and potentially deadly heat.

Currently, about 54 percent of the world’s population lives in cities, and by 2050 the urban population is expected to grow by 2.5 billion people. As those cities get hotter, weather patterns may shift and make extreme heat even more common. That will in turn threaten public health and the economy.

Figure 1

Here’s a short, personal, account of the current circumstances in Phoenix, Arizona and its future prospects:

Sorry to put such a fine point on this, but even without climate change, Phoenix, Arizona, is already pretty uninhabitable. Don’t get me wrong, I spend a fair amount of time there, and I love it—particularly in the fall and winter—but without air-conditioning and refrigeration, it would be unlivable as is. Even with those modern conveniences, the hottest months take their toll on my feeble Southern Californian body and brain. The historical average number of days per year in Phoenix that hit 100 degrees is a mind-bending 92. But that number is rapidly rising as climate change bears down on America’s fifth-largest city.

“It’s currently the fastest warming big city in the US,” meteorologist and former Arizonan Eric Holthaus told me in an email. A study from Climate Central last year projects that Phoenix’s summer weather will be on average three to five degrees hotter by 2050. Meanwhile, that average number of 100-degree days will have skyrocketed by almost 40, to 132, according to another 2016 Climate Central study. (For reference, over a comparable period, New York City is expected to go from two to 15 100-degree days.)

I live in New York City. Periodically (usually following new IPCC reports) the city compiles an up-to-date report on how climate change will impact the city, based on the best available information. The information is published in a full dedicated issue of the “Annals of the New York Academy of Sciences” for everyone to see.

The press has picked this up:

Climate change will come to New York the same way water boils around one of those mythical frogs. The city will be the same old New York in 2050; people won’t be frying eggs on the manhole covers in the summer, or riding gondolas around Times Square. But by then winter will have fewer than 50 days of freezing cold, instead of the average of 72 that was the norm in the late 20th century. There will be less shivering agony on train platforms, plus less salting and shoveling. But the summers will be harsher—half a dozen heat waves instead of the usual two, and those heat waves will be even longer and more sweltering than usual; there will be twice as many plus-90-degree days as there once were. In 2006, a brutal summer led to 140 people dying of heat-related causes; it’s safe to say that that sort of death toll will be routine by 2050.

All of that is according to the estimates in the 2013 Climate Risk Information report from the New York City Panel on Climate Change (I’m using that report’s low or median estimates). As one of America’s wealthiest and most liberal big cities—where even some prominent Republicans are staunch climate hawks—it’s not surprising that New York would commission a report like that, or take other steps toward fighting the effects of climate change. But even with all the resources of the five boroughs, that’s a tall order.

Next week I will leave aside the depressing topic of imminent doomsdays and try to address our options for mitigating or at least postponing them.

Be Sociable, Share!
Posted in Anthropocene, Anthropogenic, Climate Change, immigration, IPCC, Sustainability, UN | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Doomsday: Attributions

The high concentration of natural disasters taking place all over the world includes:

  • Hurricanes and cyclones such as Harvey, with its flooding of Houston and the rest of Southern Texas and Louisiana, Maria and its devastating destruction of Puerto Rico and other Caribbean islands, Irma and its impact on Florida, and the flooding in India, Pakistan, and Nepal
  • Mudslides in Sierra Leone
  • Deadly Mexican earthquakes
  • Bushfires in Queensland, Australia, where temperature reached 42.5oC (109oF), the Canary Islands, and Southern California

These have resulted in the combined loss of hundreds of lives, the displacement of millions who have lost their homes, and collective fiscal losses that are fast approaching trillions of dollars. The recovery will take months if not years.

For people directly affected, the impacts certainly felt like doomsday, the end of the world, the Sixth Extinction, or whatever else you are inclined to call a global calamity. For the new GOP Senate candidate from the State of Alabama, all of these are just signs of God’s unhappiness the human race for engaging in certain activities (of which Mr. Moore does not approve).

In the last few blogs, I have dealt with various aspects of future impacts of our activities on the physical environment and how they will result in global doomsday. I have phrased it as occurring in the near future that I defined broadly as “now”: within the lifetime of my grandchildren. Here we are talking about the literal “now” in local communities, countries and regions.

A valid question to ask is how do we know (and how sure are we) that human activity has made a significant contribution to these existential disasters – which means that some of the dangers are within our power to mitigate.

Here is how Wikipedia defines attributions of climate change:

Attribution of recent climate change is the effort to scientifically ascertain mechanisms responsible for recent climate changes on Earth, commonly known as ‘global warming‘. The effort has focused on changes observed during the period of instrumental temperature record, when records are most reliable; particularly in the last 50 years, when human activity has grown fastest and observations of the troposphere have become available. The dominant mechanisms are anthropogenic, i.e., the result of human activity. They are:[3]

There are also natural mechanisms for variation including climate oscillations, changes in solar activity, and volcanic activity.

According to the Intergovernmental Panel on Climate Change (IPCC), it is “extremely likely” that human influence was the dominant cause of global warming between 1951 and 2010.[4] The IPCC defines “extremely likely” as indicating a probability of 95 to 100%, based on an expert assessment of all the available evidence.[5]

As the scope of the climate events changes, so will the way in which we attribute human contributions. The attribution of global climate change will also be different than that of local weather events. Attributions will likewise differ for past events and predicted future events.

According to the IPCC, its measurements of our historical impacts on the global climate make it 95% certain of humans’ dominant contributions to climate change. A summary of the IPCC report of human contributions can be found here.

Visual summaries of the various observations are given in Figures 1 and 2.

Attribution of global warming – simulation of 20th century global mean temperatures (with and without human influences) compared to observations (NASA)Figure 1 – Attribution of global warming – simulation of 20th century global mean temperatures (with and without human influences) compared to observations (NASA)

Figure 1 shows a computer analysis of observed global temperature change over the 20th Century. The analyses of conditions with and without human contributions show only short-term fluctuations until mid-century, after which they split sharply. Toward the end of the century the global temperature without human contributions is a bit lower than in the beginning – a difference attributed mainly to the impact of volcanic eruptions (which result in a slight cooling immediately afterward). The observed temperature change is close to 1oC, in agreement with that calculated to include human contributions. In the case that exactly 100% means full accounting for the temperature increase relative to the prediction of slightly lower temperatures without human contributions, this shows a human contribution to climate change of more than 100% over this period.

Atmospheric and anthropogenic CO2 and 14C in tree ringsFigure 2

The main forcing mechanism of human contribution to the climate is the carbon dioxide emitted through burning of fossil fuels. Figure 2 shows the correlations between the measured changes of the atmospheric concentrations of carbon dioxide compared with the human-caused emissions. The curves look similar in shape; both of them kick sharply up in the middle of the 20th Century. Unfortunately, the two curves are shown in different units so direct comparisons are impossible. I am teaching my General Education students how to make such comparisons, using the tools from my book, Climate Change: The Fork at the End of Now. I am not going to repeat the calculation here. You will have to take my word that the jump in atmospheric concentration of carbon dioxide from 1950 to 2000 taken from the figure amounts to about 0.4 trillion tons of carbon dioxide while the human emissions amount to 0.5 trillion tons of carbon dioxide. These numbers are a rough approximation but are close enough to convince us that they are closely related. Section c of the same figure provides probably the most convincing evidence for the origin of this extra carbon dioxide.

Here is the background:

14C is a radioisotope of carbon with atoms that contain 6 protons and 8 neutrons as compared to the more abundant isotope of carbon (12C), which contains 6 protons and 6 neutrons. The radioisotope is unstable and slowly converts to nitrogen (14N) by converting one neutron to one proton. The conversion rate is measured through a parameter called half-time. It means that if we start with a certain amount of the material, half of it will convert into 14N in that period of time. The half-life of 14C is 5,730 years. The natural abundance of this isotope in the atmosphere is about one atom in a trillion. Plants that grow by photosynthesis of carbon dioxide in the atmosphere end up with the same amount of the carbon isotope.

Combustible fossil fuels such as coal, natural gas (mainly methane), gasoline, and various oils, are deposits of organic materials formed from decayed plants and animals. These organisms were alive many millions of years ago – way longer than 5,730 years – so all of their 14C had plenty of time to decay completely. In other words, any emissions of this type of more stabilized carbon dioxide into the atmosphere should reduce the atmospheric concentration of 14C. This reduction is shown in Figure 2c. Unfortunately, this experiment had to stop around mid century because of the prevalence of nuclear atmospheric testing at that time, which added a great deal of 14C to the atmosphere. We are left with the convincing data up until that time. Most of the carbon dioxide that we added to the atmosphere until that time came from combustible fossil fuel use. Carbon dioxide is the main anthropogenic greenhouse gas connected to our energy use (see June 25, 2012 blog or search for “greenhouse gas emissions” throughout the blog). The increase in temperature shown in Figure 1 came mostly from that same addition of carbon dioxide to the atmosphere from burning those fossil fuels.

The increase in temperature has immediate consequences.

Figure 3 shows one important consequence of an increase in average temperature. It shows two identical distributions of temperature over the same time period with a small shift to an overall higher temperature. If we define an extreme heat event through frequency of a fixed high temperature such as 100oF (how many days in a year we reach that target temperature or higher), the figure clearly shows that the probability of the extreme event increases greatly.

Figure 3 – Attribution of Extreme Weather Events in the Context of Climate Change

The anthropogenic increase in global temperature has other direct implications.

A vital implication from an important law in Physical Chemistry called the Clausius Clapeyron Equation tells us that the vapor pressure of almost all liquids steadily increases as the temperature increases. That means that the amount of humidity in the atmosphere is increasing as we warm the planet. Most of the impacts of the increase in global temperature manifest themselves through the water cycle: rise in sea level, increased desertification through enhanced transpiration and heightened land evaporation, shifts in precipitation patterns, etc.

Next week I will focus on how climate change is impacting some specific areas as well as some steps that we need to take right now to mitigate (minimize) and adapt to these dangers.

Be Sociable, Share!
Posted in Anthropocene, Anthropogenic, Climate Change, IPCC, Sustainability | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Doomsday: Timing?

Figure 1 – IPCC projections of future climate change impacts based on two different scenarios

Figure 2 – Relationship between global mean equilibrium temperature change and stabilization concentration of greenhouse gases

Trying to estimate the timing of doomsday is not a very honorable activity. Doomsday theorists abound and they don’t enjoy a great reputation for accuracy. Here’s a historical list of such apocalyptic predictions.

I feel more comfortable, substituting doomsday with the phrase 6th Mass Extinction – as used in the PNAS article that I described last week – or “self-inflicted genocide,” a term I have used repeatedly here, even though that relabeling might be considered a matter of semantics. By using these terms, scientists are less afraid of being labeled as false prophets; we consider some of the societal and political activities happening now as existential threats, greatly heightening the feasibility of doomsday scenarios.

I have used Figures 1 and 2 from the IPCC report on various occasions throughout this blog (the earliest being December 10, 2012). The WG1 scenario’s sharp climb into the dark orange zone demonstrates our rocketing towards doomsday, an existential danger that needs to be halted immediately. Reaching this situation by the end of the century in a business-as-usual scenario seems reasonable. Such a sharp marker doesn’t exist in Figure 2, which expresses the future in terms of carbon accumulation in the atmosphere. Daniel Rothman from MIT just put out a paper that works to close that gap, analyzing changes in the carbon cycle that have triggered all the recorded mass extinctions over the last 500 million years (Daniel H. Rothman. “Thresholds of catastrophe in the Earth system,” Science Advances, 2017):

Thresholds of catastrophe in the Earth system

Daniel H. Rothman

The history of the Earth system is a story of change. Some changes are gradual and benign, but others, especially those associated with catastrophic mass extinction, are relatively abrupt and destructive. What sets one group apart from the other? Here, I hypothesize that perturbations of Earth’s carbon cycle lead to mass extinction if they exceed either a critical rate at long time scales or a critical size at short time scales. By analyzing 31 carbon isotopic events during the past 542 million years, I identify the critical rate with a limit imposed by mass conservation. Identification of the crossover time scale separating fast from slow events then yields the critical size. The modern critical size for the marine carbon cycle is roughly similar to the mass of carbon that human activities will likely have added to the oceans by the year 2100.

The threshold seems to be the same. Last week, a paper in Nature Geoscience (September 18, 2017) called into question some of the IPCC’s carbon dioxide estimates (GtC = gigatons of carbon = billion tons of carbon):

Emission budgets and pathways consistent with limiting warming to 1.5°C

Richard J. Millar, Jan S. Fuglestvedt, Pierre Friedlingstein, Joeri Rogelj, Michael J. Grubb, H. Damon Matthews, Ragnhild B. Skeie, Piers M. Forster, David J. Frame & Myles R. Allen

The Paris Agreement has opened debate on whether limiting warming to 1.5 °C is compatible with current emission pledges and warming of about 0.9 °C from the mid-nineteenth century to the present decade. We show that limiting cumulative post-2015 CO2 emissions to about 200 GtC would limit post-2015 warming to less than 0.6 °C in 66% of Earth system model members of the CMIP5 ensemble with no mitigation of other climate drivers, increasing to 240 GtC with ambitious non-CO2 mitigation. We combine a simple climate–carbon-cycle model with estimated ranges for key climate system properties from the IPCC Fifth Assessment Report. Assuming emissions peak and decline to below current levels by 2030, and continue thereafter on a much steeper decline, which would be historically unprecedented but consistent with a standard ambitious mitigation scenario (RCP2.6), results in a likely range of peak warming of 1.2–2.0 °C above the mid-nineteenth century. If CO2 emissions are continuously adjusted over time to limit 2100 warming to 1.5 °C, with ambitious non-CO2 mitigation, net future cumulative CO2 emissions are unlikely to prove less than 250 GtC and unlikely greater than 540 GtC. Hence, limiting warming to 1.5 °C is not yet a geophysical impossibility, but is likely to require delivery on strengthened pledges for 2030 followed by challengingly deep and rapid mitigation. Strengthening near-term emissions reductions would hedge against a high climate response or subsequent reduction rates proving economically, technically or politically unfeasible.

The paper’s outlook on carbon dioxide emissions is a bit more optimistic than that of the IPCC but it still requires humanity to go zero carbon well before the end of the century in order to prevent doomsday.

Judging by recent developments, the US is not only aiming to double down on business-as-usual scenarios for greenhouse gas emissions, we are actively trying to reverse previous attempts to mitigate the coming disaster. Here are some recent examples:

Data-tracking watchdog group, Environmental Data & Governance Initiative (EDGI), has reported dozens of instances where the National Institute of Environmental Health Sciences has deleted references to climate change from its site

This week saw the long-delayed release of the Department of Energy’s evaluation of grid stability. The report was commissioned by Energy Secretary Rick Perry, who suggested that the expansion of renewable energy was undermining the reliability of electricity delivery. Back in June, however, a draft of the expert evaluation leaked, and it stated that the US grid was now more reliable than it had been in recent decades. Those conclusions, however, were watered down in the final report.

But the report is also notable for avoiding the use of the term “climate change” anywhere in its 125 pages. This is despite the fact that increased heat will boost demand and stress grid hardware and that climate change is currently driving state-level energy policies. In fact, the report recommends the anti-solution of increasing the use of coal-fired power plants.

For years, climate change activists have faced a wrenching dilemma: how to persuade people to care about a grave but seemingly far-off problem and win their support for policies that might pinch them immediately in utility bills and at the pump.

But that calculus may be changing at a time when climatic chaos feels like a daily event rather than an airy abstraction, and storms powered by warming ocean waters wreak havoc on the mainland United States. Americans have spent weeks riveted by television footage of wrecked neighborhoods, displaced families, flattened Caribbean islands and submerged cities from Houston to Jacksonville.

“The conversation is shifting,” said Senator Brian Schatz, Democrat of Hawaii. “Because even if you don’t believe liberals, even if you don’t believe scientists, you can believe your own eyes.”

Doomsday timing doesn’t have to be global. We can see different markers of individual cataclysms around the world and how they trigger even bigger problems. The necessary massive movement of people from more vulnerable locations to less vulnerable ones creates its own set of issues that we are just now starting to encounter. In future blogs I will try to quantify some of these prospects within a few local communities.

Next week I will return to how and why we attribute climate change to human activities. I’ll examine how we try to determine the human contributions to each of these early markers of the 6th Mass Extinction. I will try to address this both globally and locally, followed by identifying tools that we already have that can minimize these catastrophic impacts – if we have the will to do so.

Be Sociable, Share!
Posted in administration, Anthropocene, Anthropogenic, Climate Change, IPCC, politics, Sustainability, Trump | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Doomsday Early Signs: The Science

The New York Times last week tried to highlight the dangers of climate change. On Friday, Alexander Burns opened his contribution with the following two paragraphs:

For years, climate change activists have faced a wrenching dilemma: how to persuade people to care about a grave but seemingly far-off problem and win their support for policies that might pinch them immediately in utility bills and at the pump.

But that calculus may be changing at a time when climatic chaos feels like a daily event rather than an airy abstraction, and storms powered by warming ocean waters wreak havoc on the mainland United States. Americans have spent weeks riveted by television footage of wrecked neighborhoods, displaced families, flattened Caribbean islands and submerged cities from Houston to Jacksonville.

On Thursday, Tom Friedman wrote an op-ed on the contradictory ways in which President Trump is handling two seemingly low-probability global doomsday events: North Korea’s use of nuclear weapons on the US or its allies, and climate change:

The other low-probability, high-impact threat is climate change fueled by increased human-caused carbon emissions. The truth is, if you simply trace the steady increase in costly extreme weather events — wildfires, floods, droughts and climate-related human migrations — the odds of human-driven global warming having a devastating impact on our planet are not low probability but high probability.

Friedman realized that the major difference between these two possible future events is that the latter has a much higher probability. For a business-as-usual scenario in which we continue with the same policies that we presently hold, the only contentious issue is the timing.

Estimating future events always comes with uncertainty about timing. In terms of climate change, the IPCC has addressed this via different scenarios (October 1, 2013 and October 28, 2014). Doomsday timing depends on our contributions to climate change (August 29, 2017 – dark orange region in Figure 2). A similar approach is to try to predict doomsday through its early signs. Some doomsday scenarios such as North Korea bombing the US with nuclear weapons would likely have few (if any) early warning signs; they would reflect totally irrational, suicidal thinking. Other doomsday scenarios would give us much more to work with. The largest computer file that I have on climate change is dedicated to the early signs that already exist.

A recently published paper in the Proceeding of the National Academy of Science (PNAS) deals directly with this issue. All three of its authors are distinguished scientists. One of them, Paul Ehrlich, is a member of the National Academy of Science and was one of the two original formulators of the IPAT identity that I use so often in this blog (November 26, 2012). I am including significant parts of the paper because the main differences between science and stories or opinions are details, methodology, and refutability based on observations. Readers should be able to distinguish between the conclusions of this paper and the New York Magazine article that I discussed last week:

Biological annihilation via the ongoing sixth mass extinction signaled by vertebrate population losses and declines

  1. Gerardo Ceballosa,1, Paul R. Ehrlichb,1, and Rodolfo Dirzob


The strong focus on species extinctions, a critical aspect of the contemporary pulse of biological extinction, leads to a common misimpression that Earth’s biota is not immediately threatened, just slowly entering an episode of major biodiversity loss. This view overlooks the current trends of population declines and extinctions. Using a sample of 27,600 terrestrial vertebrate species, and a more detailed analysis of 177 mammal species, we show the extremely high degree of population decay in vertebrates, even in common “species of low concern.” Dwindling population sizes and range shrinkages amount to a massive anthropogenic erosion of biodiversity and of the ecosystem services essential to civilization. This “biological annihilation” underlines the seriousness for humanity of Earth’s ongoing sixth mass extinction event.


The population extinction pulse we describe here shows, from a quantitative viewpoint, that Earth’s sixth mass extinction is more severe than perceived when looking exclusively at species extinctions. Therefore, humanity needs to address anthropogenic population extirpation and decimation immediately. That conclusion is based on analyses of the numbers and degrees of range contraction (indicative of population shrinkage and/or population extinctions according to the International Union for Conservation of Nature) using a sample of 27,600 vertebrate species, and on a more detailed analysis documenting the population extinctions between 1900 and 2015 in 177 mammal species. We find that the rate of population loss in terrestrial vertebrates is extremely high—even in “species of low concern.” In our sample, comprising nearly half of known vertebrate species, 32% (8,851/27,600) are decreasing; that is, they have decreased in population size and range. In the 177 mammals for which we have detailed data, all have lost 30% or more of their geographic ranges and more than 40% of the species have experienced severe population declines (>80% range shrinkage). Our data indicate that beyond global species extinctions Earth is experiencing a huge episode of population declines and extirpations, which will have negative cascading consequences on ecosystem functioning and services vital to sustaining civilization. We describe this as a “biological annihilation” to highlight the current magnitude of Earth’s ongoing sixth major extinction event.

The loss of biological diversity is one of the most severe human-caused global environmental problems. Hundreds of species and myriad populations are being driven to extinction every year (1⇓⇓⇓⇓⇓⇓–8). From the perspective of geological time, Earth’s richest biota ever is already well into a sixth mass extinction episode (9⇓⇓⇓⇓–14). Mass extinction episodes detected in the fossil record have been measured in terms of rates of global extinctions of species or higher taxa (e.g., ref. 9). For example, conservatively almost 200 species of vertebrates have gone extinct in the last 100 y. These represent the loss of about 2 species per year. Few realize, however, that if subjected to the estimated “background” or “normal” extinction rate prevailing in the last 2 million years, the 200 vertebrate species losses would have taken not a century, but up to 10,000 y to disappear, depending on the animal group analyzed (11). Considering the marine realm, specifically, only 15 animal species have been recorded as globally extinct (15), likely an underestimate, given the difficulty of accurately recording marine extinctions. Regarding global extinction of invertebrates, available information is limited and largely focused on threat level. For example, it is estimated that 42% of 3,623 terrestrial invertebrate species, and 25% of 1,306 species of marine invertebrates assessed on the International Union for Conservation of Nature (IUCN) Red List are classified as threatened with extinction (16). However, from the perspective of a human lifetime it is difficult to appreciate the current magnitude of species extinctions. A rate of two vertebrate species extinctions per year does not generate enough public concern, especially because many of those species were obscure and had limited ranges, such as the Catarina pupfish (Megupsilon aporus, extinct in 2014), a tiny fish from Mexico, or the Christmas Island pipistrelle (Pipistrellus murrayi, extinct in 2009), a bat that vanished from its namesake volcanic remnant.

Species extinctions are obviously very important in the long run, because such losses are irreversible and may have profound effects ranging from the depletion of Earth’s inspirational and esthetic resources to deterioration of ecosystem function and services (e.g., refs. 17⇓⇓–20). The strong focus among scientists on species extinctions, however, conveys a common impression that Earth’s biota is not dramatically threatened, or is just slowly entering an episode of major biodiversity loss that need not generate deep concern now (e.g., ref. 21, but see also refs. 9, 11, 22). Thus, there might be sufficient time to address the decay of biodiversity later, or to develop technologies for “deextinction”—the possibility of the latter being an especially dangerous misimpression (see ref. 23). Specifically, this approach has led to the neglect of two critical aspects of the present extinction episode: (i) the disappearance of populations, which essentially always precedes species extinctions, and (ii) the rapid decrease in numbers of individuals within some of the remaining populations. A detailed analysis of the loss of individuals and populations makes the problem much clearer and more worrisome, and highlights a whole set of parameters that are increasingly critical in considering the Anthropocene’s biological extinction crisis.

In the last few decades, habitat loss, overexploitation, invasive organisms, pollution, toxification, and more recently climate disruption, as well as the interactions among these factors, have led to the catastrophic declines in both the numbers and sizes of populations of both common and rare vertebrate species (24⇓⇓⇓–28). For example, several species of mammals that were relatively safe one or two decades ago are now endangered. In 2016, there were only 7,000 cheetahs in existence (29) and less than 5,000 Borneo and Sumatran orangutans (Pongo pygmaeus and P. abelli, respectively) (28). Populations of African lion (Panthera leo) dropped 43% since 1993 (30), pangolin (Manis spp.) populations have been decimated (31), and populations of giraffes dropped from around 115,000 individuals thought to be conspecific in 1985, to around 97,000 representing what is now recognized to be four species (Giraffa giraffa, G. tippelskirchi, G. reticulata, and G. camelopardalis) in 2015 (32).

An important antecedent to our work (25) used the number of genetic populations per unit area and then estimated potential loss on the basis of deforestation estimates and the species–area relationship (SAR). Given the recognized limitations of the use of SAR to estimate extinctions, our work provides an approach based on reduction of species range as a proxy of population extirpation. The most recent Living Planet Index (LPI) has estimated that wildlife abundance on the planet decreased by as much as 58% between 1970 and 2012 (4). The present study is different from LPI and other related publications in several ways, including that here we use all decreasing species of vertebrates according to IUCN, mapping and comparing absolute and relative numbers of species, and focusing on population losses. Previous estimates seem validated by the data we present here on the loss of local populations and the severe decrease in the population size of many others (see also refs. 3, 4, 6⇓–8, 26). Here we examine the magnitude of losses of populations of land vertebrate species on a global system of 10,000-km2 quadrats (Methods). Species vary from common to rare, so that our analysis, which includes all land vertebrate species (amphibians, birds, reptiles, and mammals) deemed as “decreasing” by IUCN, provides a better estimate of population losses than using exclusively IUCN data on species at risk. Obviously, common species decreasing are not ordinarily classified as species at risk. IUCN criteria provide quantitative thresholds for population size, trend, and range size, to determine decreasing species (28, 33). We also evaluate shrinking ranges and population declines for 177 species of mammals for which data are available on geographic range shrinkage from ∼1900 to 2015. We specifically focus on local extinctions by addressing the following questions: (i) What are the numbers and geographic distributions of decreasing terrestrial vertebrate species (i.e., experiencing population losses)? (ii) What are the vertebrate groups and geographic regions that have the highest numbers and proportions of decreasing species? (iii) What is the scale of local population declines in mammals—a proxy for other vertebrates? By addressing these questions, we conclude that anthropogenic population extinctions amount to a massive erosion of the greatest biological diversity in the history of Earth and that population losses and declines are especially important, because it is populations of organisms that primarily supply the ecosystem services so critical to humanity at local and regional levels.


Population extinctions today are orders of magnitude more frequent than species extinctions. Population extinctions, however, are a prelude to species extinctions, so Earth’s sixth mass extinction episode has proceeded further than most assume. The massive loss of populations is already damaging the services ecosystems provide to civilization. When considering this frightening assault on the foundations of human civilization, one must never forget that Earth’s capacity to support life, including human life, has been shaped by life itself (47). When public mention is made of the extinction crisis, it usually focuses on a few animal species (hundreds out of millions) known to have gone extinct, and projecting many more extinctions in the future. But a glance at our maps presents a much more realistic picture: they suggest that as much as 50% of the number of animal individuals that once shared Earth with us are already gone, as are billions of populations. Furthermore, our analysis is conservative, given the increasing trajectories of the drivers of extinction and their synergistic effects. Future losses easily may amount to a further rapid defaunation of the globe and comparable losses in the diversity of plants (36), including the local (and eventually global) defaunation-driven coextinction of plants (3, 20). The likelihood of this rapid defaunation lies in the proximate causes of population extinctions: habitat conversion, climate disruption, overexploitation, toxification, species invasions, disease, and (potentially) large-scale nuclear war—all tied to one another in complex patterns and usually reinforcing each other’s impacts. Much less frequently mentioned are, however, the ultimate drivers of those immediate causes of biotic destruction, namely, human overpopulation and continued population growth, and overconsumption, especially by the rich. These drivers, all of which trace to the fiction that perpetual growth can occur on a finite planet, are themselves increasing rapidly. Thus, we emphasize that the sixth mass extinction is already here and the window for effective action is very short, probably two or three decades at most (11, 48). All signs point to ever more powerful assaults on biodiversity in the next two decades, painting a dismal picture of the future of life, including human life.

The doomsday scenario in this paper is the Sixth Extinction (February 3, 2015). The paper reaches the conclusion that not only it is not a new prediction but that we are already in the middle of the extinction process. The methodology was based on detailed investigation of databases that determined we are in a period of extinction both of entire species and also of individuals within non-extinct species. Additionally, the paper addresses the situations of the geographic areas surrounding these individuals and how they serve as proxies for further extinctions. The determination that this extinction is human-caused (anthropogenic) is based on its speed and global distribution. One common argument given the extinction of whole species is that the process is not the end of all life on Earth but a homogenization – a road to lower biodiversity (although presumably humans and domesticated animals, whether livestock or pets, would continue to survive). Examples of individuals dying out are putting this argument to rest.

Next week I will deal explicitly with the timing of the projected doomsday.

Be Sociable, Share!
Posted in administration, Anthropocene, Anthropogenic, Climate Change, IPCC, Sustainability, Trump | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Doomsday: The Simple (or Simplistic) Version

I am writing this blog on Saturday, one day before hurricane Irma is scheduled to make an unwelcome visit to Florida. Other unwanted weather events are taking place all around. Human impact, especially the undesirable variety, is taking a toll. The New York Times had a piece today that summarized the combination of some of these events in terms of the feeling of an apocalypse:

CLEWISTON, Fla. — Vicious hurricanes all in a row, one having swamped Houston and another about to buzz through Florida after ripping up the Caribbean.

Wildfires bursting out all over the West after a season of scorching hot temperatures and years of dryness.

And late Thursday night, off the coast of Mexico, a monster of an earthquake.

You could be forgiven for thinking apocalyptic thoughts, like the science fiction writer John Scalzi who, surveying the charred and flooded and shaken landscape, declared that this “sure as hell feels like the End Times are getting in a few dress rehearsals right about now.”

Or the street corner preacher in Harlem overheard earlier this week ranting about Harvey, Irma and Kim Jong Un, in no particular order.

Or the tens of thousands who retweeted this image of golfers playing against a raging inferno of a wildfire in Oregon.

And just last month darkness descended on the land as the moon erased the sun. Everyone thought the eclipse was awesome, but now we’re not so sure — for all the recent ruin seems deeply, darkly not coincidental.

If you thought that, you would be wrong, of course. As any scientist will tell you, nature doesn’t work that way.

Some of our esteemed communicators tried to shift the blame to supposedly sinful behavior:

Meanwhile, some of our key public servants who were appointed to take care of the consequences of these catastrophic events apparently felt insulted when anyone mentioned climate change as a contributing factor that needs addressing:

“Here’s the issue,” Pruitt told CNN in a phone interview. “To have any kind of focus on the cause and effect of the storm; versus helping people, or actually facing the effect of the storm, is misplaced.”

“All I’m saying to you is, to use time and effort to address it at this point is very, very insensitive to this people in Florida.”

But isn’t it our responsibility to try to mitigate the risks not only to ourselves but also to our children and grandchildren?

These catastrophic events are happening right now. They are highly visible and cost numerous lives as well as billions of dollars to repair. All the science that we know points to these events continuing to grow at accelerated rates. Throughout this blog, I have framed this future as “the end of now,” where I define “now” as the lifespan of my grandchildren: toward the end of the century.

As I have repeatedly mentioned, such a possible grand doomsday scenario toward the end of the century still leaves us with enough time now to take steps to mitigate and thus prevent or minimize what could be a much larger catastrophe. The implementation of such options is a legitimate topic of discussion.

David Wallace-Wells’ piece in New York Magazine prompted that sort of dialogue. The response was visceral; some described it as fear mongering while others labeled it “climate disaster porn.”  Here I would like to come to the paper’s defense. What the paper is doing is a legitimate way of describing a possible doomsday, albeit without going into scientific details or offering possible mitigating actions. The paper describes a “simplistic doomsday” and thus many people hate it – including many of my students on the few occasions that I have presented such scenarios.

Wallace-Wells addresses heat death, the end of food, climate plagues, unbreathable air, perpetual war, permanent economic collapse, and poisoned oceans. I will paste some key paragraphs from the first and last sections of his paper as they are not self-explanatory. For the rest I recommend that readers reference the original publication.

I. ‘Doomsday’
It is, I promise, worse than you think. If your anxiety about global warming is dominated by fears of sea-level rise, you are barely scratching the surface of what terrors are possible, even within the lifetime of a teenager today. And yet the swelling seas — and the cities they will drown — have so dominated the picture of global warming, and so overwhelmed our capacity for climate panic, that they have occluded our perception of other threats, many much closer at hand. Rising oceans are bad, in fact very bad; but fleeing the coastline will not be enough. Indeed, absent a significant adjustment to how billions of humans conduct their lives, parts of the Earth will likely become close to uninhabitable, and other parts horrifically inhospitable, as soon as the end of this century.


IX. The Great Filter
Surely this blindness will not last — the world we are about to inhabit will not permit it. In a six-degree-warmer world, the Earth’s ecosystem will boil with so many natural disasters that we will just start calling them “weather”: a constant swarm of out-of-control typhoons and tornadoes and floods and droughts, the planet assaulted regularly with climate events that not so long ago destroyed whole civilizations. The strongest hurricanes will come more often, and we’ll have to invent new categories with which to describe them; tornadoes will grow longer and wider and strike much more frequently, and hail rocks will quadruple in size. Humans used to watch the weather to prophesy the future; going forward, we will see in its wrath the vengeance of the past. Early naturalists talked often about “deep time” — the perception they had, contemplating the grandeur of this valley or that rock basin, of the profound slowness of nature. What lies in store for us is more like what the Victorian anthropologists identified as “dreamtime,” or “everywhen”: the semi-mythical experience, described by Aboriginal Australians, of encountering, in the present moment, an out-of-time past, when ancestors, heroes, and demigods crowded an epic stage. You can find it already watching footage of an iceberg collapsing into the sea — a feeling of history happening all at once

The paper obviously incited many objections. The author has added a site at New York Magazine, which is considerably longer than the original article, to try to answer some of these critical comments. It is not a scientific paper and was not published in a scientific journal. It doesn’t conform to some of the most basic requirements of scientific publications, the most important of which is refutability. It doesn’t even qualify as “fake news” – a popular concept these days – because it doesn’t pretend to offer news. Nor is it an opinion. It is a call for action that was designed to shock people to into considering the scenario plausible enough to provoke arguments that might lead to political pressure and movement. This was a good enough reason for a reputable publication such as New York Magazine to offer the author a platform. The described methodology – chatting with scientists – is common among popular science “documentary” books that attempt to describe the future. It cannot be refuted because the scientists are not identified by name. People can only argue with the author. The timing of his descriptions and the scenarios on which his predictions are based are well defined. The timing is toward the end of the century under “business as usual scenarios” that I have discussed many times on this blog.

“The Great Filter” segment summarizes the doomsday scenarios. The effect it describes has officially been named the “Shifting Baseline Syndrome.”  Our future generations might not be even aware that they are in trouble. They might think that this is simply how nature works.

Next week I am going to address the doomsday issue from a much more solid scientific foundation to show more concretely that not only is this coming but we are in the middle of it. I want to emphasize that in spite of the urgency we still have time to act.

Be Sociable, Share!
Posted in Climate Change | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Climate-Related Doomsday – Early Signs: Harvey

Houston Market Street before and during HarveyFigure 1 Before and during Harvey

Mumbai monsoon floodFigure 2 Mumbai monsoon, August 2017

Most expensive hurricanes in the USFigure 3Cost of recent hurricanes in the US

The three figures above demonstrate early signs of a climate-related doomsday. Figure 1 shows Market Street in Houston both before and during Harvey last week. The side-by-side photographs look like two different worlds. People have referred to the hurricane-powered rain that flooded Houston – in many places reaching depths of close to two feet – as a biblical deluge. Indeed, throughout history, we often have turned to religion to account for natural events that we did not understand. This tendency is fine unless it freezes our resolve to mitigate our own impacts on the physical environment.

Wikipedia describes floods such as the one found in the Bible:

A flood myth or deluge myth is a narrative in which a great flood, usually sent by a deity or deities, destroys civilization, often in an act of divine retribution. Parallels are often drawn between the flood waters of these myths and the primeval waters found in certain creation myths, as the flood waters are described as a measure for the cleansing of humanity, in preparation for rebirth. Most flood myths also contain a culture hero, who “represents the human craving for life”.[1]

The flood myth motif is found among many cultures as seen in the Mesopotamian flood stories, Deucalion in Greek mythology, the Genesis flood narrative, Manu in Hinduism, Bergelmir in Norse Mythology, in the lore of the K’iche’ and Maya peoples in Mesoamerica, the Lac Courte Oreilles Ojibwa tribe of Native Americans in North America, the Muisca, and Cañari Confederation, in South America, and the Aboriginal tribes in southern Australia.

As we can see, floods play a major role in countless religions; in many, they constitute divine retribution for human misbehavior – this fits with the principal elements of climate change. Almost all the religious texts allow for remediation of that wrath through a change in human behavior. Nearly half of the United States, including our government, appears reticent to make such changes.

Biblical deluges and their equivalents are almost always global. So are ours. Figure 2 shows a photograph from a Guardian piece on Mumbai, the largest city in India:

Heavy monsoon rains have brought Mumbai to a halt for a second day as the worst floods to strike south Asia in years continued to exact a deadly toll. More than 1,200 people have died across India, Bangladesh and Nepal as a result of flooding, with 40 million affected by the devastation. At least six people, including two toddlers, were among the victims in and around India’s financial capital. The devastating floods have also destroyed or damaged 18,000 schools, meaning that about 1.8 million children cannot go to classes, Save the Children warned on Thursday.

This is a worldwide problem.

Figure 3 shows the price tag associated with estimates of the damage that recent hurricanes have inflicted on the US. The cost it lists for Harvey is 40 billion dollars. However, while the source of the information is a reputable organization, it reflects an estimate presented at the beginning of the storm. There is no way that anybody could have accurately approximated the final economic impact. Indeed, a few days after that initial figure, some publications came out with an estimate of $160 billion and the September 2nd issue of The Economist – which features the flood on its front page – presented the cost as $100 billion. Real money. Imagine that occasionally, as is expected, we are going to be hit simultaneously by more than one storm of this intensity.

President Trump and others referred to Harvey as a 500-year-storm. Still others referred to it as a 1000-year-storm. This terminology is associated with the perceived probability of such an intense storm in a given year. So a 500-year-storm refers to the probability of 100/500 = 0.2% while a 1000-year-storm refers to a 0.1% probability in a given year.

These probabilities are inferred based on the history of the events – not on evaluation of future probabilities. The list in Figure 3 and the detection of a new hurricane, Irma, which is now crossing the Atlantic, are powerful indications that these historically-based probabilities are no longer valid and that the overarching occurrence we now refer to as climate change is bringing with it different, much higher, probabilities.

Shortly before Harvey hit, President Trump cancelled some of the major efforts that the Obama administration made to try to mitigate the impact of these changes. Business Insider covered the story:

Ten days before Hurricane Harvey descended upon Texas on Friday, wreaking havoc and causing widespread flooding, President Donald Trump signed an executive order revoking a set of regulations that would have made federally funded infrastructure less vulnerable to flooding.

Attribution of the changing climate to human activities is an important issue. Climate and weather have changed throughout Earth’s history (around 4.8 billion years). Direct human impact started only recently. The common starting reference point is the beginning of the Industrial Revolution in the middle of the 18th century, because it drew its power from fossil fuels. In other words, hurricanes were around but the only clear human contribution to a storm like Harvey before that time was its name. However, it now borders on certainty that human-triggered (anthropogenic) climate change is a major cause in the variability and intensification of the weather events. “Harvey would have been here with or without human contributions,” is a meaningless statement. Yes, Harvey would have probably occurred but as a much less intense storm with a much milder impact. I will return to our attempts to quantify human attributions in future blogs. Here is a summary of the human attribution analysis of Harvey by a noted climatologist:

There are essentially two global warming mechanisms at play here, according to Mann. First, sea levels in the Houston region have risen by more than half a foot over the past few decades due to global warming. That obviously makes it much more likely for an area to flood.

The second — and more complicated — factor is the amount of moisture in the air. As Mann explained, the rising temperatures in the region add up to 1°C to 1.5°C higher temperatures than average a few decades ago. Based on the Clausius-Clapeyron equation, Mann calculated that amounts to roughly 3 to 5 percent more moisture in the atmosphere — which means more rain.

“That large amount of moisture meant the potential for much greater rainfalls and greater flooding,” he noted.

He also goes into one last, but less certain, issue: It’s possible that global warming contributed to Harvey “stalling” near the Texas coast, due to “‘stationary’ summer weather patterns” that Mann argued global warming may contribute to. (He cited a recent paper in Nature about it.) This stalling is one of the reasons Harvey has become so dangerous: It’s expected to stay in the area for days, blasting the region with literally feet of rainfall.

“In conclusion, while we cannot say climate change ‘caused’ hurricane Harvey (that is an ill-posed question), we can say that it exacerbate several characteristics of the storm in a way that greatly increased the risk of damage and loss of life,” Mann wrote. “Climate change worsened the impact of Hurricane Harvey.”

Other climatologists agree with Mann. Kevin Trenberth, a senior scientist at the US National Center for Atmospheric Research, told the Atlantic, “The human contribution can be up to 30 percent or so up to the total rainfall coming out of the storm. … It may have been a strong storm, and it may have caused a lot of problems anyway — but [human-caused climate change] amplifies the damage considerably.”

That helps explain how Harvey suddenly led to what experts have called a 500-year flood.

Other climatologists agree with this 30% attribution.

What about insurance against future events?

An editorial in the NYT summarizes the history of federal flood insurance and addresses necessary steps post-Harvey:

It was clear long before Hurricane Harvey slammed into Texas that the National Flood Insurance Program, the government’s most important means of recovering from such disasters, needed to be overhauled. It fails to account for the full extent of flood risk, encourages development in areas known to be flood-prone and is not realistically funded.

Congress created the program in 1968 after most private insurers stopped selling flood policies or began charging very high premiums because the business had become too risky.

In recent years, the staggering costs of storms like Katrina and Sandy have left the program, which has about five million policies, with a nearly $25 billion debt to the federal government.

Congress is to blame for this. It requires the Federal Emergency Management Agency, which administers the program, to subsidize premiums, but has not provided it with money to do so. Reform efforts in recent years have fallen short, but lawmakers have another chance to fix the program, which will lapse if not reauthorized by Sept. 30.

It is being reported that 85% of Houston homeowners don’t have flood insurance.

Stay tuned.

Be Sociable, Share!
Posted in administration, Anthropocene, Anthropogenic, Climate Change, Sustainability, Trump | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Doomsday Predictions – Disaster Porn?

Figure 1Doomsday Clock

Three weeks ago (before Charlottesville) I summarized the climate-change-related events that took place during my July vacation and promised to expand upon those issues. Given my necessary digression, I am reposting some of those elements here for easy reference. I am also including the relevant section of a critique of Al Gore’s “An Inconvenient Sequel” movie, in which the critic equates his doomsday predictions to disaster porn.

Here’s a segment of my outline:

Distant Future: the end of the present century – i.e. my definition of “now” (the projected lifespan of my grandchildren):

However, to incorporate some of the sense of conflict that has been playing out between optimists and pessimists, here’s part of a joint critique of Al Gore’s new film and the David Wallace-Wells piece:

“An Inconvenient Sequel,” which opened in select cities on Friday and will open nationwide next week, arrives on the heels of a widely shared New York magazine article by David Wallace-Wells. The piece describes, in dramatic terms, the worst-case repercussions of climate change. “Absent a significant adjustment to how billions of humans conduct their lives, parts of the Earth will likely become uninhabitable, and other parts horrifically inhospitable, as soon as the end of this century,” Wallace-Wells writes. Some climatologists objected to the article’s characterizations of their work, but the real controversy centered on its approach. Michael Mann, the director of the Earth System Science Center, at Pennsylvania State University, declared that he was “not a fan of this sort of doomist framing,” and the sociologist Daniel Aldana Cohen described it as “climate disaster porn.”

I teach a graduate course on Physics and Society in which climate change and the transition to the Anthropocene are key components. One of the students last semester was clearly upset and left the course in the middle of the semester; she hated the idea of what she saw as doomsday scenarios masquerading as science. On the other hand, if we want to impact the future in such a way as to negate these predictions, we need to work on understanding how best to approach mitigation.

I didn’t like the Al Gore movie for a different reason. In my opinion, it did not put enough emphasis on the predicted impacts of business as usual scenarios – how a continuation of the ways in which we achieve our current standards of living (e.g. our present energy mix, population growth, water use, etc.) is causing/will cause destruction of the physical environment. “An Inconvenient Sequel” focused almost exclusively on climate events and Al Gore’s activities in the time period following his Oscar-winning first film. There was no discussion at all about how we figure out human contributions to these climate events. This omission detracts a considerable amount of credibility from the advocacy in the movie. It is difficult to make movies about the future or about how we attribute blame, but it is not impossible. His first movie did a much better job at including these important elements.

The two figures in this blog summarize some of the challenges. Figure 1 shows a doomsday clock:

The Doomsday Clock is a symbol which represents the likelihood of a man-made global catastrophe. Maintained since 1947 by the members of the Bulletin of the Atomic Scientists‘ Science and Security Board,[1] the Clock represents an analogy for the threat of global nuclear war. Since 2007, it has also reflected climate change[2] and new developments in the life sciences and technology that could inflict irrevocable harm to humanity.[3]

The Clock represents the hypothetical global catastrophe as “midnight” and The Bulletin’s opinion on how close the world is to a global catastrophe as a number of “minutes” to midnight. Its original setting in 1947 was seven minutes to midnight. It has been set backward and forward 22 times since then, the smallest-ever number of minutes to midnight being two (in 1953) and the largest seventeen (in 1991). As of January 2017[update], the Clock is set at two and a half minutes to midnight, due to a “rise of ‘strident nationalism‘ worldwide, United States President Donald Trump‘s comments over North Korea, Russia, and nuclear weapons.”[4][5] This setting is the Clock’s second-closest approach to midnight since its introduction.

Throughout its conceptual existence, the clock – although it allows for the possibility of other scenarios – has been heavily weighted towards world annihilation by way of nuclear holocaust (see February 2, 2016 blog). Here our focus will be climate change.

Figure 2IPCC projections of future climate change impacts based on two different scenarios

Figure 2 shows the IPCC’s projected impacts of climate change as estimated in its Fourth Assessment Report ten years ago (September 24, 2012 and October 14, 2014). One can see in the figure a gradual transition from yellow to orange. As we enter into the dark orange region, we see:

Few ecosystems can adapt; 50% of nature reserves cannot fulfill their objectives. Predicted extinction of 15 – 40% endemic species in global biodiversity hotspots.

This continues, as we progress further into the dark orange zone, with:

>4oC: Major extinctions around globe (as exemplified for USA and Australia). Likely extinctions of 200 – 300 species of New Zealand alpine plants.

We can arbitrarily define the transition from yellow to orange as the transition into end-of-the-world conditions and try to figure out why a respected sociologist and others labeled it disaster porn. Not being an expert in that subject or the use of the phrase, I assume that it stems from porn being considered “cheap” and not “real.” It is obvious, however, that porn is very real to both its participants and producers and it comes with a variety of prices. My job here is to make a case that doomsday scenarios cover a similar range of spectra – from viscerally frightening situations with limited quantitative details to rigorous scientific quantitative evaluations. All of these descriptions seek to encourage the masses to actively seek out ways to immediately implement policies and activities that could keep any sort of doomsday at bay for as long as possible.

Stay tuned and let me know where I succeed and where I fail.

Be Sociable, Share!
Posted in Anthropocene, Anthropogenic, Climate Change, IPCC, Sustainability | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Never Again?? Charlottesville, Nazis, the Holocaust, and Climate Change

My original plan was to dedicate this blog, and several following ones, to pornography. Not the kind that you have in mind – this is not that kind of a blog – but the kind that the sociologist Daniel Aldana Cohen meant when he referred to David Wallace-Wells’ piece in New York Magazine and critiqued other recent efforts to explore the consequences of climate change. I also promised (August 8, 2017) to move away from my coverage of the Trump administration and to restore my focus to climate change.

The recent events in Charlottesville, Virginia, were frightening enough to change my intentions.

Figure 1 – Members of the alt-right mimicking the Nazi salute

A demonstrator holds signs during a rally in response to the Charlottesville, Virginia car attack on counter-protesters after the “Unite the Right” rally organized by white nationalists, in Oakland, California, U.S., August 12, 2017. Picture taken August 12, 2017. REUTERS/Stephen Lam

Figure 2 – Sign carried by a counter-demonstrator

Figure 1, without the caption, could have been mistaken for a picture taken in Germany in the mid-1930s while Figure 2 shows a much more modern response from a young counter-demonstrator.

My background is immediately relevant to this situation and forced me to try to address what happened. I gave a summary of my earlier life in my first blog here, more than 5 years ago (April 22, 2012):

I was born in Warsaw, Poland in May, 1939. The first three years of my life were spent in the Warsaw Ghetto, as the Nazis developed their plans for systematic Jewish genocide. Before the destruction of the Ghetto in 1943, I was hidden for a time on the Aryan side by a family friend, but a Nazi “deal” to provide foreign papers to escape Poland resulted in my mother bringing me back to the Ghetto. Then a Nazi double-cross sent the remnants of my family not to safety in Palestine, but to the Bergen-Belsen concentration camp as possible pawns in exchange for German prisoners of war. As the war was nearing an end, in April 1945, we were put on a train headed to Theresienstadt, a concentration camp further from the front lines. American tank commanders with the 743rd tank battalion of the American 30th Division intercepted our train near Magdeburg in Germany, liberating nearly 2500 prisoners. Within the year, my mother and I began building new lives in Palestine.

The rest of that blog and the blog that followed tried to explain my perspective on the connection between the Holocaust and the impending disastrous future that unmitigated climate change could bring to us all. The prospective consequences of continuing careless business as usual practices will lead to what I called “self-inflicted genocide,” which is an alternative description of the doomsday scenario that Daniel Aldana Cohen labeled as porn. More on that in the next few blogs.

The show of Nazi symbolism in the violent demonstrations in Charlottesville that resulted in the murder of Heather Heyer and the serious wounding of many others, together with President Trump’s sick responses, caused me (and many others) to resurrect the slogan that titles this blog – with a large question mark.

To be a Holocaust survivor I have to be old. As my short bio describes, I am 78 years old. I was born three months before the start of WWII. Now, and on many other occasions, I am fully aware that I am part of the last generation that survived the Holocaust and the atrocities that the Nazis wrought upon the world. American soldiers saved me along with the rest of the world at that time and it is hard to believe that the same hate that inflamed Germany before WWII is now starting to do the same to American society.

I have convinced myself that – given I am the last Holocaust survivor at the school where I work – it is my duty to be part of the effort to stop the penetration of hate into the highest echelons of our country. I am too old to take part in the demonstrations to counter hate so the only activities that I can pursue are teaching, writing, speaking, and voting.

HBO’s short documentary filmed during the demonstrations, “Charlottesville: Race and Terror,” convinced me to join many others in contradicting President Trump’s attempts to find symmetry between the alt-right participants and the counter-demonstrators standing against hate. The alt-right participants were well organized, their slogans well coordinated, and in many cases even their “uniforms” matched. Their age distribution seems to be very narrow, tilted toward the younger generations, and their ranks were mostly populated by males. Some of their slogans such as “Blood and soil,” were directly plagiarized from Nazis in the 1930s, some, such as “Jews will not replace us,” were a bit more specific to the period. Others were modifications in response to the recent Black Lives Matter movement: demonstrators chanted, “White lives matter.” The resemblance to 1930s Germany was not to the Holocaust itself, but rather the SA (Sturmabteilung – Storm Detachment): the original paramilitary units of the Nazi party that ultimately perpetrated the atrocities of WWII.

There is also an abundance of parallel conspiracy theories between the two eras. Alex Jones, a prominent voice of the alt-right, is propagating the perception that Jewish actors mascaraded as members of the KKK. The HBO video includes a segment with David Duke, ex-grand wizard of the KKK, among the demonstrators. I guess that he must be part of the conspiracy.

The demonstrations did not only parallel 1930s Nazi Germany; they also reflected early 20th Century Ku Klux Klan history and their murderous actions in the US. The KKK in the South targeted Blacks while the Nazis primarily targeted Jews but neither movement spared other non-White or non-Aryan minorities.

The most frightening aspect of these events to a guy with my background is the apparent nod that the alt-right demonstrators are getting from the president of the United States. This makes the correlation with Nazi Germany almost complete. President Trump made the killing of Heather Heyer the only real crime in the event. Aside from this crime, he equated a false symmetry between the alt-right demonstrators and the anti-white-supremacy demonstrators. Fortunately for us now, as opposed to at the rise of the Nazis, and the height of the KKK, we have a powerful anti-Nazi and anti-KKK movement that is eager and ready to confront such demonstrations while the Germans and older American generations didn’t.

Some of the key players in the Trump administration are Jewish. It was reported that they were shaken and upset by the events but they didn’t resign. However, many voices on the right and left, in the business community and in the army raised their voices in protest. One such instance, directly related to my own background and my liberation by American soldiers will serve as an encouraging example and strengthen our hope that in spite of President Trump, America will not deteriorate into a Holocaust-equivalent reality.

Among the estimated thousands of alt-right demonstrators, many of whom carried firearms, social media zoomed in on one guy who was wearing a baseball hat with the insignia of the 82nd Airborne Division on it. The Washington Post covered the backlash: “He put on an 82nd Airborne cap and gave a KKK salute in Charlottesville. Vets had words”:

And the man in the hat — who hasn’t been publicly identified — drew rebuke after rebuke from the official twitter handle of the unit’s association. “Respectfully, anyone who thinks this man represents our culture and values has never worn the maroon beret … and never will,” one tweet for the 82nd’s Twitter account said.

Seventy years ago, members of the 82nd Airborne had fought against the Nazis. On a hot Saturday in 2017, someone wearing their hat was fraternizing with neo-Nazis.

The 82nd Airborne saw heavy fighting during World War II, according to the U.S. Holocaust Memorial Museum. Paratroopers advanced into Germany and liberated the Wöbbelin camp, a subcamp of the Neuengamme concentration camp. At its height, Neuengamme held 5,000 prisoners, many of whom were diseased and starving. The unit saw nearly 7,000 battle casualties, according to the museum.

The man looks much too young to have been alive in WWII or at the height of the KKK atrocities. From the quoted feedbacks in the paper we have no idea how he got the hat.

I have a hat like this with the insignia of the 30th Division on it. I have it because I was granted an honorary membership in the Division for being a concentration camp survivor saved by its soldiers. The background of that Division is similar to the 82nd as described above. After discovering the identity of the soldiers that saved me, I have participated for the last 10 years in annual meetings of survivors and liberators around the country. Unsurprisingly, all of the liberators were soldiers in their late 80s and 90s. We became drinking buddies and shared stories. They viewed us, the survivors, as one of the main causes for which many of their friends gave their lives fighting the Nazis. They had nothing to do with the KKK-saluting guy that was photographed in Charlottesville.

Be Sociable, Share!
Posted in Holocaust, politics | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

Conflict and Confusion

The Trump administration’s approach to climate-related, policy becomes clear from the following:

The administration gave “official” indication to the UN that it will abandon the Paris 2015 international agreement:

WASHINGTON — The White House formally notified the United Nations on Friday that it intends to abandon the Paris agreement on climate change but remains open to “re-engaging” on the accord.

The United States will participate in United Nations climate negotiations later this year despite its planned withdrawal, according to the administration’s statement of intent.

The letter has no legal weight and does not set in motion the United States’ departure from the pact of nearly 200 nations to curb planet-warming greenhouse gas emissions. Rather, it is a political document that affirms President Trump’s declaration in June that the Paris agreement is a bad deal for America.

The US Justice Department has amplified its effort by to catch and prosecute leakers:

Attorney General Jeff Sessions said Friday that the Justice Department has more than tripled the number of leak investigations compared with the number that were ongoing at the end of the last administration, offering the first public confirmation of the breadth of the department’s efforts to crack down on unauthorized disclosures of sensitive information.

The announcement seemed designed both to reassure the president, who has criticized the attorney general as being “weak” on leak investigations, and to scare government officials away from talking to reporters about sensitive matters.

Sessions said he was devoting more resources to stamping out unauthorized disclosures, directing Deputy Attorney General Rod J. Rosenstein and FBI Director Christopher A. Wray to actively monitor every investigation, instructing the department’s national security division and U.S. attorneys to prioritize such cases, and creating a new counterintelligence unit in the FBI to manage the work.

The administration is attempting to eliminate “Climate Change” from the vocabulary of the US government:

A series of emails obtained by the Guardian between staff at the Natural Resources Conservation Service (NRCS), a USDA unit that oversees farmers’ land conservation, show that the incoming Trump administration has had a stark impact on the language used by some federal employees around climate change.

A missive from Bianca Moebius-Clune, director of soil health, lists terms that should be avoided by staff and those that should replace them. “Climate change” is in the “avoid” category, to be replaced by “weather extremes”. Instead of “climate change adaption”, staff are asked to use “resilience to weather extremes”.

The primary cause of human-driven climate change is also targeted, with the term “reduce greenhouse gases” blacklisted in favor of “build soil organic matter, increase nutrient use efficiency”. Meanwhile, “sequester carbon” is ruled out and replaced by “build soil organic matter”.

A report by The New York Times that seemed to have stemmed from information leaked by government scientists appeared to demonstrate the impact of all these policy changes:

WASHINGTON — The average temperature in the United States has risen rapidly and drastically since 1980, and recent decades have been the warmest of the past 1,500 years, according to a sweeping federal climate change report awaiting approval by the Trump administration.

The draft report by scientists from 13 federal agencies, which has not yet been made public, concludes that Americans are feeling the effects of climate change right now. It directly contradicts claims by President Trump and members of his cabinet who say that the human contribution to climate change is uncertain, and that the ability to predict the effects is limited.

“Evidence for a changing climate abounds, from the top of the atmosphere to the depths of the oceans,” a draft of the report states. A copy of it was obtained by The New York Times.

The authors note that thousands of studies, conducted by tens of thousands of scientists, have documented climate changes on land and in the air. “Many lines of evidence demonstrate that human activities, especially emissions of greenhouse (heat-trapping) gases, are primarily responsible for recent observed climate change,” they wrote.

The report was completed this year and is a special science section of the National Climate Assessment, which is congressionally mandated every four years. The National Academy of Sciences has signed off on the draft report, and the authors are awaiting permission from the Trump administration to release it.

Except that in reality, there was no such suspense surrounding the publication of the report; it had already been released. The New York Times had just spectacularly failed to do its homework. I quickly found this out when I searched for more information on the report that hadn’t been aware of.

In fact, the report has been available and open to public comment as of the end of last year and can be downloaded in its final draft here.

Almost everybody else caught on immediately and The New York Times apologized. The Washington Post commented on the mistake:

The New York Times on Wednesday appended a correction to a story about a climate change study:

Correction: August 9, 2017
An article on Tuesday about a sweeping federal climate change report referred incorrectly to the availability of the report. While it was not widely publicized, the report was uploaded by the nonprofit Internet Archive in January; it was not first made public by The New York Times.

That correction, which sits at the foot of the story, dutifully straightens out the record. Yet given the magnitude of the screw-up, it should sit atop the story, surrounded by red flashing lights and perhaps an audio track to instruct readers: Warning: This story once peddled a faulty and damaging premise.

The report is long (close to 700 pages) but I’m including the Table of Contents and some of the background of its publication for your reference.

The report is certainly up to date regarding the extent of climate change, future forecasts, and evidence of the key role that humans are playing in the process. It seems counterintuitive that this is an official document of the US Government issued under the same administration that claimed climate change was a Chinese Hoax and that just removed our country from the only international agreement to try to mitigate the human impact on the problem. As I said, the report was opened to the public before the new administration took office. This week the White House Office of Science and Technology must decide whether to approve the final version. The White House has plenty of time to insert its own perspective.

Be Sociable, Share!
Posted in Anthropogenic, Climate Change, IPCC, UN | Tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment