Guest Post by Willis Eschenbach
First, I would like to thank Dr. Meier of the National Snow and Ice Data Center (NSIDC) for answering the questions I had posed (and had given my own personal answers) in “Trust and Mistrust”. I found his replies to be both temperate and well-reasoned. Also, I appreciate the positive and considerate tone of most of those who commented on his reply. It is only through such a peaceful and temperate discussion that we can come to understand what the other side of the debate thinks.
Onwards to the questions, Dr. Meier’s answers, and my comments:
Question 1. Does the earth have a preferred temperature, which is actively maintained by the climate system?
Willis says that he “believes the answer is yes”. In science “belief” doesn’t have much standing beyond initial hypotheses. Scientists need to look for evidence to support or refute any such initial beliefs. So, does the earth have a preferred temperature? Well, there are certainly some self-regulating mechanisms that can keep temperatures reasonably stable at least over a certain range of climate forcings. However, this question doesn’t seem particularly relevant to the issue of climate change and anthropogenic global warming. The relevant question is: can the earth’s temperature change over a range that could significantly impact modern human society?
My comment: Since unfortunately so little attention has been given to this important question, my idea of how it works is indeed a hypothesis. Therefore, “belief” is appropriate. However, I have provided several kinds of evidence in support of the hypothesis at the post I cited in my original answer to this question, “The Thermostat Hypothesis”.
Next, Dr. Meier says that there are “some self-regulating mechanisms that can keep temperature reasonably stable at least over a certain range of climate forcings.” Unfortunately, he does not say what the mechanisms might be, at what timescale they operate, or what range of forcings they can handle.
However, he says that they can safely be ignored in favor of seeing what the small changes are, which doesn’t make sense to me. Before we start looking at what causes the small fluctuations in temperature that we are discussing (0.6°C/century), we should investigate the existence and mechanism of large-scale processes that regulate the temperature. If we are trying to understand a change in the temperature of a house, surely one of the first questions we would want answered is “does the house have a thermostat?” The same is true of the climate.
Question 2: Regarding human effects on climate, what is the null hypothesis?
I will agree with Willis here – at one level, the null hypothesis is that any climate changes are natural and without human influence. This isn’t controversial in the climate science community; I think every scientist would agree with this. However, this null hypothesis is fairly narrow in scope. I think there is actually a more fundamental null hypothesis, which I’ll call null hypothesis 2 (NH2): are the factors that controlled earth’s climate in the past the same factors that control it today and will continue to do so into the future? In other words are the processes that have affected climate (i.e., the forcings – the sun, volcanic eruptions, greenhouse gases, etc.) in the past affecting climate today and will they continue to do so in the future? A basic premise of any science with an historical aspect (e.g., geology, evolution, etc.) is that the past is the key to the future.
My Comment: I assume that Dr. Meier has temporarily overlooked the fact that a null hypothesis is a statement rather than a question. Thus, his Null Hypothesis 2 (NH2) should be:
NH2: The factors that controlled earth’s climate in the past are the same factors that control it today and will continue to do so into the future
However, this formulation has some serious problems. First, a null hypothesis must be capable of being falsified. My null hypothesis (NH1) could be falsified easily, by a showing that measurements of the modern climate are outside the historical values.
Dr. Meier’s NH2, on the other hand, extends into the future … how can we possibly falsify that?
Second, to determine if the factors that controlled the climate in the past are the same factors that control it now, we must know the factors that controlled climate in the past, and we must know the factors that control climate now. But that is exactly the subject being debated – what controls the climate? We don’t know the answer to that for the present, and we know even less about it for the past. So again, his NH2 is not falsifiable.
Finally, there is a more fundamental problem with NH2. The null hypothesis has to be the logical opposite of the alternate hypothesis, so that if one is true, the other must be false. My null hypothesis NH1 is that the currently observed climate variations are the result of natural variation. The opposite of my null hypothesis is the alternate hypothesis, that currently observed climate variations are the result of human-caused GHG increases.
However, what is the opposite of NH2, which states that the factors that controlled climate in the past are those that control climate today? The opposite of that is the alternate hypothesis that the factors that controlled climate in the past are not those that control climate today.
But I have never once, in this entire decades-long debate, heard anyone make the claim that some factors that affected climate in the past have stopped affecting the climate. As a result, NH2 is a straw man. It is the null hypothesis for an alternate hypothesis that no one is propounding.
Since it is not falsifiable, and since it is a straw man null hypothesis, Dr. Meier has not proposed a valid null hypothesis. As a result, his arguments that follow from that null hypothesis are not relevant.
Question 3: What observations tend to support or reject the null hypothesis?
Let me first address NH2. We have evidence that in the past the sun affected climate. And as expected we see the current climate respond to changes in solar energy. In the past we have evidence that volcanoes affected climate. And as expected we see the climate respond to volcanic eruptions (e.g., Mt. Pinatubo). And in the past we’ve seen climate change with greenhouse gases (GHGs). And as expected we are seeing indications that the climate is being affected by changing concentrations of GHGs, primarily CO2. In fact of the major climate drivers, the one changing most substantially over recent years is the greenhouse gas concentration. So what are the indications that climate is changing in response to forcing today as it has in the past? Here are a few:
1. Increasing concentrations of CO2 and other GHGs in the atmosphere
2. Rising temperatures at and near the surface
3. Cooling temperatures in the stratosphere (An expected effect of CO2-warming, but not other forcings)
4. Rising sea levels
5. Loss of Arctic sea ice, particularly multiyear ice
6. Loss of mass from the Greenland and Antarctic ice sheets
7. Recession of most mountain glaciers around the globe
8. Poleward expansion of plant and animal species
9. Ocean acidification (a result of some of the added CO2 being absorbed by the ocean)
It is possible that latter 8 points are completely unrelated to point 1, but I think one would be hard-pressed to say that the above argues against NH2.
My Comment: Saying “it is possible that the latter 8 points are completely unrelated to point 1” begs the question. It is possible that they are related, but that is the question at hand that we are trying to answer. If Dr. Meier thinks that they are related, he needs to establish causation, not just say it is “possible that [they] are completely unrelated”.
Whether his points argue for or against NH2 is not relevant, since NH2 is not falsifiable, and is a null hypothesis for a position no one is taking. In addition, they are presented as “indications that climate is changing in response to forcing today as it has in the past” … but it is a mix of statements about forcings, and responses to increasing warmth. So I don’t see how that applies to NH2 in any case.
Despite those problems, let me address them, one by one, starting with one without a number:
In the past we’ve seen climate change with greenhouse gases (GHGs): This cries out for a citation, but there is none. When did we see that, who showed it, what evidence is there to support it?
1. Increasing concentrations of CO2 and other GHGs in the atmosphere: Yes, GHGs are increasing. However, this says nothing either way about NH2.
2. Rising temperatures at and near the surface: Yes, temperatures generally have been rising, and they have been ever since the Little Ice Age in the mid 1600’s. But again, what does this have to do with NH2?
3. Cooling temperatures in the stratosphere (An expected effect of CO2-warming, but not other forcings): I would greatly appreciate a citation to the claim that this is an expected result of GHG forcing but not other forcings. Given our general lack of understanding of the climate, it would be a very difficult claim to establish.
For one of the reasons why it would be hard to establish, here is the actual change in the stratospheric temperatures:
Figure 1. UAH and RSS satellite measurements of stratospheric temperature. DATA SOURCES UAH, RSS
Now, how on earth (or off earth and in the stratosphere) is that an “expected effect” of increasing GHGs? Since recovering from the Pinatubo eruption stratospheric temperatures have been stable … which climate model projected that outcome? What theoretical calculations showed that flat-line response?
4. Rising sea levels: Sea levels have been rising since 1900. If GHGs were driving the rise, we would expect to see an acceleration in the rate of rise corresponding to the acceleration in the rise of GHGs. However, we have seen no such acceleration in the long-term, and we see deceleration in the short-term. Here are two long-term records. Fig.2 is from Church and White and Jevrejeva:
Figure 2. Church & White and Jevrejeva sea level records from tidal stations. Photo is of Dauphin Island Tidal Station. PHOTO SOURCE
There is good agreement between the Church & White and the Jevrejeva records. As they were calculated in different ways, this increases the confidence in the result. Note that, despite increasing CO2, there is no increase in the rate of sea level rise.
Next, we have a short-term but presumably more accurate sea level record from the TOPEX satellite. Fig. 3 shows that record:
Figure 3. Sea level record from the TOPEX satellite. Black line is the trend from 1993 to 2004, and is projected to 2007 in gray. Red line is the trend since 2004.
As you can see, rather than increasing, the rate of sea level rise has dropped in recent years. And while it may well start to rise again, it is certainly not accelerating as the AGW hypothesis requires.
5. Loss of Arctic sea ice, particularly multiyear ice: As Dr. Meier would agree, the satellite record of Arctic ice is quite short, much shorter than the long-term changes in Arctic temperatures. The Arctic was as warm or warmer in the 1930s, and many records from that time attest to greatly reduced ice conditions. Both the Polyakov and the NORDKLIM records [see Update 10] show the time around 1979 as being about the bottom of the Arctic temperature swing, so reducing Arctic sea ice is to be expected since 1979. In addition, I was surprised that Dr. Meier did not mention the last three years, which have seen both increasing Arctic sea ice and increasing multiyear sea ice.
6. Loss of mass from the Greenland and Antarctic ice sheets: NASA reports that the GRACE satellite data shows the Antarctic and Greenland ice sheets to be losing a total of ~ 1,700 cubic km of ice per year. While this sounds large, this is about 0.005% of the total ice in the two sheets … I hardly see this as indicating anything but a confirmation that the earth has been warming for centuries, and is generally continuing to do so with the usual fits and starts. Since at the current rate of loss it will take about two hundred years to lose 1% of the ice, I don’t see this as a critical issue.
7. Recession of most mountain glaciers around the globe: According to the NSIDC, the excellent organization that Dr. Meier works for, there are about 100,000 glaciers on the planet. Again according to the NSIDC, we have measured the mass balance on 300 of them, and we have continuous records since 1960 for only 60 of them … so we have at least one record on 0.3% of the glaciers, and decent (although short) records on 0.1% of the glaciers. Given those percentages, “recession of most mountain glaciers” seems to be a bit of an overstatement of what scientific research actually has shown …
It is true that many of the glaciers we have measured have receded since the colder period of the 1960s when the records started. It is also true that some are advancing. Many of the known glaciers have been generally receding since sometime after the Little Ice Age in the 1600’s. Before that, they were advancing, so much so that in 1678 the village of Aletsch in Switzerland made a formal church vow to live virtuously if only the nearby advancing glacier would not over-run their village … a vow which they are now trying to recant as the glacier recedes. That dratted climate never stops changing.
All this shows is that when the earth cools, glaciers generally advance, and when it warms, they generally retreat. Surprising, huh? It says nothing about whether or not GHGs control the temperature.
8. Poleward expansion of plant and animal species: Animals and plants advance and retreat with the seasons and with the climate. In a time of general warming, like the last 300 years, we would expect them to move slightly polewards. However, care is required, because climate change is blamed for everything. For example, in this South African study (subscription required), they say (emphasis mine):
Evidence from the Northern Hemisphere and simple theoretical models both predict that climate change could force southern African birds to undergo poleward range shifts. We document the chronology and habitat use of 18 regionally indigenous bird species that colonised the extreme south-western corner of Africa after the late 1940s. This incorporates a period of almost four decades of observed regional warming in the Western Cape, South Africa. Observations of these colonisation events concur with a ‘climate change’ explanation, assuming extrapolation of Northern Hemisphere results and simplistic application of theory. However, on individual inspection, all bar one may be more parsimoniously explained by direct anthropogenic changes to the landscape than by the indirect effects of climate change. Indeed, no a priori predictions relating to climate change, such as colonisers being small and/or originating in nearby arid shrublands, were upheld.
9. Ocean acidification (a result of some of the added CO2 being absorbed by the ocean): Again, this appears to be happening, although we have very little in the way of data. If verified, this would indicate that atmospheric CO2 levels are rising … but we knew that already.
Overall, Dr. Meier’s points show that when the world warms we are likely to see various phenomena related to that warming. But that says nothing about his null hypothesis NH2, nor about my null hypothesis. None of them either support NH2 nor falsify NH2, as NH2 is a straw null hypothesis that cannot be falsified. They also say nothing about whether GHGs are currently causing unusual warming.
Next, Dr. Meier addresses NH1, my null hypothesis:
Of course none of the above says anything about human influence, so let’s now move on to Willis’ null hypothesis, call it null hypothesis 1 (NH1). Willis notes that modern temperatures are within historical bounds before any possible human influence and therefore claims there is no “fingerprint” of human effects on climate. This seems to be a reasonable conclusion at first glance. However, because of NH2, one can’t just naively look at temperature ranges. We need to think about the changes in temperatures in light of changes in forcings because NH2 tells us we should expect the climate to respond in a similar way to forcings as it has in the past. So we need to look at what forcings are causing the temperature changes and then determine whether if humans are responsible for any of those forcings. We’re seeing increasing concentrations of CO2 and other GHGs in the atmosphere. We know that humans are causing an increase in atmospheric GHGs through the burning of fossil fuels and other practices (e.g., deforestation) – see Question 6 below for more detail. NH2 tells us that we should expect warming and indeed we do, though there is a lot of short-term variation in climate that can make it difficult to see the long-term trends.
So we’re left with two possibilities:
1. NH2 is no longer valid. The processes that have governed the earth’s climate throughout its history have suddenly starting working in a very different way than in the past.
Or
2. NH1 is no longer valid. Humans are indeed having an effect on climate.
Both of these things may seem difficult to believe. The question I would ask is: which is more unbelievable?
This is a false dichotomy, created by using my real null hypothesis NH1, and Dr. Meier’s straw man null hypothesis NH2. Yes, both CO2 and temperatures rose over the 20th century … but correlation is not causation, and CO2 does not correlate any better with temperature than a straight line correlates with temperature. Next, Dr. Meier seems to think that NH1 and NH2 are somehow related, so that one or the other must be false. But both could easily be true. It could be true that the climate variations are natural (NH1), and also true that the historical forcings still apply (NH2). So his “one true / one false” duality is not valid.
At the end of the day, as Dr. Meier says himself, none of what he has said falsifies the null hypothesis NH1 that the observed climate changes are natural variations rather than human-caused. Since it is not falsified, we have nothing for the AGW hypothesis to explain. This is an important conclusion.
Skipping over some questions where we generally agree, we come to:
Question 6: How are humans affecting the climate?
Willis mentions two things: land use and black carbon. These are indeed two ways humans are affecting climate. He mentions that our understanding of these two forcings is low. This is true. In fact the uncertainties are of the same order of as the possible effects, which make it quite difficult to tell what the ultimate impact on global climate these will have. However, Willis fails to directly mention the one forcing that we actually have good knowledge about and for which the uncertainties are much smaller (relative to the magnitude of the forcing): greenhouse gases (GHGs). This is because GHGs are, along with the sun and volcanoes, a primary component that regulates the earth’s climate on a global scale.
My Comment: First, despite the IPCC claims, our knowledge of the effects of the GHGs is not as good as our knowledge of the effects of black carbon or deforestation. This is because we can actually measure the effects on the temperature of chopping down a forest. We can actually measure an amount of black carbon on snow, and see what difference it makes to the melting rate of the snow, and the temperature above the snow.
But we cannot make any such measurements for CO2. All of our numbers for the GHG forcings are based on climate models rather than measurements. The IPCC, and many scientists, give them great credence. I, and a number of scientists, do not.
Dr. Meier again:
It might be worth reviewing a few things:
1. Greenhouse gases warm the planet. This comes out of pretty basic radiative properties of the gases and has been known for well over 100 years.
My Comment: This is one of the most widely held misconceptions in the field. Here’s an example of the identical incorrect logical jump, from another field:
It is clear from the basic radiative properties that solar radiation warms what it hits. Therefore, if I walk out into the sunshine, my core body temperature will rise.
Clearly, the mere fact that a source is radiating does not mean that it will necessarily cause whatever the radiation strikes to warm up …
This is a crucial point, and one which is either overlooked or ignored by AGW proponents. Here’s another example. If your house has an air conditioner on a thermostat, despite the sun getting warmer and warmer as the day goes on, the house does not warm up. Again, we have a radiation source which does not cause what it strikes to warm up.
So yes, we know that CO2 is a greenhouse gas. And we know it will increase the forcing, although the amount is not well established.
But we absolutely do not know if that will cause the earth to warm over time. This is why my Question 1 above, about whether the Earth has a thermostat, is so important. If the earth has a thermostat, there are many basic assumptions that need to be reconsidered. I discuss this issue in detail at “The Unbearable Complexity of Climate”.
The short version of that post is that “basic radiative properties” are far from enough to determine what will happen from increased forcing in a complex system such as the climate or the human body, or even in a simple system like an air-conditioned house.
2. Carbon dioxide is a greenhouse gas. This is has been also been known for well over 100 years. There are other greenhouse gases, e.g., methane, nitrous oxide, ozone, but carbon dioxide is the most widespread and longest-lived in the atmosphere so it is more relevant for long-term climate change.
My Comment: Agreed.
3. The concentration of CO2 is closely linked with temperature – CO2 and temperature rise or fall largely in concert with each other. This has been observed in ice cores from around the world with some records dating back over 800,000 years. Sometimes the CO2 rise lags the temperature rise, as seems to be the case in some of ice ages, but this simply means that CO2 didn’t initiate the rise (it is clear that solar forcing did) and was a feedback. But regardless, without CO2 you don’t get swings between ice ages and interglacial periods. To paraphrase Richard Alley, a colleague at Penn State: “the climate history of the earth makes no sense unless you consider CO2”.
My Comment: As temperatures warm and cool, the CO2 levels go up and down. We can see that in the ice core records. SInce CO2 lags temperature in the Vostok ice core records of these changes, this means that the CO2 is not the cause of temperature change. Instead, it is a result of the warming ocean giving off more CO2. So far, Dr. Meier and I totally agree.
He then says “sometimes the CO2 rise lags the temperature rise.” This is not borne out by the data, where the correlation with lagged CO2 is greater than with un-lagged CO2 for the entire dataset. This indicates that the lag is a phenomenon common to the entire time period of the data.
Then Dr. Meier makes the claim that the CO2 “was a feedback”. If this were true, once the CO2 started to rise or fall, we should see a change in the rate of temperature rise or fall. To my knowledge no one has ever mathematically demonstrated such a feedback-driven change in temperature rise or fall in the actual ice core data. In addition to searching the literature for such a demonstration, I have used a variety of mathematical methods to try to find such a lagged feedback effect in the data, without any success. So why does Dr. Meier say that CO2 is operating as a feedback?
Dr. Meier may not even realize it, but he has totally conflated reality and models. What Dr. Meier is trying to say is that “without CO2 the models don’t get swings between ice ages and interglacial periods.” And what Richard Alley has shown is that “the modelled version of the climate history of the earth makes no sense unless you consider CO2”. Neither of them are talking about reality, they are discussing model-ice on Model-world, not ice on the Earth.
This blurring of the line between reality and models is a recurring and very frustrating feature of the climate discussion. I’m talking about reality, and meanwhile, without saying so, Dr. Meier is discussing model results. This habit of climate scientists, of talking about models as if they were discussing reality, is very frustrating and impedes communication.
4. The amount of carbon dioxide (and other GHGs) has been increasing. This has been directly observed for over 50 years now. There is essentially no doubt as to the accuracy of these measurements.
My Comment: Agreed
5. The increase in CO2 is due to human emissions. There are two ways we know this. First, we know this simply through accounting – we can estimate how much CO2 is being emitted by our cars, coal plants, etc. and see if matches the observed increase in the atmosphere; indeed it does (after accounting for uptake from the oceans and biomass). Second, the carbon emitted by humans has a distinct chemical signature from natural carbon and we see that it is carbon with that human signature that is increasing and not the natural carbon.
My Comment: Agreed.
6. Given the above points and NH2, one expects the observed temperature rise is largely due to CO2 and that increasing CO2 concentrations will cause temperatures to continue to rise over the long-term. This was first discussed well over 50 years ago.
My Comment: We have no evidence (not model results but evidence) that at the current general temperature equilibrium, changes in GHG forcing affect the temperature. We have no evidence that they affected temperature in the transitions between glacial and interglacial periods. We have no evidence that there is a linear relationship between temperature and forcing, it may well be temperature dependent and asymptotically approach zero at equilibrium. Yes, as Dr. Meier points out, forcings affect temperature in those situations (and all others) in the models. But I’ve been programming computers for almost fifty years now, and I’ve written too many computer models and I know too much about computers to trust untested, unverified models that are tuned to reproduce the past. Too many parameters, too many degrees of freedom, too much error propagation, too little understanding of important processes, they have, as Kipling said, been “twisted by knaves to make a trap for fools”.
Question 7: How much of the post-1980 temperature change is due to humans?
Here Willis says we get into murky waters and that there is little scientific agreement. And indeed this is true when discussing the factors he’s chosen to focus on: land use and soot. This is because, as mentioned above, the magnitudes of these forcings are small and the uncertainties relatively large. But there is broad scientific agreement that human-emitted CO2 has significantly contributed to the temperature change.
My Comment: Post 1980, the temperatures rose, peaked in 1998, and have been basically level since then. While there is broad agreement on something like “CO2 contributes significantly”, how significantly did it contribute to the post 1998 period of basically no temperature change? The answer, presumably, is unknown. Some scientists see CO2 as a second order forcing, after land use/land cover change (LULCC) and black/brown carbon forcing, particularly for the Arctic. My point is that there is still ongoing scientific discussion on the question of how much each forcing might affect the climate, particularly given that the temperature hasn’t risen in the last decade.
Question 8: Does the evidence from the climate models show that humans are responsible for changes in the climate?
Willis answers by claiming that climate models don’t provide evidence and that evidence is observable and measurable data about the real world. To me evidence is any type of information that helps one draw conclusions about a given question. In legal trials, it is not only hard physical evidence that is admitted, but information such as the state of mind of the defendant, motive, memories of eyewitnesses, etc. Such “evidence” may not have the same veracity as hard physical evidence, such as DNA, but nonetheless it can be useful.
My Comment: I fear this answer makes no sense. Dr. Meier says evidence is “any type of information that helps one draw conclusions”. Many people are helped to draw conclusions by astrology. Does that make astrology evidence? The conclusions of some scientists are shaped by their religious beliefs. Does that make religious beliefs evidence? Hunches and intuition help scientists draw all kinds of conclusions … are they evidence?
I don’t think Dr. Meier really believes what he is saying here. For example, said that above that I think that the earth has a thermostat. The first thing that Dr. Meier said in response to that was “Scientists need to look for evidence to support or refute any such initial beliefs.”
I don’t think he was referring to astrology, or my state of mind, or the memories of eyewitnesses. I think he was talking about data, observations, facts to support my hypothesis. And that is what I have provided at the citation listed above, for the same reason that he asked – because science is based on evidence, data, facts, measurements, and not on states of mind. The modeller’s mantra says “All models are wrong … but some models are useful.” Yes, they are often useful, but they don’t produce evidence.
Regardless, let me first say that I’m a data person, so I’ve always been a bit skeptical of models myself. We certainly can’t trust them to provide information with complete confidence. It may surprise some people, but most modelers recognize this. However, note that in my response to question 6 above, I never mention models in discussing the “evidence” for the influence of human-emitted CO2 on climate. So avoiding semantic issues, let me say that climate models are useful (though far from perfect) tools to help us understand the evidence for human and other influence on climate. And as imperfect as they may, they are the best tool we have to predict the future.
My Comment: As anyone who has looked at a weather forecast for next weekend knows, some models may be the best tool we have and still be no better than flipping a coin.
As to whether the models are useful, we have some simple ways to determine whether a model is useful. One is to see if they can make falsifiable predictions of the future states of a given system. To date, the models have failed miserably at this test. The current hiatus in warming was not predicted by a single model that I know of. Even if the GHG forcing were overwhelmed by natural variations, according to the models the stratosphere should have continued to cool. It did not do so. They have not been able to forecast the trend in the numbers of hurricanes, despite making a host of claims after the recent single-year peak in hurricane numbers. The claim is often made that the models are not accurate in the short-term, but they are accurate in the long-term. I’m still waiting … how long a term does it take until their accuracy starts to show up? Twenty-six years? Fifty-three years? Where is the theory that tells us when they will start to be right?
Another way to judge a model’s usefulness is if it can identify missing factors in a system. The classic example is the discovery of Neptune based on what was missing in models of the solar system. But the climate models are assumed to already contain all the important forcings, so they cannot discover any possible missing forcings. What verified new facts have the models told us about the operation of the climate that we did not already know?
Another way to judge the models is to see if the results of various models agree or not. Figure 4 shows the amount of clouds by latitude from a number of climate models:
Figure 4. Cloud cover of the Earth by latitude, as shown by 31 climate models, from the AMIP study (1999). Black line is the observed cloudiness by latitude.
Dr. Meier, if you think that any of those model results are evidence for the actual cloud cover by latitude, I fear that we have vastly different definitions of “evidence”. They are model results, and are not evidence of latitudinal cloud cover in even the most expansive conceivable definition of evidence. Models can be useful, but their results are not evidence of anything.
Question 9: Are the models capable of projecting climate changes for 100 years?
Based on Willis’ answer to Question 1, I’m surprised at his answer here. If the earth has a preferred temperature, which is actively maintained by the climate system, then it should be quite easy to project climate 100 years into the future. In Question 1, Willis proposed the type of well-behaved system that is well-suited for modeling.
My Comment: I see no theoretical reason that a complex chaotic system with a preferred temperature would be any simpler to model than a complex chaotic system without a preferred temperature. I have provided links in my Thermostat Hypothesis to two simple models of such a system, one by Bejan and one by Ou. However, I do not think that either of them produce evidence, or that either can project the climate a hundred years from now.
However, Willis claims that such a projection is not possible because climate must be more complex than weather. How can a more complex situation be modeled more easily and accurately than a simpler situation? Let me answer that with a couple more questions:
1. You are given the opportunity to bet on a coin flip. Heads you win a million dollars. Tails you die. You are assured that it is a completely fair and unbiased coin. Would you take the bet? I certainly wouldn’t, as much as it’d be nice to have a million dollars.
2. You are given the opportunity to bet on 10000 coin flips. If heads comes up between 4000 and 6000 times, you win a million dollars. If heads comes up less than 4000 or more than 6000 times, you die. Again, you are assured that the coin is completely fair and unbiased. Would you take this bet? I think I would.
But wait a minute? How is this possible? A single coin flip is far simpler than 10000 coin flips. …
I fear I don’t know where to start explaining the host of reasons why this doesn’t work as a metaphor for the difference between a weather model and a climate model, or as an explanation of how climate models could possibly project a hundred years out. But I’ll give it a shot.
Both weather and climate models are what are called “iterative models”. The model looks at the current state of the weather, and predicts what the weather will look like after the next time step (typically under an hour in modern models).
This type of model is very, very hard to get right, because the errors “propagate”. This means that if your calculation of the weather at one time step of the model is off a little, the next time step will likely be off a little more, and on ad infinitum. Error propagation of this type is an unavoidable feature of iterative models. It is one of the main reasons that weather models diverge from the actual weather over a very short period of time. This makes long-term forecasts very difficult.
Predicting the number of heads in 100 flips or a million flips, on the other hand, does not suffer from this problem. It is a simple and well understood statistical problem which can be solved with a single equation. In fact, the more flips, the less error you will find in the result. Ahhh, would that climate could so easily be reduced to a single equation …
Next, coin flips do not contain any variables. They are not affected by things such as humidity or temperature. It’s just the coin, period. That’s why we use them as a decision tool, because they are random, they are not dependent on variables. Weather models, by contrast, have a host of variables: temperature, humidity, barometric pressure, wind speed, wind direction, and many others. They are anything but random.
And while one coin flip has the same number of variables as a thousand coin flips (none), climate models must include a host of variables that can be neglected in weather models. These include variables like terrestrial biology, sea biology, ocean currents, variations in soil moisture, slow changes in ice cover, and lots of others. This makes climate models much more complex than weather models … and in iterative models, this means more sources of error.
Finally, both climate and weather are chaotic. This introduces a host of other problems into any attempt to model the climate or the weather.
As a result, the idea that climate models can project the climate a hundred years out because “a single coin flip is simpler than 10000 coin flips” is untrue, simplistic, and in no way a metaphor which would help us understand the problem with long-term climate model projections of the future.
Moving along, I find:
Question 13: Is the current peer-review system inadequate, and if so how can it be improved?
There is always room for improvement and Willis makes some good suggestions in this regard. Speaking only from my experience, the process works reasonably well (though not perfectly), quality papers eventually get published and bad papers that slip through the peer-review process and get published can be addressed by future papers.
My Comment: I love the idea that “quality papers eventually get published”. It just sounds so good. However, please read Ross McKitrick’s saga with his paper on Surface Temperatures, and Bishop Hill’s post on Caspar and the Jesus Paper, before you become too enamoured of the idea that the system is self-correcting and works in the end. A review of the CRU emails in this regard is in order as well.
From my own experience, I wrote a paper explaining the problems with a study by Michael Mann that had been published in Geophysical Research Letters (GRL). His study claimed that the best way to extend a smooth (Gaussian or otherwise) to the end of a series was to pad the end of the series by reflecting it around both the x and y axes. (This results in forcing the smooth through the last point of the series, which is absolutely the last thing you want to do).
The paper was rejected by GRL because one reviewer said I was too hard on poor Mike. So I set off to re-write it.
Within a few months, Mann published a new paper in GRL on the subject, incorporating my ideas as his own. Coincidence? You be the judge … I threw up my hands, my paper never got published. I think the present peer-review system sucks. The CRU emails contain hosts of references to this kind of scientific malfeasance, stacking peer-review panels with people who will give papers an easy pass, circulating papers like mine to other scientists, blackballing journals, and pressuring editors. We know it is happening, we have their emailed confessions.
Yes, I understand that Dr. Meier’s personal experience is different, and I respect that. But only looking at his own experience is a very restricted view of the situation. The repeated refusal of many climate scientists to go outside their own experience and honestly look at the scientific malfeasance going on in their own field is a constant source of amazement to me.
Question 14: Regarding climate, what action (if any) should we take at this point?
This is of course an economic and political question, not a scientific question, though the best scientific evidence we have can and should inform the answer. So far there isn’t any scientific evidence that refutes NH2 and we conclude that the processes that influenced climate in the past are doing so today and will continue to do so in the future. From this we conclude that humans are having an impact on climate and that this impact will become more significant in the future as we continue to increase GHGs in the atmosphere. Willis answers no and claims that the risks are too low to apply the precautionary principle. The basis for his answer, in practical terms, is his conclusion that NH2 is no longer valid because while GHGs have been a primary climate forcing throughout earth’s history, they are no longer having an impact. This could of course be true, but to me there doesn’t seem to be much evidence to support this idea. But then again, I’m a skeptic.
My Comment: First, NH2 is not falsifiable and is a straw null hypothesis. Second, I make no claim that the factors operating now did not operate in the past. I did not conclude that “NH2 is no longer valid because while GHGs have been a primary climate forcing throughout earth’s history, they are no longer having an impact” as Dr. Meier claims, and I am mystified that my words could be misunderstood in that way.
Also, I did not say that “the risks are too low to apply the precautionary principle”. I said “I disagree with those who say that the “precautionary principle” means that we should act now. I detail my reasons for this assertion at “Climate, Caution, and Precaution”. And nothing at that link says that the issue is that the “risks are too low”, I have no clue where Dr. Meier got that claim.
Regrettably, after explaining why he thinks that I’m wrong about what action to take, Dr. Meier does not say what action (if any) he thinks we should take.
Final Conclusions, in no particular order
1. Reading Dr. Meier’s answers to the questions has been very interesting and very productive for me. It has helped to identify where the discussion goes off the rails.
2. Understanding how the guy on the other side of the table sees the situation is valuable for everyone concerned.
3. Dr. Meier’s answers were well thought out and well expressed. He obviously has considered these matters in detail, answered honestly and fully, and taken the time to lay them out clearly.
4. As I didn’t discuss most of the questions where Dr. Meier and I were in basic agreement, it likely appears that I disagreed on almost all points. This is absolutely not the case.
5. I wish that Dr. Meier had included citations for his assertions. Not having them makes it harder to discuss his ideas.
6. I sincerely hope that I have not offended Dr. Meier. I am a reformed cowboy, but despite going to the cowboy reform meetings and following the twelve steps, sometimes the raw ranch kid shines through. I am passionate about these matters, and sometimes I overstep the bounds. I apologize for any sins of omission or sins of commission I may have committed, and I hope that Dr. Meier considers my words in the spirit of vigorous scientific debate.
7. Since the null hypothesis that the climate variations are natural has not been falsified, the AGW hypothesis is still a solution in search of a problem.
8. As I have found out more than once to my own cost, putting one’s ideas out on the web for people to find fault with is a daunting prospect, and one which may not always end well. I offer Dr. Meier my profound thanks and my respect for his courage and willingness to put his ideas on the firing line, as it is not an easy thing to do.
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That’s my point – We’ll never reach a time when overall concentrations of man made c02 aren’t increasing.
Wren (00:33:53) : I think the coin-flip analogy was supposed to show that you can be more confident in the outcome of a 1,000 flips than a few flips. Even though the odds are against two successive heads or tails (only 0.25), it happens frequently. The odds against 1,000 successive heads or tails, however, are virtually nil.
You have misunderstood Walt’s example. He doesn’t ask for a prediction of successive flips. He only asks for a prediction of the aggregate of the number of heads:
You are given the opportunity to bet on 10000 coin flips. If heads comes up between 4000 and 6000 times, you win a million dollars. If heads comes up less than 4000 or more than 6000 times, you die. Again, you are assured that the coin is completely fair and unbiased. Would you take this bet? I think I would.
The sequence of outcomes could easily be { … H,T,T,T,H,T,H,H… }. At the end, we count up the total number of heads to see if we have correctly predicted the number of heads.
But when Walt gave himself a range of 4000 to 6000, he turned this into a near certainty that he could correctly predict the outcome. And that means he either doesn’t understand the point, or he was trying to mislead. I’d prefer to go with the former.
When folks on the street hear these arguments from a figure of authority, there is a danger that a bad idea will be accepted as correct.
MMGW proponents use this type of argument to claim that long-term climate averages are more predictable than weather. But they fail to make a like-for-like comparison: the statistics of a prediction of an average must be “more tightly consrtained” than a preduction of an individual event.
If we correctly formulate the measure of the utility of different types of prediction, we will see that a prediction of an average will be no better than the prediction of an individual event.
It is only fair to point this out to Walt to ensure he is in a better position to challenge his own assumptions.
I may have missed it having been stated already in all the comments, but would like to add:
Any warming effect from CO2 is NON-linear.
The bent-stick proponents missed this, assuming a doubling of CO2 (nominally 200 to 400 ppm) produced a doubling of effect, whereas it’s more likely to produce an approximately 15% to 20% increase.
I have posted the following question earlier to Walt Meier. I did not see him answering any questions here on this post. It is an omen that he is trying to steer clear of this debate. Pity. He seemed a bit apologetic about not knowing much of exactly what’s on both sides of the coins,. Anyway, here is the question again:
We know that Svante Arrhenius’ formula has long been proven wrong. If it had been right earth should have been a lot warmer. So I am asking: what is the correct formula? I am sure Walt Meier can give me this formula or ask the scientists who work with this every day, at the NSIDC?
I can,t wait for Dr Meiers response to Eschenbach.
This is epic science debate, brilliant, both of you have earned my most sincere respect and trust, openess is the solution.
Well argued Willis. If this was a tennis match you would be 6 -0 in the first set.
Reference your point about models.
When I graduated over forty years ago my physics tutor told me that I was “wasting my degree” when he heard I was going into manufacturing!
I thought differently. My tutor had spent all his life in academia whilst I had already spent over a year in highly demanding manufacturing activities tackling stubborn technical problems. The thing about manufacturing is that it as real as you get. If it does not work it does not work, and no one is interested in a theory that does not improve performance. The other thing about manufacturing is that harbours all the errors inherent in the models used by the process designers. If the models were correct the plant would be capable of making zero defect product 100% of the time. In practice it takes decades to achieve this and in my experience the single biggest cause of this excessively long development period is the refusal of process scientists to believe that their concept of what is happening is wrong. This is not to say that these scientists are stupid. The vast majority of their models are accurate. The problem is that they are never completly accurate. Yet every time I came up with conflicting data they would argue that I had made some sort of mistake in my analysis or the operator had not documented things properly or had not carried out the process as instructed. Do ad hominem attacks ring a bell?
My first job after graduating was very exciting. Having been blamed for everything that was going wrong the manufacturing personnel gave me tremendous support as I “took on” the development department. I eventually set up my own scientific experiments and although it took 5 years ( by which time I was running the department) I eventually proved that one of the fundamental assumptions used in the process design ( for which a nobel prize had been awarded!) was actually wrong. There were many other errors found by others the most common being that we were not measuring what we thought we were measuring. As Feynman once said of the new “sciences” like economics “I know how much effort it takes to really know something. These guys just haven’t done their homework”.
Climate scientists seem to fall into this category. For the most part they are a disparate group of data gatherers and modelers. Unfortunately hardly any of them seem to be doing fundamental science which measures the real world in a way that tests the theories that abound. Those that are are to be applauded but it hard to discover who they are and what they are saying since so much is spun by the media and vested interests. If I found it hard to fight the scientests when it was theoretically their job to help me what chance have we when the ir main interest of the average climate scientis is maintaining their funding.
Willis Eschenbach (02:18:26) :
‘You say that the trend line is somehow easier to forecast than the individual years temperatures. What this claim neglects is that the models don’t forecast the trend line. The models forecast the temperature of the the individual years (actually, the individual hours). Once the hourly temperatures are forecast, then and only then can the trend line be calculated. If the hourly temperatures are wrong, so are the yearly temperatures, and so is the trend line … so we can place no more confidence in a projected trend line than we can in the individual hourly or yearly temperatures.’
My apologies if this is a very naive question, I come somewhat late (and probably very uninformed) to this fascinating discussion – but is it not possible to envision a model who’s hourly predictions are sensitive to initial conditions and model parameters, which would make it’s prediction for any given hour quite poor, but on repeated running of the model with variations in initial conditions and/or model parameters a similar trend could be observed through the data – allowing more confidence to be placed in the trend than in the individual hourly or yearly temperatures? I have no idea if this is the case as I am not familiar with the models in question, but is it not possible that there at least a class of models for which this could be true?
Why does everyone so easily subscribe to the view that fossil fuel carbon differs chemically from “natural” carbon? It differs from inorganic carbon but not from organic carbon. The ratio of 13C to 12C – i.e. d13C – in the atmosphere has been used to try to characterise the origins of the changing CO2 concentration – to identify the sources and sinks. Plant photosynthetic biochemistry is remarkably specific preferring to fix 12C over 13C by a large margin. Thus during photosynthesis d13C rises due to the preferential abstraction of 12C. Respiration – being derived from very low 13C plant material preferentially adds 12C to the atmosphere and d13C falls. Fossil fuels are derived from carbon of photosynthetic origin and have similarly low 13C content. The rise and fall in d13C observed at the many monitoring stations such as Mauna Loa matches perfectly with the annual changing balance of respiration and photosynthesis. Because both respiration and combustion oxidise photosynthetic carbon the change in d13C cannot distinguish the origin of the added CO2.
Note also that Respiration is Temperature dependent roughly doubling with a ten degree increase in temperature whereas photosynthesis is by and large not temperature dependent. This confounds attempts to correlate temperature with CO2 concentration which in any case cannot be done by simple regression as has been done recently in this discussion. This is because both are measured dependent variables. For regression to work properly one variable must be independent and known.
Well, I have to abandon my lurking posture, since authors and commentators alike seem to be off-base on the coin flipping issue. The alternative heads/tails pattern of coin flipping is not an inherent property of the coin. The observed largely random results from coin flipping are completely attributable to the manner in which a person does the flipping. A clever lady mathematician at Stanford has created a coin flipping machine that produces heads (or tails if you wish) every trial.
http://www.thebigmoney.com/articles/hey-wait-minute/2009/07/28/flipping-out?page=0,1&g=1
In my miind, this information makes the coin flipping analogy all the more fitting for climatology discussions. We have drawn conclusions as to the random performance of the coin although the source of the randomness observed randomness comes entirely from the variable behavior of the coin flipper.
At the end of the day scientists are tied to their research.
But the crux of this matter, is measurment and theory.
Theory to progress must address measurement.
I found Mier’s arguments, mathematically specious. I found his reliance on past theories unfortunate to cover theory failure spectacular.
To my mind Scientists with the best tools of humanity can provide cannot cover falsification as a more time issue. That is anti science.
The only and correct answer is, we dont know, work in progress.
Not protecting politics or business.
This herd think is dangerous when conjoined with PNS or politicisation of science.
Science is not belief.
I am not one for Kumbayahs and lets cuddle. Does it work, if not why not.
The question of trust is based in only two areas, expertise/abiltiies and truth.
Trusted people can make mistakes, but they must admit them.
I am not buying the other sides excuses in PNS or anti science.
The models have failed.
Their behavior remains the same, cover up and denial.
For a theory to work, it works all the time.
Mathematically in applied science we build error and downside assessments, we build failure into the models.
This is what the standard normal distribution is about.
But all these models have failed at 100%, in predictive capacity. You cannot spin that. They have failed at 100 per cent.
Willis, I think the whole discussion is pointless.
Why?
Because everyone knows that the most important GHG is water vapour.
Everyone knows that water wapour is created from evapouration just by the sun shining on the oceans.
Everyone knows that in a short time enough water vapour is created to offset any cap and trade result.
When enough water vapour is created an equillibrium is reached. We see it every day.
So whats the point in discussing it?
Wren (23:43:11) :
davidmhoffer (21:45:51) :
Willis Eschenbach;
I know of no one making that claim, that the present climate runs on different principles than the past climate.>>
Sure you do. There’s these dudes with tree ring studies who discarded 50 years or so of data because “they suddenly stopped tracking temperature”. They don’t know why, but even though they don’t, they are quite certain that what ever it is they don’t know is causing it now, they “know” it never happened before.
====
Who knows what that means?>>
I don’t know Wren. I only know that they have said that they don’t know. Until we know, what they don’t know, we don’t know what they don’t know means. When we do know, we can tell them. That won’t mean that they then know of course, as they can choose to not know what they have been told we now know.
Uhm…. what was the question again?
The earth’s temperature has risen approximately every 60 years since the invention of the thermometer. The periodic warming cycles are “normal” and have probably been going on forever but we only have records since 1860 or so. The rate and amount of the most recent cycle isn’t significantly different from the previous ones to cause us to believe there is a different cause or amplifying factor.
Even Dr Phil Jones of CRU fame admits this.
Question: Do you agree that according to the global temperature record used by the IPCC, the rates of global warming from 1860-1880, 1910-1940 and 1975-1998 were identical?
Dr Phil Jones: An initial point to make is that in the responses to these questions I’ve assumed that when you talk about the global temperature record, you mean the record that combines the estimates from land regions with those from the marine regions of the world. CRU produces the land component, with the Met Office Hadley Centre producing the marine component.
Temperature data for the period 1860-1880 are more uncertain, because of sparser coverage, than for later periods in the 20th Century. The 1860-1880 period is also only 21 years in length. As for the two periods 1910-40 and 1975-1998 the warming rates are not statistically significantly different (see numbers below) ”
http://wattsupwiththat.com/2010/02/14/phil-jones-momentous-qa-with-bbc-reopens-the-science-is-settled-issues/#more-16418
The first two warmings seem to be in sync with ocean cycles [PDO and ADO] ! Why should we ascribe a different cause to the third warming ?
This cyclical warming seems to be added to a long slow warming caused by recovery from the little ice age [increasing sunspot activity] so we get a ratchet effect. Each cycle starts just a little higher than the last.
http://sidc.oma.be/html/wolfaml.html
There seems to me to be no reason to ascribe a different cause to the most recent warming cycle.
Correlation is not causation, even when it’s 100%.
Example: during testing, a particular piece of hardware of ours showed totally out-of-spec performance. In the process of failure investigation, I noticed that the aircraft navigation system appeared to not be integrating velocity correctly, i.e. velocity did not integrate to position. It turned out that during each of the performance assessment tests, our system was mounted on the same aircraft, even though the assessment was performed over a period of weeks.
The natural thing to do would be to blame the aircraft, because (it turned out) it had a faulty navigation system. But because I had a good understanding of the underlying physics, I couldn’t connect the aircraft as cause to the system’s out of spec performance. Even though the correlation was 100%.
It turned out to be a complete coincidence that the aircraft’s navigation system (which had to be replaced) was bad; the problem was an unanticipated one local to that particular piece of hardware.
Point being: correlation is not enough. There has to be a causal relationship, and it’s up to the scientist to establish causality; it’s not up to the rest of the world to prove that no (or minimal) causality exists.
Geoff,
‘Wrong.
At each new flip of the coin, the coin has no memory of its history. With a perfect coin, the probability on every flip is the same, 0.5.’
…but that’s the whole point. The model of coin flips, their independence, implicitly means that as the dynamic variables that determine the outcome of a single coin flip will average out over the course of ALL the flips, we get closer and closer to this idealized model. That’s Dr. Meier’s whole point. Given the parameters of a moment, it’s hard to model the outcome of a single coin flip due to complex dynamics going on (wind, precipitation, air pressure, etc), but those parameters average out for many, many coin flips, so we can fall back on our model of independence.
It seems like many readers have misunderstood this point.
TerryS writes,
‘Actually, the more times you flip the coin the more difficult it is to predict how many times heads will come up. As an example, if you flip the coin twice and predict heads will come up once your odds of being correct are 1 in 2 whereas if you flip it 10 times the odds of correctly predicting 5 heads is 63 in 256 or slightly more than 1 in 4.’
Huh?
You have quantified the probability of picking as many heads as one wants in more than one flip. You proved my point. Steven Goddard did it for 10000 flips 100000 different times and there was a very sharp distribution around heads coming up 5000 times.
It seemed to me that Dr. Meier’s point, in the context of discussing the difference of modeling climate in the short term versus the long term, is that one can have a great deal more confidence in a model of the range of times heads comes up in 10000 flips versus confidence in a model determining whether heads comes up in a single flip. Your comment supports this idea as well, though I don’t know if that was your intent.
Willis’ assessment, however, seems to make it as though Dr. Meier is saying the opposite on my assessment. It is obviously confusing readers who think they are somehow making an argument against me when they are not.
Willis,
would you mind cleaning up the end of that section to reflect Dr. Meier’s point correctly?
Thanks again for your time and everyone for their comments.
Beth Cooper (00:37:44),
Who says cowboys aren’t elegant and courteous?
Well, courteous anyway. ☺
Maxwell,
In a nutshell,
The flip of a coin is a two event result based in a single variable, the coin.
The distribution is 50 50.
The Climate is not a coin.
The climate is a multivariable system.
Don’t talk probabilistic nonsense.
I’m just a capenter/lurker and way over my head here but I think the coin flip analogy is faulty as are most analogies. Each coin flip has exactly the same odds, Each flip adds or subtracts one unit. As the total number of flips increase the effect of each flip decreases.
For climate science I think a better analogy might be one we carpenters face all the time.
We need a level line. We can eliminate the error if we know the two points are level and string a line. If we only know one point and project a line out using a level that has some unknown error the total rise/error after a meter or two is very small. Over a great distance obviously the rise/error will become very large. (I know , an analogy and probably faulted too) .I think Willis said something similar.
Maxwell just so you can see it in your head.
Consider the Climate, 15 dice and none with an equal number of sides or equal sized sides.
The climate system is obviouusly not a coin toss, because if was on past scientific history no one would want to roll a serious ice age.
Obviously not only dont they teach logic anymore they dont even teach probablility.
The coin toss argument is not relevant, not in a discussion of multi variables.
Different variables have different weights or progessive orders of magnitude.
Re: Ian H (17:41:43)
Due to this massive legion of “creation scientists” trying to get their “dissenting view” into the classrooms, now is not a good time to revisit the peer-review process?
Really? That the best you got? Those challenges from “creation scientists” tend to wind up in court, which has shown it can ably decide to exclude such “dangerous” views from public education.
Please point us to the legal process, perhaps describe the procedure, where challenges to a peer-review process and/or judgment may be brought, where evidence may be presented and considered, and legally-binding rulings are issued that force the retraction or acceptance for publication of scientific papers. From what I’ve seen, there is a demonstrable need for such a method of redress, and I would be pleased to know it already exists.
This has been *the* most informative and instructive discussion I’ve met. May I warmly congratulate both participants. I hope I may look forward to Dr Meier’s response.
Steve Goddard says:
This is a claim that is based on a complete misunderstanding of the carbon cycle. I recommend you read, for example, Section 2.4 of the book “Global Warming: The Hard Science” by L.D. Danny Harvey. The summary is this: The atmosphere + biota + soils + ocean mixed layer components form a tightly coupled subsystem that rapidly exchange carbon between them but exchange it only slowly with the deep ocean. Hence, any new slug of carbon introduced into this subsystem rapidly partitions between the different components. To confuse exchanges between components with the introduction of new carbon from outside this subsystem is to make a very elementary error in basic understanding of the carbon cycle.
Richard S Courtney,
“2. the validity of the assumption that climate change is driven by radiative forcing.”
This is a crucial point, because so often the appeal of AGW falls on the CO2 is a GHG ==> radiative forcing ==> warming. This chain is taken as an axiomatic truth, but it should not be.
The “Faint Sun Paradox” led to a the search for a CO2 solution to prove the radiative forcing theory, but such a theory would be classed as an “ugly” theory because it depends on “fine tuning” the change in CO2 with change is solar irradience. A beautiful theory is one that appears to be inevitable – it could not have been any other way.
I believe (that unscientific word again) that the albedo theory could be the beautiful solution to the faint sun paradox. Broadly speaking, the early earth was saved from turning into a ball of ice due to a very low albedo caused by a lack of clouds. There was a recent paper that demonstrated the physical reasons why this could be correct. As the sun warmed up, cloud formation increased and increased the albedo. As one causes the other, there is an inevitability about the events and does not depend on fine tuning.
Showing close similarity to Willis’ thermostat idea, whether it turns out to be right or wrong, I would say that at least it passes the test of being a beautiful theory.
I suggest it is misleading to call CO2 in the atmosphere a greenhouse gas, as there is no evidence that it causes any significant warming. To say that it must add to “forcing” implies that we know the energy balance of CO2 with everything else, in particular the biosphere.