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,
.
We’ve got to play the game show music,
.
. 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 3.
.
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.
Agree with sunsettommy. The cooling is 0.3-0.5 deg C.
http://virakkraft.com/Temp-without-volcanoes.png
vukcevic says:
March 16, 2012 at 2:01 pm
Willis Eschenbach says:
“As you say, there is no visible indication of Krakatoa in the record, and that was a supervolcano. And if you can’t see that …
Of course there is in any reasonably accurate temperature record.
http://www.vukcevic.talktalk.net/CET-NAP.htm”
Well not really a “supervolcano”, in the Krakatoa range of power, there are volcanoes such as Vesuvius, Pinatubo, and of course Anak Krakatau (son of Krakatoa) that are still active. Tambora is another active volcano that has actually bested Krakatoa in the past, with its 1815 eruption putting out an estimated 100 cubic kilometers of debris (compared with 25 for Krakatoa). Note, none of these are in the VEI8 category though, which is the category for some of Yellowstone’s past eruptions, which is a true supervolcano. Wikipedia (sorry) lists 6 known supervolcanos:
Yellowstone,
Long Valley, and
Valles Caldera in the United States;
Lake Toba, North Sumatra, Indonesia;
Taupo Volcano, North Island, New Zealand; and
Aira Caldera, Kagoshima Prefecture, Kyūshū, Japan
Of course not all of their eruptions are in the super category though they have that ability.
And for those who claim that if we just removed the El Nino signal they could spot the volcanoes, against my better judgement I’ve done that. Here’s the quiz … one volcano? Two volcanoes?
w.
I get the impression from some of the critical comments that all volcanoes are the same–well, they’re not.
They don’t have the same chemical composition, the sequence or ferocity of eruption isn’t the same, they don’t produce the same amount or type of ejecta, and they aren’t located at the same elevation, latitude, or longitude; or are the same with respect to surrounding mountains, oceans, etc. etc. And they all tend to errupt at different times of the year.
So to think they all should impact the weather or the climate the same is completely unfounded. Please keep that in mind when trying to compare one volcanic eruption to another.
Btw, good post, Willis–my MS thesis was on volcanoes so this was very interesting.
Willis:
Love the concept of thermostat(s). I happen to believe the earth-atmosphere has multiple thermostats and that they all work to maintain a ‘preferred’ condition for temperature, water vapor, chemical composition, etc.
Do you know of a list of all the possible mechanisms, or have you ever thought to build one?
lgl says:
March 16, 2012 at 2:54 pm
You show my graph, with a green line drawn over it. Singularly uninformative. All you have shown to date is … well, you’ve shown that the line is green. And you seem to be calling the graph “temp without volcanoes”.
How on earth did you “remove” the volcanoes, when the whole debate centers on how much they affect the temperature?
w.
Paul Bahlin says:
March 16, 2012 at 3:11 pm
The mechanisms that I know of are as follows:
1. The daily time of formation and amount of cumulus clouds in response to local temperature.
2. The daily time of formation and amount of tropical thunderstorms in response to local temperature.
3. The warming/cooling effect of clouds, which warm in winter and cool in the summer.
4. The frequency and length of the nino/nina alterations.
I’m sure there are more out there, but those are some of the major ones.
w.
Willis
Thought it was obvious, the green line is ENSO.
Willis Eschenbach says:
But heck, I’ll play your game.
Willis I’ve done 1750 to 1850 about a year ago (as a favour for one of the regulars), eventually will go back and do the rest:
http://www.vukcevic.talktalk.net/CET-D.htm
Willis,
Spot the Volcano now:
http://www.esrl.noaa.gov/gmd/webdata/grad/mloapt/mlo_transmission.gif
Mouna Loa is close to and downwind of Pinatubo and El Chichon.
I would assume that a volcanoes impact on albedo (and temperature)would be based on: Amount of ash, height of the blast, quality of the ash (house dust fine to gritty sand…I was a St. Helen’s down winder and can attest that all ash is not created equal) and the location of the volcano. I would guess that volcanoes closer to the equator have more of an impact than those near the poles. I remember the satellite pics of the St. Helen’s Ash circling the earth….right at 45 degrees North, right where it started.
Having said all that, the impact of these volcanoes was very short lived. In the chart above, solar radiation measurements returned to near normal in 12 months and were completely normalized in less than 24 months.
This would agree with the historical example of Tambora and “the year without a summer”. There was an impact on temperature, but short lived. …it wasn’t “ the decade without a summer”.
Tim Ball says on March 16, 2012 at 11:41 am: “Once again ——Etc, etc.
Tim, you are the only ace left in the stack. – Who needs” Skeptics” who think CO2 is capable of warming the Earth?
Either the “Warming by CO2 Theory” is right. – Or it is wrong. —— I say it is wrong, – but it is not up to me to prove it to be wrong. — I make no claims. Those who do, — should prove their assertions.
Someone mentioned above about snow cover, saying that temperature records aren’t all we have. Here’s the Rutgers snow extent records for the Northern Hemisphere …
The winter after El Chichon erupted, there was more snow. The winter after Pinatubo erupted, there was less snow …
But in no case are the excursions unusual …
w.
Anything is possible says:
It is not the immediate effect (strong warming) that intrigues me so much as what happens afterwards. When the aerosols (presumably) clear out, lower stratospheric temperatures fall dramatically to a level lower than they were before the eruption and, so far at least, there is no clear sign of any sort of recovery.
What’s up with that? Anyone?
One of my favorite topics, but you beat me to it this time 🙂
The reason for the steps is probably stratospheric water vapor injected by the two volcanoes. And when stratospheric water vapor increases, stratospheric temperatures drop, and that makes tropospheric temperatures rise!
“An increase in stratospheric water vapor in the 1990s likely had the opposite effect of increasing the rate of warming observed during that time by about 30 percent, the authors found.”
(http://www.noaanews.noaa.gov/stories2010/20100128_watervapor.html )
I think the conclusion from climate scientists so far has been that this warming is not enough to cancel out the initial cooling from the volcanoes. But what if these calculations are wrong? What if the two volcanoes actually were responsible for quite a bit of the 1980-2000 warming…?
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.
It has been shown that as well the 6.3 heat peaks per year and the 6.3 global sea level oscillation peaks are time coherent in phase with solar tide functions of the heliocentric Mercury/Earth frequency:
http://www.volker-doormann.org/images/sea_level_vs_solar_tide.gif
http://www.volker-doormann.org/images/sea_level_vs_solar_tides_e1.gif
http://www.volker-doormann.org/Sea_level_vs_solar_tides1.htm
This means that whatever the oven is that heats the earth, there is no time delay in the temperature answer of the globe; the temperature follows immediately the heat source power function – obvious from the Sun.
http://www.volker-doormann.org/images/sea_level_vs_solar_tides_d1.gif
Climate code is solved.
V.
Arctic ‘speckled’ snowfall (future ice) melt is main casualty of the volcanic ash
http://www.vukcevic.talktalk.net/EAA.htm
Larry Ledwick (hotrod) says:
March 16, 2012 at 9:10 am
The graph below shows as well as anything the value of what you call “apocryphal evidence” … here is the Denver snowfall record.
Snowfall went down the winter after the Krakatoa and Novarupta eruptions, and went up following El Chichon and Pinatubo. None of these were in any way unusual or anomalous. So I’m gonna say the plural of anecdote is not evidence …
w.
So to think they all should impact the weather or the climate the same is completely unfounded. Please keep that in mind when trying to compare one volcanic eruption to another.
So, the perfect epicycle, then? Need to explain a drop – it was the right sort of volcano. Need to explain no drop – it was the wrong sort!
Either a volcano puts large amounts of ash and/or sulphate into the upper atmosphere, or it does not. If the results of large explosions cannot be predicted beforehand, then we can assume the ash and sulphate is not working as predicted.
If the effects are so small that they cannot be determined very well thanks to other fluctuations, then why to the climate models need a large factor to account for them? (No need to answer, because we know it is to help explain why CO2 is not working as fast as predicted/projected.)
lgl says:
March 16, 2012 at 3:34 pm
Why on earth would that be “obvious”? And what are you using for what you blithely call ENSO? ENSO is the phenomenon itself, and there are many ways to measure it.
Does the green line show the Nino 3 index? The MEI (multivariate enso index)? The BEST (Bivariate EnSo Time series) index? The Nino 3.4 index? The SOI (southern ocean index)?
If you thought it was “obvious” … think again. We can’t read your mind.
w.
Nic Lewis – L&G 1998’s model really is too simplistic. To quote from Wigley et al 2005, “Effect of climate sensitivity on the response to volcanic forcing”, (http://media.cigionline.org/geoeng/2004%20-%20Wigley%20-%20Effect%20of%20climate%20sensitivity%20on%20the%20response%20to%20volcanic%20forcing.pdf):
“Our results differ significantly from those of Lindzen
and Giannitsis [1998]. These authors conclude that the
observations favor a low value for the climate sensitivity
on the basis of the long-timescale response to eruptions.
The main reason for this difference is because the longtimescale
response that we obtain, using physically more
comprehensive and realistic models, is substantially less
than that obtained by Lindzen and Giannitsis.” (emphasis added)
I (IMO) tend to agree. Wigley et al conclude that:
“Comparisons of observed and modeled coolings after the eruptions of Agung, El Chicho´n,
and Pinatubo give implied climate sensitivities that are consistent with the
Intergovernmental Panel on Climate Change (IPCC) range of 1.5–4.5 C. The cooling
associated with Pinatubo appears to require a sensitivity above the IPCC lower bound of
1.5 C, and none of the observed eruption responses rules out a sensitivity above 4.5 C.”
vukcevic says:
March 16, 2012 at 2:01 pm
I think you are missing the point. You can stick a volcano icon under any low period in the temperature record. It doesn’t mean the low was caused by volcanic aerosols. Also, what about the equal amplitude other lows with no associated anomalies.
Vukcevic – you would never have made it in mineral exploration with that analysis.
Willis: I haven’t had a chance to read through the comments, so I’m not sure if anyone else has presented the following. I will agree that global surface temperature is not forcing dependent. And I will also note that variations in downward shortwave radiation associated with volcanic aerosols are significantly different than downward longwave radiation associated with greenhouse gases. But…
It’s very easy to show the impact of volcanic aerosols on a global surface temperature dataset, specifically Mount Pinatubo on a satellite-based sea surface temperature dataset, HADISST or Reynolds OI.v2. I do it in lots of posts and comments. All one needs to do is invert the Aerosol Optical Depth data, include scaled (0.08) NINO3.4 SST anomalies as an ENSO reference, and smooth all of the data with a 13-month running-average filter. I’ve used the same period that you used in your first couple of graphs.
http://i43.tinypic.com/14npnd1.jpg
Or if you want to use the monthly change data as you had in your first couple of graphs, include the same volcano and ENSO references, determine the monthly change in all of the datasets, and then smooth all of the results with a 13-month filter again to reduce the seasonal components and weather noise.
http://i42.tinypic.com/jrzfxg.jpg
dana 1981:
‘Wigley et al. (2005):
“Comparisons of observed and modeled coolings after the eruptions of Agung, El Chichón, and Pinatubo give implied climate sensitivities that are consistent with the Intergovernmental Panel on Climate Change (IPCC) range of 1.5–4.5°C. The cooling associated with Pinatubo appears to require a sensitivity above the IPCC lower bound of 1.5°C, and none of the observed eruption responses rules out a sensitivity above 4.5°C. ….I’ll take peer-reviewed research over the eyeball method, personally.’
This is an example of the kind of nonsense that “peer reviewed” (actually buddy reviewed) climate science has become. Somehow these guys think El Chichon caused cooling when the record shows that it was followed by warming. As to the IPCC climate sensitivity they peddle, it is exactly zero. How do I know this, you might ask. I know this thanks to Ferenc Miskolczi’s work. Using NOAA database of weather balloon observations that goes back to 1948 he was able to show that the infrared transmittance of the atmosphere remained constant for 61 years. During that same time the amount of carbon dioxide in air increased by 21.6 percent. This means that the addition of this amount of carbon dioxide to air had no effect whatsoever on the absorption of IR by the atmosphere. And no absorption means no greenhouse effect, case closed. Carbon dioxide simply does not warm the atmosphere, even if you double it, hence the sensitivity is zero.
Sorry Sir, but I have a problem understanding your parlance, which sounds as clear as Pentagon-speak : what is that “transmittance” about?
Actually, we might not need volcanism to kick us over the edge if solar magnetics has the impact Svensmark thinks it has. The only question would be how long it lasts. On one hand we know that whatever happened during the LIA wasn’t enough to kick it in the opposite state but we also see that each cold period seems to be getting colder than the previous one. If we DO have severe cold period and it is colder than the LIA was, the jig might be up. It might not even require it to be as severely cold if it lasts longer. If the ocean cools enough, that might be all that is required. Combine weak solar magnetics with a volcanic eruption, and all bets are off, even with elevated CO2.
Willis
Because sunsettommy said “The strong 1982 El-Nino that can blunt the effect of a large volcanic eruption” and I said I agreed.
The green line is the Nino 3.4 temperature.