Guest Post by Willis Eschenbach
The claim is often made that volcanoes support the theory that forcing rules temperature. The aerosols from the eruptions are injected into the stratosphere. This reflects additional sunlight, and cuts the amount of sunshine that strikes the surface. As a result of this reduction in forcing, the biggest volcanic eruptions are said to depress global temperatures, sometimes for years.
The idea that large volcanoes significantly cool the planet is widely accepted. This effect is built into the climate models, for example. It is a reflection of the dominant climate paradigm, which is that surface temperature is a linear function of forcing. Since it can be measured observationally that the volcanoes greatly reduce the global solar forcing, it follows that they must significantly affect the global temperature.
However, I hold that the climate system is not an inert slave of changes in forcing. I hold that the climate system immediately and actively responds to changes in forcing by adjusting things like albedo, cloud type, cloud formation times and locations, timing of Nino/Nina alterations, and the like, to quickly counteract any forcing changes.
Which means, of course, that according to my hypothesis, even very large volcanoes should a have very small effect on the global temperature. To see which hypothesis is true, mine or the standard AGW hypothesis, I devised a little game I call “Spot the Volcanoes”. Two of the largest volcanoes of the century occurred within a twenty year time span. See if you can tell where they occurred.
Figure 1. First difference (month-to-month change) in global surface air temperature. Timespan shown is twenty years. Two of the largest volcanoes of the 20th century are shown in this record. The volcano in the picture is Mt. Redoubt, Alaska, one of my favorite mountains.
In Figure 1, to make things a bit difficult, I show the month-by-month CHANGE in temperature. This is not the temperature itself, but the month-by-month change in temperature, called “delta T” (∆T). If the temperature is a function of the forcing, the eruptions should be making the temperatures drop for a while. So the game is, where in Figure 1 are the two eruptions? Make your choice before you take the jump …
The answer is shown in Figure 2 below. It contains the record of the atmospheric transmission over Mauna Loa. The two eruptions, of El Chichon and Mt. Pinatubo, are very apparent in the Mauna Loa (MLO) record. I have scaled the Mauna Loa record to the corresponding GISS estimate for the forcing from Pinatubo (in W/m2), in order to show the generally accepted size of the volcanic forcing.
Figure 2. As in Figure 1, plus Mauna Loa atmospheric transmittance observations. These observations are of the total amount of clear-sky sunlight making it through the atmosphere.
Now, I can already hear folks grumbling, that this was not a fair game, that it was rigged because it was the first differences and not the actual temperature itself. And besides, most people don’t spend much time looking at first differences, so it was too hard. And perhaps those folks are 100% correct.
So let’s play a bonus round of “Spot the Volcanoes”, this time using the real temperature data. Figure 3 shows a stretch of the HadCRUT3 global surface air temperature record. This time it includes one smaller and two larger volcanoes. See if you can spot where the big ones erupted:
Figure 3. A stretch of the HadCRUT3 temperature record containing one small and two large eruptions. Don’t bother trying to find the small one.
So once again, the game is to spot two volcanoes.
Now at this time,
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We’ve got to play the game show music,
.
. dee
. dee
. da dee dee dum
.
So as to hide the answer,
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Until you make your choice, of the exact location of the two eruptions in Figure 3.
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So here it is.
Figure 4. As in Figure 2, showing the eruptions of El Chichon (1982) and Pinatubo (1993). The small eruption is Mt. Agung (1963).
I’m sure you understand my point. There is nothing to see. The kinds of temperature excursions we see after the volcanoes are not different from the temperature excursions before the volcanoes.
How big an effect should we have seen, given the IPCC assumptions about climate sensitivity? Well, the average change in forcing over the three years following the Pinatubo eruption is ~ -1.7 W/m2. Now, that’s about half the forcing change expected from a doubling of CO2, maintained for three entire years … and where’s the response? Using the IPCC numbers, we should have seen a temperature drop of 1.4°C at equilibrium, and three years after the step change we should have seen at least a full degree of that …
Instead of a full degree of cooling after Pinatubo, or even half a degree, we see maybe a tenth of a degree of cooling.
But wait, as they say on TV … it’s even worse than that. The drop after Pinatubo may be just by chance, because after the earlier El Chichon eruption we see maybe a tenth of a degree of warming … and the average three year change in forcing for El Chichon is only trivially smaller than Pinatubo, at ~ -1.6 W/m.
So this is a great natural experiment regarding changes in forcing. From these observations, as near as we can tell, half the forcing change expected from a doubling of CO2 was applied for three full years, at two different times, and it resulted in … well, pretty much nothing.
So I’d say that the volcanic eruption data strongly supports my thermostat hypothesis, which says that changes in forcing are almost immediately and nearly completely offset by opposing changes in other aspects of the climate system.
w.
PS—Here’s the double bonus question … the UAH lower temperature record:
Figure 5. UAH MSU satellite based global lower tropospheric temperature record.
This time the game is a bit different. Are there one or two volcanoes in the record, and where is it / are they?.
Now at this time,
.
We’ve got to play the game show music like last time,
.
. dee
. dee
. da dee dee dum
.
So as to hide the answer,
.
Until you make your choice, of the exact location of the two eruptions in Figure 5.
.
So here it is.
Figure 6. As Figure 5 plus transmittance information.
Note that as with the surface temperature record, the globe cooled slightly after Pinatubo … and that as with the surface temperature record, the globe warmed slightly after El Chichon. And since the post-Pinatubo drop is indistinguishable from the post-1983 and the post-1988 drops, there is no reason to assume that the post-1991 drop is due solely to Pinatubo.
Which in my opinion is why all of the analyses focus on Pinatubo, while poor El Chichon is roundly ignored because it didn’t get the memo about causing a temperature drop.
PS—Does this mean volcanoes have no effect on the climate? No, it just means that because of the immediate and basically “equal but opposite” response of the climate system to forcing changes, the effect is much more local, much shorter lived, and much smaller than would be expected if the IPCC estimates of climate sensitivity were correct.
FURTHER READING: Climate forcing by the volcanic eruption of Mount Pinatubo
[UPDATE] People have asked for more information about how the climate responds to counteract the cooling action of the volcano. Figure 7 shows the response of the albedo to the Pinatubo eruption. The albedo immediately began to drop, allowing more and more sunlight to warm the surface.
Figure 7. Anomaly in post-albedo solar isolation for the period 1984-1998. The transmittance change due to the volcano is shown in red. Albedo data from Hatzianastassiou et al.
You can see that it’s not too hard to spot the volcano in this graph … which is exactly the reason why it’s so hard to spot in the other graphs.
w.
Tim Ball says:
March 19, 2012 at 11:33 am
Dr. Tim, I respect your work, but this time I’m going to have to respectfully disagree. You say:
I don’t see any “1°C drop” anywhere, either globally (see e.g. Figure 3) or in Canada.
To see why I don’t find anything in the Canadian temperatures, let me invite you to play “Spot the Volcanoes Canadian Edition”.
The data above is the CRUTEM surface temperature data from KNMI for the Canadian growing region. To make it easier for everyone, it is the data with the monthly averages removed so that the volcanic effects can be seen.
There are two major volcanoes shown in the data, El Chichon and Pinatubo … so spot the volcanoes!
My best to you, and thanks for your good work,
w.
Dr. Tim, reading back over your cited papers I note that your claim only involves the summer:
So here’s just the summers …
The question in this game of “Spot the Volcanoes” is … which drop is Pinatubo—red, green, or blue?
w.
Using TLT Anomalies and a 13-month filter, it’s easy to spot the volcanoes.
http://i42.tinypic.com/2sh3l.jpg
The rise and fall in TLT anomalies in response to the 1982/83 El Niño should have been comparable to the response to the 1997/98 El Niño. But what did the TLT anomalies do? They dropped, then rose a reduced amount.
Bob Tisdale says:
March 19, 2012 at 4:01 pm
Thanks, Bob. Yes, if you look at the atmospheric temperature (which swings more easily than surface temperature) using a 13 month filter plus a comparison to El Nino, you might be able to spot the volcano … which is my point.
If you have to comb through the atmosphere with a 13-month filter and the El Nino to spot the volcano, the surface signal you’re looking for must be pretty small …
w.
For those who’d like to see the huge effects of the volcanoes on Canada, here’s the answer to the first of the two “Spot the Volcanoes Canadian Edition”.
You can see the huge effect that the two volcanoes had on Canada … not. In fact, after Pinatubo temperatures spiked up and then down … WUWT?
w.
My problem with this post is I can’t get past the first figure.
First, there is no reference to the data used for the first differencing of the global surface air temperature in figure 1.
Is the global surface air temperature time series the actual temperate data or merely the residues – or the so-called temperature “anomaly”?
Second, first differencing is a mathematical transform which hopefully produces a stationary signal.
What does the first differencing in figure 1 tell you about the original time series – is the global surface air temperature time series stationary?
Why would anyone use the first difference of the temperature to match a temperature when they have the temperature data?
Differencing AMPLIFIES the noise in the signal (reduces it’s precision.)
It appears the junk science “forcing from Pinatubo (in W/m2)” you chose from Hansen’s RadF.dat file was the “StratAer” forcing – since Hansen’s net forcing has a trend.
agileaspect says:
March 20, 2012 at 2:10 am
HadCRUT3.
Temperature anomaly.
If you don’t like Figure 1, move on to the next figure. It’s a game, to see if you can spot the volcano. You don’t want to play? Fine, but if you don’t want to play, don’t complain about the game.
Yes, that is the forcing in question.
w.
Willis
My evidence makes me right. The largest volcanoes in the modern era have had only a trivial effect on the temperature.
You have no evidence. You are putting on the darkest glasses you can find, looking for something, can’t find it and conclude it isn’t there.
You can’t use the raw dT in this exercise. The ENSO is much higher frequency than the volcanoes and equally strong on the interannual scale, so all you see is noise. You have to filter those high frequencies, and then you get something like this: http://virakkraft.com/moon-volcano-temp.png, and flipped: http://virakkraft.com/Volcano-temp-deriv.png, clearly a huge impact on temperature.
This impact is also very visible in sea level change rate, http://virakkraft.com/sealevel-VEI-4.jpg
so time to admit you are very wrong on this.
Now that we’ve seen the answer to the first Spot the Volcanoes Canadian Edition, let me post up the second one again and discuss it for a moment:
As you recall, the question is which one is Pinatubo—red, green, or blue.
But the point of the exercise should be quite clear. Any one of the three could be the change after Pinatubo, but whichever one it is, the other two are just normal random fluctuations. As it turns out, the answer to the question is that the drop after Pinatubo is indicated by the blue arrow. But there’s nothing to distinguish it from the others.
Now perhaps the drop indicated by the blue arrow is caused to Pinatubo. But with three drops like that in a decade or so, there is certainly a good chance that the post-Pinatubo drop is merely a fortuitous happenstance.
So there you have it … of the three temperature drops, Pinatubo is the blue one, and you can’t tell that drop from the two natural fluctuations.
w.
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Hang on … did I say the drop after Pinatubo was marked by the blue arrow? I meant to say the green arrow.
Note that the eruption of El Chichon had no effect at all. Note also that no matter when a volcano erupted during that time period, it has a good chance of looking like it caused a drop in temperature.
lgl says:
March 20, 2012 at 8:47 am
lgl, it sounds like you’re upset because you couldn’t spot the volcano even after I removed the ENSO effects … in any case, in your first chart above, you have Pinatubo lined up with a big temperature drop. The only problem is … the temperature drop starts happening before Pinatubo explodes. I note also that according to your graph, Krakatoa, the largest explosion in a while, caused a significant temperature rise … and I’m sure you can explain that all away somehow, using Jupiter instead of the moon or something.
But even ignoring those huge holes in your argument, you make my point very well. If you have to take out the moon’s orbit and remove the ENSO and filter the high frequencies and the like, obviously the signal you’re trying to find must be small.
But the claim is that the signal is very large. The claim is that volcanos in the late 20th century are what has kept the globe from overheating due to CO2. Here’s a typical claim, one of many:
Now, 0.3K is HALF THE 20TH CENTURY WARMING … and for volcanoes to cool the planet by 0.3°C total over the century, you’d have to be able to see the effect immediately after the eruption without putting on special colored glasses and holding the record at a certain precise angle and looking at it in just the right kind of moonlight …
w.
Willis
You didn’t removed the ENSO so I only spent 1 sec. on that. How did you remove it?
The derivative always leads the signal, so no hole.
The derivative is smoothed so it should drop before the volcanoes, no hole.
The derivative still contains low frequency ENSO which will sometimes cancel or counter some of the volcano signal, no hole.
I agree “cooling trend of about 0.3 K” is absurd. Don’t know where you found it but sounds like something from skepticalscience or some other unreliable source.
lgl says:
March 20, 2012 at 2:18 pm
Thanks, lgl. It’s the AGW party line, and that’s what I’m objecting to. That particular incarnation of the claim is from the wild-eyed, unreliable Journal of Geophysical Research (JGR) … there are plenty of others in the same order of magnitude.
I note that you neglected to explain why, according to your graphs, the massive eruption of Krakatoa caused a rise in the temperature.
w.
PS—if the temperature drops before the volcanic eruptions because of the particular smoothing method used, why didn’t you use the same smoothing method on the volcano data? As it is you are comparing apples to oranges.
PPS—I removed the ENSO signal by regressing the Nino 3.4 temperature on the global temperature and removing the regression from the signal. How would you suggest I do it? In any case, I don’t agree with regressing part of the global temperature against the entire thing. That seems unjustifiable mathematically.
Willis
No, I didn’t neglect to explain. ENSO is still there and there probably were a strong Nino and Nina right before 1880.
No smoothing because I used some old stuff, but now you made me waste even more time on this, http://virakkraft.com/Volcano-temp-derivative.png
Face it, volcanoes have a huge effect.
Willis – there is no doubt that volcanic cooling is a myth. I proved it in my book that has been out for two years but no one seems to pay attention to it. You seem to be reinventing the wheel here when you suddenly discover that volcanic cooling does not influence climate. You are of course right that there was no cooling associated with El Chichon. As I showed in my book that is because by random chance it erupted exactly when a La Nina cooling had just hit bottom and an El Nino was starting to build up. In satellite temperature curves you can pinpoint that accurately. With Pinatubo it was the reverse – by chance its eruption coincided with the peak of an El Nino warming that was immediately followed by La Nina cooling. Best in 1996 called that particular La Nina of 1992/93 Pinatubo cooling and everyone copied him, including Roy Spencer on his own web site. You don’t need anything else but these two volcanoes to understand what is going on: volcanic eruptions occur at random times, and depending upon how their timing meshes with ENSO phase they may be followed by cooling or warming of various degrees, none of it their own making. You do need to understand that what makes this possible is the universal presence of these ENSO peaks and valleys in all temperature curves. That is because ENSO is a harmonic oscillation of ocean water from side to side that has existed as long as the equatorial current system has existed, which is to say about 1.85 million years.
Here’s a page on the site of current guest author Forrest Mims III, claiming:
http://www.sunandsky.org/Sun_and_Sky_Data.html
Brian H says:
April 29, 2012 at 5:38 am
Thanks, Brian. No, the “reduction in temperature” is definitely not “quite obvious” as he claims. In fact, there are four winters (1990, 1995, 1996, and 2001) and several summers in even this short record that are cooler than the winters of 1991 and 1992.
Next, the claim is made that these are extensions of data from Geronimo Creek Observatory as shown at the Forest Mims website … but when I go to that website, I do not find any such data at all from Geronimo Creek …
In fact there is no AOT data at all at the Forest Mims website, just Total Optical Thickness data from Seguin Creek, and it is different data. The data you refer to seems odd, because it frequently has a value of zero (a perfectly clear sky). The data from Seguin Creek looks more real, as it doesn’t go down to zero.
w.