Phaeton’s Reins - fisked.
Kerry Emanuel is a professor of meteorology at MIT and the author of Divine Wind: The History and Science of Hurricanes. In 2006 Time magazine recognized him as one of the world’s 100 most influential people.
He published the following article in the January/February 2007 issue of Boston Review.
It is a fascinating, and very interesting article, also full of information in layman's terms.
I copied it here in it's entirety, adding my comments.
Phaeton’s Reins
The human hand in climate change
Kerry Emanuel
Two strands of environmental philosophy run through the course of human history. The first holds that the natural state of the universe is one of infinite stability, with an unchanging earth anchoring the predictable revolutions of the sun, moon, and stars. Every scientific revolution that challenged this notion, from Copernicus’ heliocentricity to Hubble’s expanding universe, from Wegener’s continental drift to Heisenberg’s uncertainty and Lorenz’s macroscopic chaos, met with fierce resistance from religious, political, and even scientific hegemonies.
Also a lot, a greater lot, of false (un)scientific theories "met with fierce resistance ….." Meeting with fierce resistance doesn't prove the truth of your theory.
The hint that global warming alarmism might be a true "scientific revolution" that is "met with fierce resistance from religious, political, and even scientific hegemonies." is unsubstantiated.
The second strand also sees the natural state of the universe as a stable one but holds that it has become destabilized through human actions. The great floods are usually portrayed in religious traditions as attempts by a god or gods to cleanse the earth of human corruption. Deviations from cosmic predictability, such as meteors and comets, were more often viewed as omens than as natural phenomena. In Greek mythology, the scorching heat of
So humans have a tendency to create myths where the end of the world is brought about by some human activity…. Hmm… sounds familiar…
These two fundamental ideas have permeated many cultures through much of history. They strongly influence views of climate change to the present day.
The myth of natural stability
In 1837, Louis Agassiz provoked public outcry and scholarly ridicule when he proposed that many puzzles of the geologic record, such as peculiar scratch marks on rocks, and boulders far removed from their bedrock sources, could be explained by the advance and retreat of huge sheets of ice. This event marked the beginning of a remarkable endeavor, today known as paleoclimatology, which uses physical and chemical evidence from the geological record to deduce changes in the earth’s climate over time. This undertaking has produced among the most profound yet least celebrated scientific advances of our era. We now have exquisitely detailed knowledge of how climate has varied over the last few million years and, with progressively less detail and more uncertainty, how it has changed going back in time to the age of the oldest rocks on our 4.5-billion-year-old planet.
For those who take comfort in stability, there is little consolation in this record. Within the past three million years or so, our climate has swung between mild states, similar to today’s and lasting from ten to 20 thousand years, and periods of 100,000 years or so in which giant ice sheets, in some places several miles thick, covered northern continents. Even more unsettling than the existence of these cycles is the suddenness with which the climate can apparently change, especially as it recovers from glacial eras.
The climate, then, has a proven record of great changes, totally unrelated to human activity, changes whose causes we don't know…. But the earth, and we, living beings, managed somehow to survive all those changes…
Yet we are deeply alarmed about some small change that seems to be taking place right now, as if it were some unprecedented catastrophe.
Over longer intervals of time, the climate has changed even more radically. During the early part of the Eocene era, around 50 million years ago, the earth was free of ice, and giant trees grew on islands near the North Pole, where the annual mean temperature was about
Yet, despite being "exceptionally hot" no catastrophic feedback cycle took hold to destroy life completely! But that's precisely what we fear now. Why ? Doesn't the past teach us not to fear that ?
What explains these changes? For climate scientists, the ice cores in Greenland and
Relying on such analyses of ice cores and sediment cores from the deep ocean, climate scientists have learned something remarkable: the ice-age cycles of the past three million years are probably caused by periodic oscillations of the earth’s orbit that affect primarily the orientation of the earth’s axis. These oscillations do not much affect the amount of sunlight that reaches the earth, but they do change the distribution of sunlight with latitude. This distribution matters because land and water absorb and reflect sunlight differently, and the distributions of land and water—continents and oceans—are quite different in the northern and southern hemispheres. Ice ages occur when, as a result of orbital variations, the arctic regions intercept relatively little summer sunlight so that ice and snow do not melt as much.
The timing of the ice ages, then, is the combined result of the earth’s orbit and its basic geology. But this combination does not explain either the slow pace of the earth’s descent into the cold phases of the cycle or the abrupt recovery to interglacial warmth evident in the ice-core records. More disturbing is the evidence that these large climate swings—from glacial to interglacial and back—are caused by relatively small changes in the distribution of sunlight with latitude. Thus, on the time scale of ice ages, climate seems exquisitely sensitive to small perturbations in the distribution of sunlight.
And yet for all this sensitivity, the earth never suffered either of the climate catastrophes of fire or ice.
This needs to be stressed: "And yet for all this sensitivity, the earth never suffered either of the climate catastrophes of fire or ice."
In the fire scenario, the most effective greenhouse gas—water vapor—accumulates in the atmosphere as the earth warms. The warmer the atmosphere, the more water vapor can accumulate; as more water vapor accumulates, more heat gets trapped, and the warming spirals upward. This uncontrolled feedback is called the runaway greenhouse effect, and it continues until the oceans have all evaporated, by which time the planet is unbearably hot. One has only to look as far as Venus to see the end result. Any oceans that may have existed on that planet evaporated eons ago, yielding a super greenhouse inferno and an average surface temperature of around
But, despite climate being "exceptionally hot" in the past (+30 degrees F) this uncontrolled feedback hasn't materialized.
As to Venus – isn't it somewhat nearer the sun than earth? Can that explain the 900 degrees "inferno"? If so – invoking, or mentioning Venus - isn't this just an instance of fear-mongering by false associations ? Isn't it just wrong to mention Venus in this context?
Death by ice can result from another runaway feedback. As snow and ice accumulate progressively equatorward, they reflect an increasing amount of sunlight back to space, further cooling the planet until it freezes into a “snowball earth.” It used to be supposed that once the planet reached such a frozen state, with almost all sunlight reflected back to space, it could never recover; more recently it has been theorized that without liquid oceans to absorb the carbon dioxide continuously emitted by volcanoes, that gas would accumulate in the atmosphere until its greenhouse effect was finally strong enough to start melting the ice.
"…the earth was almost entirely covered with ice at various times around 500 million years ago". Yet this cooling runaway feedback hasn't happened either.
It would not take much change in the amount of sunlight reaching the earth to cause one of these catastrophes. And solar physics informs us that the sun was about 25 percent dimmer early in the earth’s history, which should have led to an ice-covered planet, a circumstance not supported by geological evidence.
So what saved the earth from fire and ice?
Life itself may be part of the answer to the riddle of the faint young sun. Our atmosphere is thought to have originated in gases emitted from volcanoes, but the composition of volcanic gases bears little resemblance to air as we know it today. It is thought that the early atmosphere consisted mostly of water vapor, carbon dioxide, sulfur dioxide, chlorine, and nitrogen. There is little evidence that there was much oxygen—until the advent of life. The first life forms helped produce oxygen through photosynthesis and transformed the atmosphere into something like today’s, consisting mostly of nitrogen and oxygen with trace amounts of water vapor, carbon dioxide, methane, and other gases. Carbon-dioxide content probably decreased slowly with time owing to chemical weathering, possibly aided by biological processes. As the composition changed, the net greenhouse effect weakened, compensating for the slow but inexorable brightening of the sun.
Wait a minute… could the current warming be caused by the "slow but inexorable brightening of the sun" ? At least part of it?
Thus early life dramatically changed the planet. We humans are only the most recent species to do so.
The compensation between increasing solar power and decreasing greenhouse effect may not have been an accident. In the 1960s, James Lovelock proposed that life actually exerts a stabilizing influence on climate by producing feedbacks favorable to itself. He called his idea the Gaia hypothesis, named after the Greek earth goddess. But even according to this view, life is only preserved in the broadest sense: individual species, such as those that transformed the early atmosphere, altered the environment at their peril.
So, maybe the theory that earth produces stabilizing feedbacks (processes that counter big changes) is more plausible that the one that predicts runaway feedbacks.
Greenhouse physics
As this sketch of the planet’s early climatic history shows, the greenhouse effect plays a critical role in the earth’s climate, and no sensible discussion of climate could proceed without grasping its nature. (A cautionary note: the greenhouse metaphor itself is flawed. Whereas actual greenhouses work by preventing convection currents from carrying away heat absorbed from sunlight, the atmosphere prevents heat from radiating away from the surface.)
But of course. Without the greenhouse effect earth would be too cold to support life.
The greenhouse effect has to do with radiation, which in this context refers to energy carried by electromagnetic waves, which include such phenomena as visible light, radio waves, and infrared radiation. All matter with a temperature above absolute zero emits radiation. The hotter the substance, the more radiation it emits and the shorter the average wavelength of the radiation emitted. A fairly narrow range of wavelengths constitute visible light. The average surface temperature of the sun is about 10,000°F, and the sun emits much of its radiation as visible light, with an average wavelength of about half a micron. (A micron is one millionth of a meter; there are 25,400 microns in an inch.) The earth’s atmosphere emits as though its average temperature were around
Most solids and liquids absorb much of the radiation they intercept, and they also emit radiation rather easily. Air is another matter. It is composed almost entirely of oxygen and nitrogen, each in the form of two identical atoms bonded together in a single molecule. Such molecules barely interact with radiation: they allow free passage to both solar radiation moving downward to the earth and infrared radiation moving upward from the earth’s surface. If that is all there were to the atmosphere, it would be a simple matter to calculate the average temperature of the earth’s surface: it would have to be just warm enough to emit enough infrared radiation to balance the shortwave radiation it absorbed from the sun. (Were it too cool, it would emit less radiation than it absorbed and would heat up; conversely, were it too warm it would cool.) Accounting for the amount of sunlight reflected back to space by the planet, this works out to be about
Fortunately for us, our atmosphere contains trace amounts of other substances that do interact strongly with radiation. Foremost among these is water, H2O, consisting of two atoms of hydrogen bonded to a single atom of oxygen. Because of its more complex geometry, it absorbs and emits radiation far more efficiently than molecular nitrogen and oxygen. In the atmosphere, water exists both in its gas phase (water vapor) and its condensed phase (liquid water and ice) as clouds and precipitation. Water vapor and clouds absorb sunlight and infrared radiation, and clouds also reflect sunlight back to space. The amount of water vapor in a sample of air varies greatly from place to place and time to time, but in no event exceeds about two percent of the mass of the sample. Besides water, there are other gases that interact strongly with radiation; these include CO2, or carbon dioxide (presently about 380 tons for each million tons of air), and CH4, or methane (around 1.7 tons for each million tons of air).
Collectively, the greenhouse gases are nearly transparent to sunlight, allowing the short-wavelength radiation to pass virtually unimpeded to the surface, where much of it is absorbed. (But clouds both absorb and reflect sunlight.) On the other hand, these same gases absorb much of the long-wavelength, infrared radiation that passes through them. To compensate for the heating this absorption causes, the greenhouse gases must also emit radiation, and each layer of the atmosphere thus emits infrared radiation upward and downward.
As a result, the surface of the earth receives radiation from the atmosphere as well as the sun. It is a remarkable fact that, averaged over the planet, the surface receives more radiation from the atmosphere than directly from the sun! To balance this extra input of radiation—the radiation emitted by atmospheric greenhouse gases and clouds—the earth’s surface must warm up and thereby emit more radiation itself. This is the essence of the greenhouse effect.
If air were not in motion, the observed concentration of greenhouse gases and clouds would succeed in raising the average temperature of the earth’s surface to around
Why the climate problem is difficult
This basic climate physics is entirely uncontroversial among scientists. And if one could change the concentration of a single greenhouse gas while holding the rest of the system (except its temperature) fixed, it would be simple to calculate the corresponding change in surface temperature. For example, doubling the concentration of CO2 would raise the average surface temperature by about 1.4°F, enough to detect but probably not enough to cause serious problems. Almost all the controversy arises from the fact that in reality, changing any single greenhouse gas will indirectly cause other components of the system to change as well, thus yielding additional changes. These knock-on effects are known as feedbacks, and the most important and uncertain of these involves water.
A fundamental difference exists between water and most other greenhouse gases. Whereas a molecule of carbon dioxide or methane might remain in the atmosphere for hundreds of years, water is constantly recycled between the atmosphere, land surface, and oceans, so that a particular molecule of water resides in the atmosphere for, on average, about two weeks. On climate time scales, which are much longer than two weeks, atmospheric water is very nearly in equilibrium with the surface, which means that as much water enters the atmosphere by evaporating from the surface as is lost to the surface by rain and snow. One cannot simply tally up the sources and sinks and figure out which wins; a more involved argument is needed.
To make matters worse, water vapor and clouds are far and away the most important greenhouse substances in the atmosphere, and clouds also affect climate not only by sending infrared radiation back to earth and warming it up but by reflecting sunlight back into space, thus cooling the planet. Water is carried upward from its source at the surface by convection currents, which themselves are a byproduct of the greenhouse effect, which tends to warm the air near the surface. Simple physics as well as detailed calculations using computer models of clouds show that the amount of water vapor in the atmosphere is sensitive to the details of the physics by which tiny cloud droplets and ice crystals combine into larger raindrops and snowflakes, and how these in turn fall and partially re-evaporate on their way to the surface. The devil in these details seems to carry much authority with climate.
This complexity is limited, however, because the amount of water in the atmosphere is subject to a fundamental and important constraint. The concentration of water vapor in any sample of air has a strict upper limit that depends on its temperature and pressure: in particular, this limit rises very rapidly with temperature. The ratio of the actual amount of water vapor in a sample to this limiting amount is the familiar quantity called relative humidity. Calculations with a large variety of computer models and observations of the atmosphere all show that as climate changes, relative humidity remains approximately constant. This means that as atmospheric temperature increases, the actual amount of water vapor increases as well. But water vapor is a greenhouse gas. So increasing temperature increases water vapor, which leads to further increases in temperature. This positive feedback in the climate system is the main reason why the global mean surface temperature is expected to increase somewhat more than the
Isn't there, as said, also a negative feedback – i.e. more water vapor produces more clouds, and clouds reflect sun rays back into space, causing cooling ? Feedbacks work in both directions, and it isn't clear what is the net effect.
The amount and distribution of water vapor in the atmosphere is also important in determining the distribution of clouds, which play a complex role in climate. On the one hand, they reflect about 22 percent of the incoming solar radiation back to space, thereby cooling the planet. On the other hand, they absorb solar radiation and both absorb and emit infrared radiation, thus contributing to greenhouse warming. Different global climate models produce wildly different estimates of how clouds might change with changing climate, thus constituting the largest source of uncertainty in climate-change projections.
"Different global climate models produce wildly different estimates of how clouds might change with changing climate, thus constituting the largest source of uncertainty in climate-change projections. "
Well said!
A further complication in this already complex picture comes from anthropogenic aerosols—small solid or liquid particles suspended in the atmosphere. Industrial activity and biomass burning have contributed to large increases in the aerosol content of the atmosphere, and this is thought also to have had a large effect on climate.
The main culprits are the sulfate aerosols, which are created through atmospheric chemical reactions involving sulfur dioxide, another gas produced by the combustion of fossil fuels. These tiny particles reflect incoming sunlight and, to a lesser degree, absorb infrared radiation. Perhaps more importantly, they also serve as condensation nuclei for clouds. When a cloud forms, water vapor does not form water droplets or ice crystals spontaneously but instead condenses onto pre-existing aerosol particles. The number and size of these particles determines whether the water condenses into a few large droplets or many small ones, and this in turn strongly affects the amount of sunlight that clouds reflect and the amount of radiation they absorb.
It is thought that the increased reflection of sunlight to space—both directly by the aerosols themselves and through their effect on increasing the reflectivity of clouds—outweighs any increase in their greenhouse effect, thus cooling the planet. Unlike the greenhouse gases, however, sulfate aerosols only remain in the atmosphere a few weeks before they are washed out by rain and snow. Their abundance is proportional to their rate of production—as soon as production decreases, sulfate aerosols follow suit. Since the early 1980s, improved technology and ever more stringent regulations have diminished sulfate aerosol pollution in the developed countries, aided by the collapse of the
Why is that unclear? Isn't the global aerosol content measurable?
Important uncertainties enter the picture, then, with water (especially clouds) and airborne particulates. But the uncertainties actually go much deeper: indeed, to understand long-term climate change, it is essential to appreciate that detailed forecasts cannot, even in principle, be made beyond a few weeks. That is because the climate system, at least on short time scales, is chaotic.
"…it is essential to appreciate that detailed forecasts cannot, even in principle, be made beyond a few weeks. That is because the climate system, at least on short time scales, is chaotic.
Very important statement. Yet scientists try to make forecasts for 100 years, using models….
The essential property of chaotic systems is that small differences tend to magnify rapidly. Think of two autumn leaves that have fallen next to each other in a turbulent brook. Imagine following them as they move downstream on their way to the sea: at first, they stay close to each other, but the eddies in the stream gradually separate them. At some point, one of the leaves may get temporarily trapped in a whirlpool behind a rock while the other continues downstream. It is not hard to imagine that one of the leaves arrives at the mouth of the river days or weeks ahead of the other. It is also not hard to imagine that a mad scientist, having equipped our brook with all kinds of fancy instruments for measuring the flow of water and devised a computer program for predicting where the leaves would go, would find it almost impossible to predict where the leaf would be even an hour after it started its journey.
Let’s go back to the two leaves just after they have fallen in the brook, and say that at this point they are ten inches apart. Suppose that after 30 minutes they are ten feet apart, and this distance increases with time. Now suppose that it were possible to rewind to the beginning but this time start the leaves only five inches apart. It would not be surprising if it took longer—say an hour—before they are once again
The same principle applies if, instead of having two leaves, we have a single leaf and a computer model of the leaf and the stream that carries it. Even if the computer model is perfect and we start off with a perfect representation of the state of the brook, any error—even an infinitesimal one—in the timing or position of the leaf when it begins its journey will lead to the forecast being off by at least ten feet after six hours, and greater distances at longer times. Prediction beyond a certain time is impossible.
Not all chaotic systems have this property of limited predictability, but our atmosphere and oceans, alas, almost certainly do. As a result, it is thought that the upper limit of the predictability of weather is around two weeks. (That we are not very close to this limit is a measure of the imperfection of our models and our measurements.)
While the day-to-day variations of the weather are perhaps the most familiar examples of environmental chaos, variations at longer time scales can also behave chaotically. El Niño is thought to be chaotic in nature, making it difficult to predict more than a few months in advance. Other chaotic phenomena involving the oceans have even longer time scales, but beyond a few years it becomes increasingly difficult for scientists to tell the difference between chaotic natural variations and what climate scientists called “forced” variability. But this difference is important for understanding the human role in producing climate change.
On top of the natural, chaotic “free” variability of weather and climate are changes brought about by changing “forcing,” which is usually considered to involve factors that are not themselves affected by climate. The most familiar of these is the march of the seasons, brought about by the tilt of the earth’s axis, which itself is independent of climate. The effects of this particular forcing are not hard to separate from the background climate chaos: we can confidently predict that January will be colder than July in, say,
Some of this natural climate forcing is chaotic in nature, but some of it is predictable on long time scales. For example, barring some catastrophic collision with a comet or asteroid, variations of the earth’s orbit are predictable many millions of years into the future. On the other hand, volcanic activity is unpredictable. In any event, the actual climate we experience reflects a combination of free (unforced), chaotic variability, and changes brought about by external forcing, some of which, like volcanic eruptions, are themselves chaotic. And part of this forced climate variability is brought about by us human beings.
Determining humanity’s influence
An important and difficult issue in detecting anthropogenic climate change is telling the difference between natural climate variations—both free and forced—and those that are forced by our own activities.
One way to tell the difference is to make use of the fact that the increase in greenhouse gases and sulfate aerosols dates back only to the industrial revolution of the 19th century: before that, the human influence is probably small. If we can estimate how climate changed before this time, we will have some idea of how the system varies naturally. Unfortunately, detailed measurements of climate did not themselves really begin in earnest until the 19th century; but there are “proxies” for quantities like temperature, recorded in, for example, tree rings, ocean and lake plankton, pollen, and corals.
What is the degree of accuracy of such proxies? To a tenth of a degree?
To one degree F? I don't think so….
Plotting the global mean temperature derived from actual measurements and from proxies going back a thousand years or more reveals that the recent upturn in global temperature is truly unprecedented: the graph of temperature with time shows a characteristic hockey-stick shape, with the business end of the stick representing the upswing of the last 50 years or so. But the proxies are imperfect and associated with large margins of error, so any hockey-stick trends of the past may be masked, though the recent upturn stands above even a liberal estimate of such errors.
The hockey stick has been shown to have been produced by an erroneous statistic method, and is false.
Anyway – the whole hockey stick depicts variations of +- 0.4 degree – are the proxies that it is based on so accurate? Of course not!
We know from written and archeological records that the climate was several degrees warmer in the middle ages (~800-1200 AD) than it is now.
Why are these facts not mentioned? Not even in order to be refuted? Strange omission. It's hard to believe that the author is unaware of these claims. If he thinks they are false he has to explain why.
Another way to tell the difference is to simulate the climate of the last 100 years or so with climate models. Computer modeling of global climate is perhaps the most complex endeavor ever undertaken by mankind. A typical climate model consists of millions of lines of computer instructions designed to simulate an enormous range of physical phenomena, including the flow of the atmosphere and oceans, condensation and precipitation of water inside clouds, the transfer of solar and terrestrial radiation through the atmosphere, including its partial absorption and reflection by the surface, by clouds and by the atmosphere itself, the convective transport of heat, water, and atmospheric constituents by turbulent convection currents, and vast numbers of other processes. There are by now a few dozen such models in the world, but they are not entirely independent of one another, often sharing common pieces of computer code and common ancestors.
Although the equations representing the physical and chemical processes in the climate system are well known, they cannot be solved exactly. It is computationally impossible to keep track of every molecule of air and ocean, and to make the task viable, the two fluids must be divided up into manageable chunks. The smaller and more numerous these chunks, the more accurate the result, but with today’s computers the smallest we can make these chunks in the atmosphere is around
How, then, can we go about tuning the parameters of a climate model in such a way as to make it a reasonable facsimile of reality? Here important lessons can be learned from our experience with those close cousins of climate models, weather-prediction models. These are almost as complicated and must also parameterize key physical processes, but because the atmosphere is measured in many places and quite frequently, we can test the model against reality several times per day and keep adjusting its parameters (that is, tuning it) until it performs as well as it can. But with climate, there are precious few tests. One obvious hurdle the model must pass is to be able to replicate the current climate, including key aspects of its variability, such as weather systems and El Niño. It must also be able to simulate the seasons in a reasonable way: the summers must not be too hot or the winters too cold, for example.
Beyond a few simple checks such as these, there are not too many ways to test the model, and projections of future climates must necessarily involve a degree of faith. The amount of uncertainty in such projections can be estimated to some extent by comparing forecasts made by many different models, with their different parameterizations (and, very likely, different sets of coding errors). We operate under the faith that the real climate will fall among the projections made with the various models; in other words, that the truth will lie somewhere between the higher and lower estimates generated by the models.
We operate under the faith that the real climate will fall among the projections made with the various models;
Indeed, that's what it is –faith. Not facts. Not science. Just faith.
The figure above shows the results of two sets of computer simulations of the global average surface temperature of the 20th century using a particular climate model. In the first set, denoted by blue, only natural, time-varying forcings are applied; these consist of variable solar output and “dimming” owing to aerosols produced by known volcanic eruptions. The second set (in red) adds in the man-made influences on sulfate aerosols and greenhouse gases. In each set, the model is run four times beginning with slightly different initial states, and the range among the four ensemble members is denoted by the shading in the figure, reflecting the free random variability of the climate produced by this model, while the colored curves show the average of the four ensemble members. The observed global average surface temperature is depicted by the black curve. One observes that the two sets of simulations diverge during the 1970s and have no overlap at all today, and that the observed global temperature also starts to fall outside the envelope of the all-natural simulations in the 1970s. This exercise has been repeated using many different climate models, with the same qualitative result: one cannot simulate the evolution of the climate over last 30 years without including in the simulations mankind’s influence on sulfate aerosols and greenhouse gases. This, in a nutshell, is why almost all climate scientists today believe that man’s influence on climate has emerged from the background noise of natural variability.
Ok, it's climate models, not facts.
It was explicitly stated that the belief in climate models is just a belief. The climate is far too complicated, and contains a great number of unknown factors, and a great number of factors, that though known, cannot be measured with precision.
Yet, all the case of alarmists rests on those models, and on them alone!
It was very well explained how complicated and chaotic the climate is, and how many unknown and un-measurable factors are involved, and how difficult it is to check the correctness of models.
Yet – by a jump of faith – the result of these models is presented as a scientific fact. It is – in my opinion, a mere guess, not a fact. We don't know how good a guess.
The consequences
Projections based on climate models suggest that the globe will continue to warm another 3 to
Is this really so bad? In all the negative publicity about global warming, it is easy to overlook the benefits: It will take less energy to heat buildings, previously infertile lands of high latitudes will start producing crops, and there will be less suffering from debilitating cold waves. Increased CO2 might also make crops grow faster. On the down side, there will be more frequent and more intense heat waves, air conditioning costs will rise, and previously fertile areas in the subtropics may become unarable. Sure, there will be winners and losers, but will the world really suffer in the net? Even if the changes we are bringing about are larger than the globe has experienced in the last few thousand years, they still do not amount to the big natural swings between ice ages and interglacial periods, and the earth and indeed human beings survived these.
Even if the changes we are bringing about are larger than the globe has experienced in the last few thousand years,
Wrong on two counts
- "we are bringing" – if you have big faith in those models…
- "larger than" – even the predicted change isn't larger than what we had 1000 years ago!
But there are consequences of warming that we cannot take so lightly. During the peak of the last ice age, sea level was some
Were the entire
Is that a possibility? Does anyone predict that? Does any scientist predict the melting of the entire
If not – why mention it? Isn't that false alarmist hyperbole? Isn't that cheap, sensationalist journalism?
My own work has shown that hurricanes are responding to warming sea surface temperatures faster than we originally expected, especially in the
Are there any "substantial changes in hurricane activity" already recorded and proven? Seems to me there are not. This is just unsubstantiated fear .
"substantial changes in hurricane activity" caused by the paltry 1 deg F that temperatures have risen so far in the last 100 years ?
Basic theory and models show another consequential result of a few degrees of warming. The amount of water vapor in the air rises exponentially with temperature: a seven-degree increase in temperature increases water vapor by 25 percent. One might at first suppose that since the amount of water ascending into clouds increases, the amount of rain that falls out of them must increase in proportion. But condensing water vapor heats the atmosphere, and in the grand scheme of things, this must be compensated by radiative heat loss.
Wrong. "condensing water vapor heats the atmosphere" ? No. The water vapor, when it was formed by evaporation, has absorbed energy from the earth (and the atmosphere), when it condenses it releases that same energy. There is no net addition of energy (and heat) involved in condensation.
On the other hand, simple calculations show that the amount of radiative heat loss increases only very slowly with temperature, so that the total heating by condensation must increase slowly as well. Models resolve this conundrum by making it rain harder in places that are already wet and at the same time increasing the intensity, duration, or geographical extent of droughts. Thus, the twin perils of flood and drought actually both increase substantially in a warmer world.
It is particularly sobering to contemplate such outcomes in light of the evidence that smaller, natural climate swings since the end of the last ice age debilitated and in some cases destroyed entire civilizations in such places as Mesopotamia, Central and South America, and the southwestern region of what is today the
That is a new claim, never heard it before. Any evidence? (For the claim that past civilizations were destroyed by climate swings… ).
Suddenly, out of the blue, new factoids are born!
In pushing the climate so hard and so fast,
In pushing the climate so hard and so fast
What does this mean? Who is pushing what? The whole article detailed in great detail the uncertainties and the impossibility of making predictions – yet all of a sudden the climate is pushed hard and fast!
we are also conscious of our own collective ignorance of how the climate system works.
we are also conscious of our own collective ignorance of how the climate system works.
Nevertheless we must ignore our "collective ignorance" and behave as if we knew all about climate change with scientific certainty! Out of our "collective ignorance" we confidently predict catastrophe.
Perhaps negative-feedback mechanisms that we have not contemplated or have underestimated will kick in, sparing us from debilitating consequences. On the other hand, the same could be said of positive feedbacks, and matters might turn out worse than projected. The ice-core record reveals a climate that reacts in complex and surprising ways to smoothly and slowly changing radiative forcing caused by variations in the earth’s orbit. Far from changing smoothly, it remains close to one state for a long time and then suddenly jumps to another state. We do not understand this, and are worried that a sudden climate jump may be part of our future.
Perhaps negative-feedback mechanisms that we have not contemplated or have underestimated will kick in, sparing us from debilitating consequences. On the other hand, the same could be said of positive feedbacks, and matters might turn out worse than projected.
"…will kick in, sparing us from debilitating consequences. "
Even if no feedbacks kick in at all, there will be no "debilitating consequences"… (the 3 to 9 deg F over 100 years are by no means "debilitating consequences").
What you say in fact is that we know absolutely nothing. There may be positive feedback, there may be negative feedbacks, and we have no clue as to what the case is. This is absolutely correct.
Yet you say that "we are worried" about the unknown.
Well, man was always worried about the unknown. Maybe correctly so. But this is no science. This is pure sentimentalist, intangible fear.
Maybe justified, maybe in the end – correct – but devoid of any anchor in facts or in science. Purely irrational fear (though it's not impossible that what we fear will happen, it's only that we don't know, and cannot know, but we fear the unknown anyway).
Science, politics, and the media
Science proceeds by continually testing and discarding or refining hypotheses, a process greatly aided by the naturally skeptical disposition of scientists. We are, most of us, driven by a passion to understand nature, but that means being dispassionate about pet ideas. Partisanship—whatever its source—is likely to be detected by our colleagues and to yield a loss of credibility, the true stock of the trade. We share a faith—justified by experience—that at the end of the day, there is a truth to be found, and those who cling for emotional reasons to wrong ideas will be judged by history accordingly, whereas those who see it early will be regarded as visionaries.
The evolution of the scientific debate about anthropogenic climate change illustrates both the value of skepticism and the pitfalls of partisanship. Although the notion that fossil-fuel combustion might increase CO2 and alter climate originated in the 19th century, general awareness of the issue dates to a National Academy of Sciences report in 1979 that warned that doubling CO2 content might lead to a three-to-eight-degree increase in global average temperature. Then, in 1988, James Hansen, the director of NASA’s Goddard Institute for Space Studies, set off a firestorm of controversy by testifying before Congress that he was virtually certain that a global-warming signal had emerged from the background climate variability. At that time, less was known about natural climate variability before the beginning of systematic instrumental records in the nineteenth century, and only a handful of global climate simulations had been performed. Most scientists were deeply skeptical of Hansen’s claims; I certainly was. It is important to interpret the word “skeptical” literally here: it was not that we were sure of the opposite, merely that we thought the jury was out.
At roughly this time, radical environmental groups and a handful of scientists influenced by them leapt into the fray with rather obvious ulterior motives. This jump-started the politicization of the issue, and conservative groups, financed by auto makers and big oil, responded with counterattacks.
financed by auto makers and big oil,
Nonesense. "Our own motives are always pure and true, but our opponents are motivated by filthy lucre!" It can't be that they have a case, that their theories need to be addressed, and are as valuable and as plausible as ours. No! They are motivated by filthy lucre, while we have a monopoly on noble motives!
They are insincere frauds, while we are honest and pure of heart!
Indeed, a very scientific claim J.
This reveals the true colors of the author. He isn't conscious of the absurdity of these claims.
This also marked the onset of an interesting and disturbing phenomenon that continues to this day. A very small number of climate scientists adopted dogmatic positions and in so doing lost credibility among the vast majority who remained committed to an unbiased search for answers. On the left, an argument emerged urging fellow scientists to deliberately exaggerate their findings so as to galvanize an apathetic public, an idea that, fortunately, failed in the scientific arena but which took root in
As the global-warming signal continues to emerge, this soap opera is kept alive by a dwindling number of deniers constantly tapped for interviews by journalists who pretend to look for balance.
So, those that have opposing theories and opinions aren't to be taken seriously, they are just "deniers"… We are the sole oracles of truth.
These claims take on a religious dimension – which is not surprising, being based, as the author stated himself – on faith (faith in impossible models).
And this – by a person who decries "extremists and dogmatists on both sides" !!
While the American public has been misinformed by a media obsessed with sensational debate, climate scientists developed a way forward that helps them to compare notes and test one another’s ideas and also creates a valuable communication channel. Called the Intergovernmental Panel on Climate Change, or IPCC, it produces a detailed summary of the state of the science every four years, with the next one due out in February 2007. Although far from perfect, the IPCC involves serious climate scientists from many countries and has largely withstood political attack and influence.
While the American public has been misinformed by a media obsessed with sensational debate,
Never has a truer statement be made! This whole global warming alarmism is a matter of the public being "misinformed by a media obsessed with sensational debate".
The IPCC reports are fairly candid about what we collectively know and where the uncertainties probably lie. In the first category are findings that are not in dispute, not even by les refusards:
Refusards – deniers … very scientific terms….
• Concentrations of the greenhouse gases carbon dioxide, methane, ozone, and nitrous oxide are increasing owing to fossil-fuel consumption and biomass burning. Carbon dioxide has increased from its pre-industrial level of about 280 parts per million (ppmv) to about 380 ppmv today, an increase of about 35 percent. From ice-core records, it is evident that present levels of CO2 exceed those experienced by the planet at any time over at least the past 650,000 years.
• Concentrations of certain anthropogenic aerosols have also increased owing to industrial activity.
• The earth’s average surface temperature has increased by about
Big deal! This is far below the accuracy level of our measuring instruments and methods over those 100 years!
We must distinguish between predictions of the future, which are speculative and ridden with uncertainties, and facts – which state what happened in the past, and are based on measurement.
So far there hasn't been much global warming. This is an undisputed fact. 1.2 deg F isn't much.
The whole debate is about future warming.
• Sea level has risen by about
• The annual mean geographical extent of arctic sea ice has decreased by 15 to 20 percent since satellite measurements of this began in 1978.
In the second category are findings that most climate scientists agree with but are disputed by some:
• The global mean temperature is now greater than at any time in at least the past 500 to 1,000 years.
Greater by how much? 0.4 degrees ? Do our proxy measuring methods give us results accurate to fractions of degrees ?
(And this factoid isn't even true! It ignores the warm middle ages period.)
• Most of the global mean temperature variability is caused by four factors: variability of solar output, major volcanic eruptions, and anthropogenic sulfate aerosols and greenhouse gases.
What about earth's axis inclination variation, mentioned before? Can we be sure there aren't additional factors?
• The dramatic rise in global mean temperature in the past 30 years is owing primarily to increasing greenhouse-gas concentrations and a leveling off or slight decline in sulfate aerosols.
The dramatic rise in global mean temperature
Dramatic ?? Dramatic?? How much exactly?? Is "dramatic" a scientific term? Why jump from science to journalistic hyperbole ?
Is 0.4 degrees "dramatic"? How ? How many degrees is this "dramatic rise"?
Those agreed upon 1.2 deg F of the last century include the "dramatic rise" of the last 30 years !
• Unless measures are taken to reduce greenhouse-gas production, global mean temperature will continue to increase, about 2.5 to
These are the only uncertainties? What about all those enumerated so eloquently in the first part of this article?
• As a result of the thermal expansion of sea water and the melting of polar ice caps, sea level will increase six to
• Rainfall will continue to become concentrated in increasingly heavy but less frequent events.
• The incidence, intensity, and duration of both floods and drought will increase.
• The intensity of hurricanes will continue to increase, though their frequency may dwindle.
As stated – these are highly speculative predictions, not accepted by all scientists.
But even if true – not catastrophic.
All these projections depend, of course, on how much greenhouse gas is added to the atmosphere over the next century, and even if we could be certain about the changes, estimating their net effect on humanity is an enormously complex undertaking,
estimating their net effect on humanity is an enormously complex undertaking,
Nevertheless we confidently predict catastrophe.
pitting uncertain estimates of costs and benefits against the costs of curtailing greenhouse-gas emissions. But we are by no means certain about what kind of changes are in store, and we must be wary of climate surprises. Even if we believed that the projected climate changes would be mostly beneficial, we might be inclined to make sacrifices as an insurance policy against potentially harmful surprises.
we might be inclined to make sacrifices
Depends on the cost – how big a sacrifice? And how sure can we be that the sacrifice will have the desired effect (i.e. – will not be in vain)?
The politics of global climate change
(Ok, since the science is already settled, we scientists can now indulge in politics)!
Especially in the
Paradoxes abound on the political left as well. A meaningful reduction in greenhouse-gas emissions will require a shift in the means of producing energy, as well as conservation measures. But such alternatives as nuclear and wind power are viewed with deep ambivalence by the left. Senator Kennedy, by most measures our most liberal senator, is strongly opposed to a project to develop wind energy near his home in Hyannis, and environmentalists have only just begun to rethink their visceral opposition to nuclear power. Had it not been for green opposition, the
But such alternatives as nuclear and wind power are viewed with deep ambivalence by the left.
False. Nuclear power is viewed with deep abhorrence by the left, no ambivalence at all!
There are other obstacles to taking a sensible approach to the climate problem. We have preciously few representatives in Congress with a background or interest in science, and some of them display an active contempt for the subject. As long as we continue to elect scientific illiterates like James Inhofe, who believes global warming to be a hoax, we will lack the ability to engage in intelligent debate.
"As long as we continue to elect scientific illiterates like James Inhofe"
Heh ! Could you please name some members of Congress that are scientifically literate?
Or do you wish to imply that only scientist are qualified to serve in Congress?
Or that anyone who disagrees with you is "scientifically illiterate"?
A not very scientific statement! The temper has trumped his brain!
Scientists are most effective when they provide sound, impartial advice, but their reputation for impartiality is severely compromised by the shocking lack of political diversity among American academics, who suffer from the kind of group-think that develops in cloistered cultures. Until this profound and well documented intellectual homogeneity changes, scientists will be suspected of constituting a leftist think tank.
On the bright side, the governments of many countries, including the
the governments of many countries, including the
Here is a prejudice that all depends on governments, that only governments can tackle the problem.
Like it or not, we have been handed Phaeton’s reins, and we will have to learn how to control climate if we are to avoid his fate. <
When this happens, we can get down to the serious business of tackling the most complex and perhaps the most consequential problem ever confronted by mankind.
How do we tackle?
What needs to be done? What can produce the desired effect of reducing CO2 ?
We need to do…. Much is to be done… WHAT?? What exactly ?
There is nothing we can do!
(Except nuclear power, and except what is being done already – like research).
The alternative is to drastically reduce our use of energy – and that would have worse consequences, by far, that the supposed (and claimed, and guessed) effects of global warming.
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