Guest Post by Willis Eschenbach
[UPDATE]: I have added a discussion of the size of the model error at the end of this post.
Over at Judith Curry’s climate blog, the NASA climate scientist Dr. Andrew Lacis has been providing some comments. He was asked:
Please provide 5- 10 recent ‘proof points’ which you would draw to our attention as demonstrations that your sophisticated climate models are actually modelling the Earth’s climate accurately.
To this he replied (emphasis mine),
Of note is the paper by Hansen, J., A. Lacis, R. Ruedy, and Mki. Sato, 1992: Potential climate impact of Mount Pinatubo eruption. Geophys. Res. Lett., 19, 215-218, which is downloadable from the GISS webpage.
It contains their model’s prediction of the response to Pinatubo’s eruption, a prediction done only a few months after the eruption occurred in June of 1991:
Figure 1. Predictions by NASA GISS scientists of the effect of Mt. Pinatubo on global temperatures. Scenario “B” was Hansen’s “business as usual” scenario. “El” is the estimated effect of a volcano the size of El Chichón. “2*El” is a volcano twice the size of Chichón. The modelers assumed the volcano would be 1.7 times the size of El Chichón. Photo is of Pinatubo before the eruption.
Excellent, sez’ I, we have an actual testable prediction from the GISS model. And it should be a good one if the model is good, because they weren’t just guessing about inputs. They were using early estimates of aerosol depth that were based on post-eruption observations. But with GISS, you never know …
Here’s Lacis again talking about how the real-world outcome validated the model results. (Does anyone else find this an odd first choice when asked for evidence that climate models work? It is a 20-year-old study by Lacis. Is this his best evidence he has?) But I digress … Lacis says further about the matter:
There we make an actual global climate prediction (global cooling by about 0.5 C 12-18 months following the June 1991 Pinatubo volcanic eruption, followed by a return to the normal rate of global warming after about three years), based on climate model calculations using preliminary estimates of the volcanic aerosol optical depth. These predictions were all confirmed by subsequent measurements of global temperature changes, including the warming of the stratosphere by a couple of degrees due to the volcanic aerosol.
As always, the first step in this procedure is to digitize their data. I use a commercial digitizing software called “GraphClick” on my Mac, there are equivalent programs for the PC, it’s boring tedious hand work. I have made the digitized data available here as an Excel worksheet.
Being the untrusting fellow that I am, I graphed up the actual temperatures for that time from the GISS website. Figure 2 shows that result, along with the annual averages of their Pinatubo prediction (shown in detail below in Figure 3), at the same scale that they used.
Figure 2. Comparison of annual predictions with annual observations. Upper panel is Figure 2(b) from the GISS prediction paper, lower is my emulation from digitized data. Note that prior to 1977 the modern version of the GISS temperature data diverges from the 1992 version of the temperature data. I have used an anomaly of 1990 = 0.35 for the modern GISS data in order to agree with the old GISS version at the start of the prediction period. All other data is as in the original GISS prediction. Pinatubo prediction (blue line) is an annual average of their Figure 3 monthly results.
Again from their paper:
Figure 2 shows the effect of E1 and 2*El aerosol son simulated global mean temperature. Aerosol cooling is too small to prevent 1991 from being one of the warmest years this century, because of the small initial forcing and the thermal inertia of the climate system. However, dramatic cooling occurs by 1992, about 0.5°C in the 2*El case. The latter cooling is about 3 σ [sigma], where σ is the interannual standard deviation of observed global annual-mean temperature.This contrasts with the 1-1/2 σ coolings computed for the Agung (1963)and El Chichon (1982) volcanos
So their model predicted a large event, a “three-sigma” cooling from Pinatubo.
But despite their prediction, it didn’t turn out like that at all. Look at the red line above showing the actual temperature change. If you didn’t know there was a volcano in 1991, that part of the temperature record wouldn’t even catch your eye. Pinatubo did not cause anywhere near the maximum temperature swing predicted by the GISS model. It was not a three-sigma event, just another day in the planetary life.
The paper also gave the monthly predicted reaction to the eruption. Figure 3 shows detailed results, month by month, for their estimate and the observations.
Figure 3. GISS observational temperature dataset, along with model predictions both with and without Pinatubo eruptions. Upper panel is from GISS model paper, lower is my emulation. Scenario B does not contain Pinatubo. Scenario P1 started a bit earlier than P2, to see if the random fluctuations of the model affected the result (it didn’t). Averages are 17-month Gaussian averages. Observational (GISS) temperatures are adjusted so that the 1990 temperature average is equal to the 1990 Scenario B average (pre-eruption conditions). Photo Source
One possibility for the model prediction being so far off would be if Pinatubo didn’t turn out to be as strong as the modelers expected. Their paper was based on very early information, three months after the event, viz:
The P experiments have the same time dependence of global optical depth as the E1 and 2*El experiments, but with r 1.7 times larger than in E1 and the aerosol geographical distribution modified as described below. These changes crudely account for information on Pinatubo provided at an interagency meeting in Washington D.C. on September 11 organized by Lou Walter and Miriam Baltuck of NASA, including aerosol optical depths estimated by Larry Stowe from satellite imagery.
However, their estimates seem to have been quite accurate. The aerosols continued unabated at high levels for months. Optical depth increased by a factor of 1.7 for the first ten months after the eruption. I find this (paywall)
Dutton, E. G., and J. R. Christy, Solar radiative forcing at selected locations and evidence for global lower tropospheric cooling following the eruptions of El Chichon and Pinatubo, Geophys. Res. Lett., 19, 2313-1216, 1992.
As a result of the eruption of Mt. Pinatubo (June 1991), direct solar radiation was observed to decrease by as much as 25-30% at four remote locations widely distributed in latitude. The average total aerosol optical depth for the first 10 months after the Pinatubo eruption at those sites is 1.7 times greater than that observed following the 1982 eruption of El Chichon
and from a 1995 US Geological Service study:
The Atmospheric Impact of the 1991 Mount Pinatubo Eruption ABSTRACT
The 1991 eruption of Pinatubo produced about 5 cubic kilometers of dacitic magma and may be the second largest volcanic eruption of the century. Eruption columns reached 40 kilometers in altitude and emplaced a giant umbrella cloud in the middle to lower stratosphere that injected about 17 megatons of SO2, slightly more than twice the amount yielded by the 1982 eruption of El Chichón, Mexico. The SO2 formed sulfate aerosols that produced the largest perturbation to the stratospheric aerosol layer since the eruption of Krakatau in 1883. … The large aerosol cloud caused dramatic decreases in the amount of net radiation reaching the Earth’s surface, producing a climate forcing that was two times stronger than the aerosols of El Chichón.
So the modelers were working off of accurate information when they made their predictions. Pinatubo was just as strong as they expected, perhaps stronger.
Finally, after all of that, we come to the bottom line, the real question. What was the difference in the total effect of the volcano, both in observations and in reality? What overall difference did it make to the temperature?
Looking at Fig. 3 we can see that there is a difference in more than just maximum temperature drop between model results and data. In the model results, the temperature dropped earlier than was observed. It also dropped faster than actually occurred. Finally, the temperature stayed below normal for longer in the model than in reality.
To measure the combined effect of these differences, we use the sum of the temperature variations, from before the eruption until the temperature returned to pre-eruption levels. It gives us the total effect of the eruption, in “degree-months”. One degree-month is the result of changing the global temperature one degree for one month. It is the same as lowering the temperature half a degree for two months, and so on.
It is a measure of how much the volcano changed the temperature. It is shown in Fig. 3 as the area enclosed by the horizontal colored lines and their respective average temperature data (heavier same color lines). These lines mark the departure from and return to pre-eruption conditions. The area enclosed by each of them is measured in “degree – months” (degrees vertically times months horizontally).
The observations showed that Pinatubo caused a total decrease in the global average temperature of eight degree-months. This occurred over a period of 46 months, until temperatures returned to pre-eruption levels.
The model, however, predicted twice that, sixteen degree-months of cooling. And in the model, temperatures did not return to pre-eruption conditions for 63 months. So that’s the bottom line at the end of the story — the model predicted twice the actual total cooling, and predicted it would take fifty percent longer to recovery than actually happened … bad model, no cookies.
Now, there may be an explanation for that poor performance that I’m not seeing. If so, I invite Dr. Lacis or anyone else to point it out to me. Absent any explanation to the contrary, I would say that if this is his evidence for the accuracy of the models, it is an absolute … that it is a perfect … well, upon further reflection let me just say that I think the study and prediction is absolutely perfect evidence regarding the accuracy of the models, and I thank Dr. Lacis for bringing it to my attention.
[UPDATE] A number of the commenters have said that the Pinatubo prediction wasn’t all that wrong and that the model didn’t miss the mark by all that much. Here’s why that is not correct.
Hansen predicted what is called a “three sigma” event. He got about a two sigma event (2.07 sigma). “Sigma” is a measure of how common it is for something to occur. However, it is far from linear.
A two sigma event is pretty common. It occurs about one time in twenty. So in a dataset the size of GISSTEMP (130 years) we would expect to find somewhere around 130/20 = six or seven two sigma interannual temperature changes. These are the biggest of the inter-annual temperature swings. And in fact, there are eight two-sigma temperature swings in the GISSTEMP data.
A three sigma event, on the other hand, is much, much rarer. It is a one in a thousand event. The biggest inter-annual change in the record is 2.7 sigma. There’s not a single three sigma year in the entire dataset. Nor would we expect one in a 130 year record.
So Hansen was not just making a prediction of something usual. He was making a prediction that we would see a temperature drop never before seen, a once in a thousand year drop.
Why is this important? Remember that Lacis is advancing this result as a reason to believe in climate models.
Now, suppose someone went around saying his climate model was predicting a “thousand-year flood”, the huge kind of millennial flood never before seen in people’s lifetimes. Suppose further that people believed him, and spent lots of money building huge levees to protect their homes and cities and jacking up their houses above predicted flood levels.
And finally, suppose the flood turned out to be the usual kind, the floods that we get every 20 years or so.
After that, do you think the flood guy should go around citing that prediction as evidence that his model can be trusted?
But heck, this is climate science …
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Great article and great comments too. Thank You all. Not to belabor the point or recover old ground for the tenth time, let me just add: expectations and realizations are almost always mismatched, mostly because we humans generally fail to recognize our ignorance.
Comparing aerosols from climate impact of Mount Pinatubo eruption with the background changed over recent decades shows only about 0.02c per decade. This amount is far too small to explain the cooling between the 1940’s and 1970’s being caused by aerosols. Likely explaination is the change in ocean cycles where the PDO become negative with eventually the AMO. This period also had a decreasing number of El Ninos and increasing number of La Nina’s where during the period the AO and NAO also become more negative. This scientific evidence is the inconvenient truth that the alarmists don’t want you to know.
I have a memory of the boot being applied to this paper previously, noting the advent of an La Niña coinciding with the cooling period attributed to Pinatubo.
So, were NASA predictions based upon a “Constant Temperature” pertubation or a “Reduction in temperature” pertubation by the eruption?
Steven Mosher says:
December 29, 2010 at 9:04 am
Say what? Both you guys miss the point, you’re preaching to the choir. I’m not saying that the model is exceptionally bad. Lacis is saying it is exceptionally good, that those particular model results are prima facie evidence that we can trust the models.
You’ve got the shoe on the wrong foot. Certainly, models can be useful. But you are defending Lacis’s use of these particular model results to establish that models have predictive skill … you sure that’s the side you want to line up on?
Because this result does nothing (for the reasons you give, and others) to establish the fidelity and trustworthiness of models. That’s what Lacis is claiming, and that is what you are defending … and you’ve made a really, really poor choice of where to take a stand in defense of models. Sure, defend models all you want, I defend them myself at times … but I’d think twice about defending this particular model result.
Finally, if you think that a model that gets the answer wrong by 100% is not “bad”, you’ve never been in a business or other situation where a model needs to, you know, kinda resemble reality enough not to make errors that big …
So yes, I didn’t say how much accuracy is needed, guilty as charged.
But surely if my computer program predicted your taxes at ten thousand dollars, and when the IRS looked into it, they billed you twenty thousand dollars (plus penalties and fees), you would not be impressed with the accuracy of my tax model, or my claims that the error somehow wasn’t “bad”. Let’s get real here. Errors of 100% are bad.
Well of course they overestimated the cooling effect – they ramped up the effects of aerosols in their models to explain away 4 decades of cooling in spite of increasing CO2 levels.
Whoops! Got that arse-about, ’91 an El-Nino year?
Thanks Willis, great post. For all who label this as nitpicking, does it not seem strange to you yet that every single error shown in every analysis of climate models always goes towards exaggerating the magnitude of the effect of CO2?
To Willis at 09:25: I certainly got your point in the post. In fact your response to Stevo and Steve was too polite. The GISS model is used to supposedly prove an extraordinary claim of “catastrophic runaway” AGW, and justify a monumental power grab over the world’s energy supply and use. That’s what the UN/AlGore and Hansen demand. In the real world, failed models are discarded and failed modelers have to get another job. In AGW world, the alarmists demand that we ignore their failed models and give them the power anyway. Skeptics rightly say, no way no how. Prove it first, then we’ll think about what to do.
The modelers face a dilemma. On one hand, they need to make their models match reality, basically by getting the hindcasting right, which would also have the side-effect of getting events like Pinatubo half way right for a short time into the future.
On the other hand, they need to deliver catastrophic outcomes in the long range, and they can’t do this in a too open manner in the source code, for instance by just increasing the amount of energy in the system over time; it would be too obvious.
When i say they NEED to deliver catastrophic outcomes, i don’t mean that all modelers are dishonest crooks; but there is a natural selection amongst researchers through the grant mechanism that favors those that deliver the catastrophic predictions. This mechanism constantly purges the moderates and prefers the extremists.
So to SURVIVE, a modeler needs to deliver catastrophic predictions while at the same time hindcasting the past correctly. It is NOT important whether a given model proves to be correct after 10 years because grants are not issued according to such evaluations. So it is not important for the survival of the modeler whether what he predicts now comes to pass in 10 years; he can refine his model many times and revise his opinion without punishment.
Nothing in the selection process rewards correct models.
In my view, predicting the future, especially many decades in advance, is not science, regardless of whether it is done using tarot cards, astrological charts or “sophisticated computer models”. Such forecasts are not science because they are impossible to refute, at least not without having to wait for many decades, after which time the climate modelers will be long since retired and possibly deceased. Predicting future events in this way is not sound science, but if people believe that it is sound science, then those who would like to make the case that a future catastrophe awaits have a foolproof device for winning any argument; if you challenge their predictions they can simply say, “Prove me wrong”. And of course, you can’t!
“Because this result does nothing … to establish the fidelity and trustworthiness of models”
It certainly does do something. Only a fool would dismiss it entirely, as you seem to be doing. No model ever predicts the future to 27 decimal places, as you seem to be demanding it should.
Adam Gallon says:
December 29, 2010 at 9:26 am
Whoops! Got that arse-about, ’91 an El-Nino year?
======
ENSO events:
http://ggweather.com/enso/years.htm
—————
Craig Loehle,
I think that Hansen’s prediction for the climate effects of the 1991 Pinatubo eruption is not consistent with an assumption of someone like him having a premeditated strategy to overstate the aerosol effect in a model.
I would say that if someone like Hansen wanted to have an effective premeditated strategy in a Pinatubo effect prediction then he should have purposely and significantly underestimated the aerosol effect in his model prediction. That way one could look at the actual climate effect of Pinatubo being more than his model predictions; and then AGW supporters could say something like ‘Hey, we need to increase the AGW forcing in models because we underestimated the aerosol forcing as compared the actuals shown by the Pinatubo example.’
So, to me this means someone like Hansen really thought the aerosol forcing in their models really was going to be that large in reality and so had no premeditated strategy for the model outcome.
John
LOL, I was sitting here looking at figure 3 (trying to be objective) and was about to post that the model (as crude as it probably was) did remarkably well (about 50% eyeball accurate) and matched overall trends when I realized what it actually shows.
What the GISS temperature is showing is no change or a slight decrease in global temperature from 1990 – 1997. What just happened to the hockey stick?
@ur momisugly Stevo
Dude, if the GISS model missed the hindcast of a simple event like Mt Pinatubo by 100%, does that not give you any qualms about accepting the PREDICTIONS (ie, extrapolation) from that model about a very complex event, like what is the global temperature in 2100?
I think you can say without argument that we understand weather more so than the climate and how they each work. Yet most long range weather forcasts (5 days say) are generally 50% wrong. If we can’t predict the weather 5 days out, how can anyone assume, or presume to be able to tell us what the temperature will be in 100 years, even 10 years. I think it’s an egotistical attitue that we can actually have that kind of an effect on climate. Extrapolating that reasoning, I think we should assume an announcement anytime now that we can stop tornado’s, even hurricanes. Those are much more localized events and should be much easier to control!
Viva la-science!
Climate modeling is based on an unproven assumption. That while weather is chaotic, the long term average of a chaotic system is not. This has not been proven, Lorenz certainly didn’t agree. Trewartha and Horn (1980) (5th edition), pp. 392-95.
Show the mathematics; show that the long term average of chaos is not chaotic. Until that is done, there is no reason to believe climate is predictable. Infinity divided by N is still infinity, or it is undefined. The average of chaos is chaos, or it is undefined.
Here is what Wikipedia has to say:
“… for chaotic systems, rendering long-term prediction impossible in general. … This behavior is known as deterministic chaos, or simply chaos. … Chaotic behavior can be observed in many natural systems, such as the weather.”
http://en.wikipedia.org/wiki/Chaos_theory
This comparison has the problem of “Accepting the Premise.”
The “Global Temperature” is a sufficiently fungible number with substantial slack built into it and a limited number of feasible responses anyway. If one is discussing -hindcasting-, it is easy enough to just fail or reparametrize models that refuse to pay homage to known events.
But if you actually intend to test predictive power, you want to be doing it by the gridcell. What did the model predict for the cell that actually contains Pinatubo? One 100 klicks down stream? One on the opposite side of the earth? Compare those results with the actual measurements – and keep track of the squared error instead of just adding positive errors and negative errors together. Which happens to be what everyone is doing when they move on to evaluate the Global Temperature.
The Globe cooled 0.56 Degree Celsius in only four days
Pretty much all of 20th century global warming may have been eradicated within 4 days – the same time that Apollo 11 needed to get to the Moon, as correctly predicted by Jules Verne.
http://motls.blogspot.com/2010/12/globe-cooled-by-056-c-in-four-days.html
@stevo
100% error is hardly “27 decimal places”.
You would be much more credible if you avoided hyperbole.
AGW Progress Report.
…-
“Y2Kyoto: Would You Prefer Your Temperatures Fried Or Boiled?
Daily Bayonet;
New Zealand’s Climate Science Coalition has issued a press release detailing the end of the Kiwi-gate affair.
The outcome is that data published in 2009 by New Zealand’s National Institute of Water and Atmospheric Research (NIWA) entitled ‘Are we feeling warmer yet’ has been abandoned and replaced with real, unadjusted data that shows a picture that warmists don’t want you to see:
NIWA makes the huge admission that New Zealand has experienced hardly any warming during the last half-century. For all their talk about warming, for all their rushed invention of the “Eleven-Station Series” to prove warming, this new series shows that no warming has occurred here since about 1960. Almost all the warming took place from 1940-60, when the IPCC says that the effect of CO2 concentrations was trivial. Indeed, global temperatures were falling during that period.
Well, it’s only New Zealand, right? Well, there’s lots more chewy chart goodness here!”
http://www.smalldeadanimals.com/
@Craig Loehle says:
December 29, 2010 at 7:28 am
“While it is nice to get the sign of the effect right, as Hansen does…”
I wouldn`t bank on that. The strongest cooling around then is before the volcano erupted, a pattern that repeats itself before all big eruptions.
@roger Andrews says:
December 29, 2010 at 8:02 am
“And not all volcanic eruptions caused temperatures to decrease. One of the largest (El Chichón 1982) was in fact followed by a temperature increase.”
And many more do too. The last nail in the coffin will be showing that the cool summer of 1816 was due do to natural variation.
Stevo says:
December 29, 2010 at 9:41 am
What are you on about Stevo? And calling Willis a fool? I see a smackdown coming your way.
They are even farther off on Krakatoa.
http://img297.imageshack.us/img297/16/krakatoata5.png
Temperatures didn’t actually change much after the eruption (maybe they actually did but after all the adjustments they have done to the record, they just lost track of the need to have a little dip after the August 1883 eruption).
Furthermore, net solar radiation at ground level estimated to have declined by -5.3 watts/m2 as a result of Krakatoa yet the temperature did not hardly change at all. (And in Model E, they are using an efficacy of forcing factor which reduces the impact to 0.1C/watt/m2 – about one-third of the impact of other forcings but obviously still too high taking into account the temperature impact per forcing change – which also calls into question all the aerosols impacts as Craig Loehle noted above).
[I don’t know if this table will show up or if it will only show up for a short period of time – it is the change in net solar radiation at ground level by month from GISS Model E volcanic forcing – Pinatubo peaked at -4.1 watts/m2].
http://data.giss.nasa.gov/work/modelEt/time_series/work/tmp.25_E3SAaeoM20_1_1880_2003_1951_1980-L3AaeoM20A/LTglb.txt
Stevo and others,
Please no accolades for getting the sign right! Heck, I predict that the next major eruption will have the same sign and I did this with the common sense model we all are equipped with.