Guest Post by Willis Eschenbach
Well, this has been a circuitous journey. I started out to research volcanoes. First I got distracted by the question of model sensitivity, as I described in Model Climate Sensitivity Calculated Directly From Model Results. Then I was diverted by the question of smoothing of the Otto data, as I reported on in Volcanoes: Active, Inactive, and Retroactive. It’s like Mae West said, “I started out as Snow White … but then I drifted.” The good news is that in the process, I gained the understanding needed to direct my volcano research. Read the first of the links if you haven’t, it’s a prelude to this post.
Unlike the situation with say greenhouse gases, we actually can measure how much sunlight is lost when a volcano erupts. The volcano puts reflective sulfur dioxide into the air, reducing the sunlight hitting the ground. We’ve measured that reduction from a variety of volcanoes. So we have a reasonably good idea of the actual change in forcing. We can calculate the global reduction in sunlight from the actual observations … but unfortunately, despite the huge reductions in global forcing that volcanoes cause, the global temperature has steadfastly refused to cooperate. The temperature hasn’t changed much even with the largest of modern volcanoes.
Otto et al. used the HadCRUT4 dataset in their study, the latest incarnation from the Hadley Centre and the Climate Research Unit (CRU). So I’ll use the same data to demonstrate how the volcanoes falsify the climate models.
Figure 1. Monthly HadCRUT4 global surface air temperatures. The six largest modern volcanoes are indicated by the red dots.
This post will be in four parts: theory, investigation, conclusions, and a testable prediction.
THEORY
Volcanoes are often touted as a validation of the climate models. However, in my opinion they are quite the opposite—the response of the climate to volcanoes clearly demonstrates that the models are on the wrong path. As you may know, I’m neither a skeptic nor a global warming supporter. I am a climate heretic. The current climate paradigm says that the surface air temperature is a linear function of the “forcing”, which is the change in downwelling radiant energy at the top of the atmosphere . In other words, the current belief is that the climate can be modeled as a simple system, whose outputs (global average air temperatures) are a linear function of the SUM of all the various forcings from greenhouse gas changes, volcanoes, solar changes, aerosol changes, and the like. According to the theory, you simply take the total of all of the forcings, apply the magic formula, and your model predicts the future. Their canonical equation is:
Change in Temperature (∆T) = Change in Forcing (∆F) times Climate Sensitivity
In lieu of a more colorful term, let me say that’s highly unlikely. In my experience, complex natural systems are rarely that simply coupled from input to output. I say that after an eruption, the climate system actively responds to reductions in the incoming sunlight by altering various parts of the climate system to increase the amount of heat absorbed by other means. This rapidly brings the system back into equilibrium.
The climate modelers are right that volcanic eruptions form excellent natural experiments in how the climate system responds to the reduction in incoming sunlight. The current paradigm says that after a volcano, the temperature should vary proportionally to the forcing. I say that the temperature is regulated, not by the forcing, but by a host of overlapping natural emergent temperature control mechanisms, e.g. thunderstorms, the El Nino, the Pacific Decadal Oscillation, the timing of the onset of tropical clouds, and others. Changes in these and other natural regulatory phenomena quickly oppose any unusual rise or fall in temperature, and they work together to maintain the temperature very stably regardless of the differences in forcing.
So with the volcanoes, we can actually measure the changes in temperature. That will allow us to see which claim is correct—does the temperature really follow the forcings, or are there natural governing mechanisms that quickly act to bring temperatures back to normal after disturbances?
INVESTIGATION
In order to see the effects of the volcanoes, we can “stack” them. This means aligning the records of the time around the volcano so the eruptions occur at the same time in the stack. Then you express the variations as the anomaly around the temperature of the month of the eruption. It’s easier to see than describe, so Figure 2 shows the results.
Figure 2. Stacked records of the six major volcanoes. Individual records show from three years before to five years after each eruption. The anomalies are expressed as variations around the temperature of the month of the eruption. The black heavy line shows the average of the data. Black vertical lines show the standard error of the average.
The black line is the average of the stacked records, month by month. Is there a signal there? Well, there is a temperature drop starting about six months after the eruptions, with a maximum of a tenth of a degree. However, El Chichon is clearly an outlier in this regard. Without El Chichon, the signal gets about 50% stronger.
Figure 3. As in Figure 3, omitting the record for El Chichon.
Since I’m looking for the common response, and digging to find the signal, I will leave out El Chichón as an outlier.
But note the size of the temperature response. Even leaving out El Chichon, this is so small that it is not at all clear if the effect shown is even real. I do think it is real, just small, but in either case it’s a very wimpy response.
To properly judge the response, however, we need to compare it to the expected response under various scenarios. Figure 3 shows the same records, with the addition of the results from the average models from the Forster study, the results that the models were calculated to have on average, and the results if we assume a climate sensitivity of 3.0 W/m2 per doubling of CO2. Note that in all cases I’m referring the equilibrium climate sensitivity, not the transient climate response, which is smaller. I have used the lagged linear equation developed in my study of the Forster data (first cite above) to show the theoretical picture, as well as the model results.
Figure 4. Black line shows the average of the monthly Hadcrut temperatures. Blue line shows the average of the modeled annual temperatures from the 15 climate models in the Forster paper, as discussed here. The red line shows what the models would have shown if their sensitivity were 2.4°C per doubling of CO2, the value calculated from the Forster model results. Finally, the orange line shows the theoretical results for a sensitivity of 3°C per doubling. In the case of the red and orange lines, the time constant of the Forster models (2.9 years) was used with the specified sensitivity. Tau ( τ ) is the time constant. The sensitivity is the equilibrium climate sensitivity of the model, calculated at 1.3 times the transient climate response.
The theoretical responses are the result of running the lagged linear equation on just the volcanic forcings alone. This shows what the temperature change from those volcanic forcings will be for climate models using those values for the sensitivity (lambda) and the time constant (tau).
Now here, we see some very interesting things. First we have the model results in blue, which are the average of the fifteen Forster models’ output. The models get the first year about right. But after that, in the model and theoretical output, the temperature decreases until it bottoms out between two and three years after the eruption. Back in the real world, by contrast, the average observations bottom out by about one year, and have returned to above pre-eruption values within a year and a half. This is a very important finding. Notice that the models do well for the first year regardless of sensitivity. But after that, the natural restorative mechanisms take over and rapidly return the temperature to the pre-eruption values. The models are incapable of making that quick a turn, so their modeled temperatures continue falling.
Not only do the actual temperatures return to the pre-eruption value, but they rise above it before finally returning to the that temperature. This is the expected response from a governed, lagged system. In order to keep a lagged system in balance, if the system goes below the target value for a while, it need to go above that value for a while to restore the lost energy and get the system back where it started. I’ll return to this topic later in the post. This is an essential distinction between governors and feedbacks. Notice that once disturbed, the models will never return to the starting temperature. The best they can do is approach it asymptotically. The natural system, because it is governed, swings back shortly after the eruption and shoots above the starting temperature. See my post Overshoot and Undershoot for an earlier analysis and discussion of governors and how they work, and the expected shape of the signal.
The problem is that if you want to represent the volcanoes accurately, you need a tiny time constant and an equally tiny sensitivity. As you can see, the actual temperature response was both much smaller and much quicker than the model results.
This, of course, is the dilemma that the modelers have been trying to work around for years. If they set the sensitivity of their models high enough to show the (artificially augmented) CO2 signal, the post-eruption cooling comes out way, way too big. If they cut the sensitivity way, way down to 0.8° per doubling of CO2 … then the CO2 signal is trivially small.
Now, Figure 4 doesn’t look like it shows a whole lot of difference, particularly between the model results (blue line) and the observations. After all, they come back close to the observations after five years or so.
What can’t be seen in this type of analysis is the effect that the different results have on the total system energy. As I mentioned above, getting back to the same temperature isn’t enough. You need to restore the lost energy to the system as well. Here’s an example. Some varieties of plants need a certain amount of total heat over the growing season in order to mature. If you have ten days of cool weather, your garden doesn’t recover just because the temperature is now back to what it was before. The garden is still behind in the total heat it needs, the total energy added to the garden this season is lower than it would have been otherwise.
So after ten days of extra cool weather, your garden needs ten days of warm weather to catch up. Or perhaps five days of much warmer weather. The point is that it’s not enough to return the temperature to its previous value. We also need to return the total system energy to its previous value.
To measure this variation, we use “degree-days”. A degree-day is a day which is one degree above from some reference temperature. Ten degree-days could be five days that are two degrees warmer than usual, or two days that are five degrees warmer than usual. As in the example with the garden, degree-days accumulate over time, with warmer (positive) degree days offsetting cooler (negative) degree days. For the climate, the corresponding unit is a degree-month or a degree year. To convert monthly temperature into degree-months, you simply add each months temperature difference from the reference to the previous total. The record of degree-months, in other word, is simply the cumulative sum of the temperature differences from the date of the eruption.
What does such a chart measure? It measures how far the system is out of energetic balance. Obviously, after a volcano the system loses heat. The interesting thing is what happens after that, how far out of balance the system goes, and how quickly it returns. I’ve left the individual volcanoes off of this graph, and only shown the stack averages.
Figure 5. Cumulative record of degree-months of energy loss and recovery after the eruptions. Circles show the net energy loss in degree-months four years after the eruption.
Remember that I mentioned above that in a governed system, the overshoot above the original temperature is necessary to return the system to its previous condition. This overshoot is shown in Figure 3, where after the eruptions the temperatures rise above their original values. The observations show that the earth returned to its original temperature after 18 months. The results in Figure 5 show that it took a mere 48 months to regain the lost energy entirely. Figure 5 shows that the actual system quickly returned to the original energy condition, no harm no foul.
By contrast, the models take much larger swings in energy. After four years, the imbalance in the system is still increasing.
Now folks, look at the difference between what the actual system does (black line) and what happens when we model it with the IPCC sensitivity of 3° per doubling, or even the model results … I’m sorry, but the idea that you can model volcanic eruptions using the current paradigm simply doesn’t work. In a sane world, Figure 5 should sink the models without a trace, they are so very far from the reality.
We can calculate the average monthly energy shortage in the swing away from and back to the zero line by dividing the area under the curve by the time interval. Nature doesn’t like big swings, this kind of response that minimizes the disturbance is common in nature. Here are those results, the average energy deficit the system was running over the first four years.
Figure 6. Average energy deficit over the first four years after the eruption.
In this case, the models are showing an average energy deficit that is ten times that of the observations … and remember, at four years the actual climate is back to pre-eruption conditions, but the models’ deficit is still increasing, and will do so for several more years before starting back towards the line.
CONCLUSIONS
So what can we conclude from these surprising results?
The first and most important conclusion is that the climate doesn’t work the way that the climate paradigm states— it is clearly not a linear response to forcing. If it were linear, the results would look like the models. But the models are totally unable to replicate the rapid response to the volcanic forcings, which return to pre-existing temperatures in 18 months and restore the energy balance in 48 months. The models are not even close. Even with ridiculously small time constant and sensitivity, you can’t do it. The shape of the response is wrong.
I hold that this is because the models do not contain the natural emergent temperature-controlling phenomena that act in concert to return the system to the pre-catastrophic condition as soon as possible.
The second conclusion is that the observations clearly show the governed nature of the system. The swing of temperatures after the eruptions and the quick return of both temperature and energy levels to pre-eruption conditions shows the classic damped oscillations of a governed system. None of the models were even close to being able to do what the natural system does—shake off disturbances and return to pre-existing conditions in a very short time.
Third conclusion is that the existing paradigm, that the surface air temperature is a linear function of the forcing, is untenable. The volcanoes show that quite clearly.
There’s probably more, but that will do for the present.
TESTABLE PREDICTION
Now, we know that the drops in forcing from volcanoes are real, we’ve measured them. And we know that the changes in global temperature after eruptions are way tiny, a tenth of a degree or so. I say this is a result of the action of climate phenomena that oppose the cooling.
A corollary of this hypothesis is that although the signal may not be very detectable in the global temperature itself, for that very reason it should be detectable in the action of whatever phenomena act to oppose the volcanic cooling.
So that was my prediction, that if my theory were correct, we should see a volcanic signal in some other part of the climate system involved in governing the temperature. My first thought in this regard, of course, was the El Nino/La Nina pump that moves warm Pacific water from the tropics to the poles.
The snag with that one, of course, is that the usual indicator for El Nino is the temperature of a patch of tropical Pacific ocean called the Nino3.4 area. And unfortunately, good records of those temperatures go back to about the 1950s, which doesn’t cover three of the volcanoes.
A second option, then, was the SOI index, the Southern Oscillation Index. This is a very long-term index that measures the difference in the barometric pressures of Tahiti, and Darwin, Australia. It turns out that it is a passable proxy for the El Nino, but it’s a much broader index of Pacific-wide cycles. However, it has one huge advantage. Because it is based on pressure, it is not subject to the vagaries of thermometers. A barometer doesn’t care if you are indoors or out, or if the measurement location moves 50 feet. In addition, the instrumentation is very stable and accurate, and the records have been well maintained for a long time. So unlike temperature-based indices, the 1880 data is as accurate and valid as today’s data. This is a huge advantage … but it doesn’t capture the El Ninos all that well, which is why we use the Nino3.4 Index.
Fortunately, there’s a middle ground. This is the BEST index, which stands for the Bivariate ENSO Timeseries. It uses an average of the SOI and the Nino 3.4 data. Since the SOI has excellent data from start to finish, it kind of keeps the Nino3.4 data in line. This is important because the early Nino3.4 numbers are from reanalysis models in varying degrees at various times, so the SOI minimizes that inaccuracy and drift. Not the best, but the best we’ve got, I guess.
Once again, I wanted to look at the cumulative degree-months after the eruptions. If my theory were correct, I should see an increase in the heat contained in the Pacific Ocean after the eruptions. Figure 6, almost the last figure in this long odyssey, shows those results.
Figure 6. Cumulative index-months of the BEST index. Positive values indicate warmer conditions. Krakatoa is an obvious outlier, likely because it is way back at the start of the BEST data where the reconstruction contains drifts.
Although we only find a very small signal in the global temperatures, looking where the countervailing phenomena are reacting to neutralize the volcanic cooling shows a clearer signal of the volcanic forcing … in the form of the response that keeps the temperature from changing very much. When the reduction in sunlight occurs following an eruption, the Pacific starts storing up more energy.
And how does it do that? One major way is by changing the onset time of the tropical clouds. In the morning the tropics is clear, with clouds forming just before noon. But when it is cool, the clouds don’t form until later. This allows more heat to penetrate the ocean, increasing the heat content. A shift of an hour in the onset time of the tropical clouds can mean a difference of 500 watt-hours/m2, which averages over 24 hours to be about 20 W/m2 continuous … and that’s a lot of energy.
One crazy thing is that the system is almost invisible. I mean, who’s going to notice if on average the clouds are forming up a half hour earlier? Yet that can make a change of 10 W/m2 on a 24-hour basis in the energy reaching the surface, adds up to a lot of watt-hours …
So that’s it, that’s the whole story. Let me highlight the main points.
• Volcanic eruptions cause a large, measurable drop in the amount of solar energy entering the planet.
• Under the current climate paradigm that temperature is a slave to forcing with a climate sensitivity of 3 degrees per doubling of CO2, these should cause large, lingering swings in the planet’s temperature.
• Despite the significant size of these drops in forcing, we see only a tiny resulting signal in the global temperature.
• This gives us two stark choices.
A. Either the climate sensitivity is around half a degree per doubling of CO2, and the time constant is under a year, or
B. The current paradigm of climate sensitivity is wrong and forcings don’t determine surface temperature.
Based on the actual observations, I hold for the latter.
• The form (a damped oscillation) and speed of the climate’s response to eruptive forcing shows the action of a powerful natural governing system which regulates planetary temperatures.
• This system restores both the temperature and the energy content of the system to pre-existing conditions in a remarkably short time.
Now, as I said, I started out to do this volcano research and have been diverted into two other posts. I can’t tell you the hours I’ve spent thinking about and exploring and working over this analysis, or how overjoyed I am that it’s done. I don’t have a local church door to nail this thesis to, so I’ll nail it up on WUWT typos and all and go to bed. I think it is the most compelling evidence I’ve found to date that the basic climate paradigm of temperatures slavishly following the forcings is a huge misunderstanding at the core of current climate science … but I’m biased in the matter.
As always, with best wishes,
w.
APPENDICES
UNITS
Climate sensitivity is measured in one of two units. One is the increase in temperature per watt/m2 of additional forcing.
The other is the increase in temperature from a doubling of CO2. The doubling of CO2 is said to increase the forcing by 3.7 watts. So a sensitivity of say 2°C per doubling of CO2 converts to 2/3.7 = 0.54 °C per W/m2. Using the “per doubling” units doesn’t mean that the CO2 is going to double … it’s just a unit.
DATA
Let’s see, what did I use … OK, I just collated the Otto and Forster net radiative forcings, the Forster 15 model average temperature outputs, the GISS forcing data, and the dates of the eruptions into a single small spreadsheet, under a hundred k of data, it’s here.
METHOD
The method depends on the fact that I can closely emulate the output of either individual climate models, or the average output of the unruly mobs of models called “ensembles” using a simple lagged linear equation. The equation has two adjustable parameters, the time constant “tau” and the climate sensitivity lambda. Note that this is the transient sensitivity and not the equilibrium sensitivity. As you might imagine, because the earth takes time to warm, the short-term change in temperature is smaller than the final equilibrium change. The ratio between the two is fairly stable over time, at about 1.3 or so. I’ve used 1.3 in this paper, the exact value is not critical.
Using this lagged linear equation, then, I simply put in the list of forcings over time, and out comes the temperature predictions of the models. Here’s an example of this method used on the GISS volcanic forcing data:
Lambda (a measure of sensitivity) controls the amplitude, while tau controls how much the data gets “smeared” to the right on the graph. And sad to say, you can emulate any climate model, or the average of a bunch of models, with just that … see my previous posts referenced above for details about the method.
INDIVIDUAL RECORDS
Here are the most recent six eruptions, eruptions that caused large reductions in the amount of sunlight reaching the earth, with the date of the eruptions shown in red.
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Greg Goodman says:
May 26, 2013 at 12:45 pm
Ken all the volcano columns are derived from col G , except El Chichon, which is based on col E.
Is that intentional , what’s it about?
Greg, thanks for finding that error. All volcanoe columns should reference col G. It is now fixed:
http://www.friendsofscience.org/assets/files/WillisE_Forcings_and_Models.xlsx
[They were originally referenced to col E, which was mislabeled as temperature. I had changed the reference to col G, which is the modelled temperature, but I missed the El Chichon column. Sorry about that!]
Now the graph of six volcanoes is only a little different from the graph of five volcanoes (which excludes El Chichon) in the spreadsheet. The five volcanoes modeled temperatures drop in the year after the eruptions to -0.22 C (relative to the year before the eruptions) and recovers to -0.09 C in the 4th year after the eruptions. In contrast, Willis’ Figure 4 shows the modeled temperatures drop in the year after the eruptions to -0.30 C and recovers to -0.15 C in the 4th year after the eruptions.
Ok, so we’re getting nearer, that shapes right. Now what’s going on with the number of models? Are you plotting the same thing?
@Greg Goodman: It would be interesting to do the stacking but keeping calendar months aligned.
You could do that, but I wouldn’t believe the results either way.
We just don’t have that many volcanos to work with to instill an average 3 month time-positional error. Furthermore, working with calendar months makes little difference when we have Northern and Southern Hemispheres in play and most are in the Tropics anyway.
Arranged North to South
(Indicates other eruptions that could conflate the study)
N.Temperate-Arctic
Novarupta, USA AK, 1912 Lat= +58.27 Alaska Penn. June 6, 1912 VE 6
(note:largest eruption in 20th century)
(Colima, MX. Lat=+19.15 N.Tropic Jan 20, 1913 VE 5)
N. Tropics:
El Chichon, MX Lat=+17.36 (N.Tropic) Cen Am April 3, 1982 VE 5
(Mt. St Helens, USA Lat=+46.20 (N.Hem) May 18, 1880 (pre-Chichon) , VE 5)
Pinatubo, Phil Lat=+15.13 (N.Tropic) Asia Pac June 15, 1991 VE 6
(Cerro Hudson, Chile Lat=-45.90 (S.Hem) Aug 12, 1991 VE 5 )
(also pointed out by Dr. Stefan Weiss )
Santa Maria, Guat. , 1902 Lat=+14.76 (N.Tropic) Cen. Am. Oct 27, 1902 VE 6
S. Tropics
Krakatoa, Indo. 1883 Lat=-6.10 (S.Tropic) Indo-Indean Aug 27, 1883
(Okataina, NZ Lat=-38.12 (S.Hem) June 10, 1886 VE 5)
Mt. Agung, Indo Lat= -8.34 (S.Tropic) Indo-Indean peak VE 5 on March 17, 1963, but a year long.
Tambora, Indo Lat.=-8.25 (S.Tropic) Indo-Indean April 10, 1815 VE 7
(“Year without Summer” 1916 NE USA.)
Arranged by Local Season.
El Chichon – N.Tropic, Spring (preceded by Mt. St.Helens, 23 months Spring)
Novarupta – N.Hem-Late Spring (followed by Colima, 6 months)
Pinatubo – N.Tropic, Late Spring (followed by Cerro Hudson, 2 months, S.Hem)
Mt. Agung, – S.Tropic, Late Summer (alone)
Santa Maria – N.Tropic, Autumn (alone)
Krakatoa – S.Tropic, Late Winter (followed by Okataina 35 months, S.Hem.)
Tambora – S.Tropic, Early Autumn (alone)
Grouped by Geographic Area of influence:
N.Am, N.Pac – Novarupta
Cen.Am-E.Pacific – el Chichon, Santa Maria
Asia-W.Pac: Pinatubo
Indo-Indian: Krakatoa, Mt. Agung, Tambora
Greg Goodman says:
Now what’s going on with the number of models?
Well, the caption to Fig. 4 says “Blue line shows the average of the modeled annual temperatures from the 15 climate models in the Forster paper, as discussed here.”, but I think the 15 is an error. It is 19 models. There is one and only one record of the Forster modeled temperatures. It is from the previous post
http://wattsupwiththat.com/2013/05/21/model-climate-sensitivity-calculated-directly-from-model-results/
Willis digitized the graph from the Forster paper. The link at the bottom of the post gives the data. The caption to Fig. 3 says, “The blue line shows the average hindcast temperature from 19 models in the the Forster data.” This agrees with Table 1 of the Forster paper, and the digitized data, copied into my spreadsheet, matches the graph from the Forster paper.
Again I’ve split this to see north/south tropics and extra-topical zones
http://climategrog.wordpress.com/?attachment_id=277
Temporary cooling visible in both NH and SH extra-tropics . NH ends very slightly lower ; SH equally the other way. On average, both hemispheres are cooling before the event.
NO long term cooling .
http://climategrog.wordpress.com/?attachment_id=278
one really evident feature is the warmer winter in tropical SH ; cooling min at 2y warm bump at 6y.
Don’t know that any of that would get past a test of statistical significance. Looks very much too close to usual ups and downs.
If you took out the established circa 2.5 year bumps that seem a regular feature the cooling/warming features are minimal.
NO long term cooling .
The post 6y averaged “nino-like” bump is similar to the pre-6y one.
So the main feature seems to be that eruptions are synchronised to the “internal” variations. The same thing that I remarked in Willis’ figure 2.
Oh and did I mention, NO long term cooling .
Ian H says:
May 25, 2013 at 2:18 am
The next step then is to ask what CAN cause the climate to change if it is governed as you describe. Because as we all know climate can and does change. For example what could cause the LIA or the late 20th century warming if the system is indeed governed. A governed system is likely to be quite insensitive to changes in the input energy. To get it to change you would need something that “tweaks” the settings on the governor.
I asked myself the same question a couple of years back, and concluded that climate change results from factors that affect the phase changes of water; aerosols, including organic carbon (cloud condensation, and precipitation suppression), black carbon (snow/ice albedo changes), and perhaps GCRs. Ignoring Milankovitch Cycles.
Which led me to look for evidence of century scale changes in aerosols and BC to account for the MWP and LIA. I didn’t find any, but that doesn’t mean such changes didn’t occur.
Those bumps are worrying me. I synchronise the data on volcanic events spanning a full century, take the average SST anomaly and I get a series of regular bumps of about 2.4 years duration that stretch both before and after then event.
In fact a lot of what is generally attributed to volcanic cooling is just the synchronisation to this cycle.
Another observation, the larger peaks are about 11 years apart and the eruptions are in the middle. Solar minimum ??
Willis Eschenbach:
Excellent work!
Ian H says: The next step then is to ask what CAN cause the climate to change if it is governed as you describe.
Best not to over simplify. Willis has put a good case for a governor type response to variations to insolation of the tropics. Despite the individual storms being very fast, It is not instant on the regional scale. Here we are discussing changes over six years.
There is also the question of where does the heat go when it is evacuated from the tropics. I commented on that above as well. It get shipped to upper troposphere were some escapes and Hadley circulation takes the rest to higher latitudes. Eventually probably to the polar regions.
Don’t forget higher latitudes don’t have the governor.
Also a governor will leave a small offset if the forcing is maintained. How much depends on the strength of the internal feedbacks involved. A governor may be good at controlling deviations of a degree or two and bring the system back to within a few tenths.
If we can trust the data we have and trust the trustees of the data , tropical NH has show a few tenths of warming and it seems linked to Arctic melting season.
http://climategrog.wordpress.com/?attachment_id=276
However the key point of this post is that volcanic forcing is neutralised as far as the data shows. And without that someone will have to cut the CO2 factor down to size to restore the energy budget.
<i.Don’t forget higher latitudes don’t have the governor.
I think its likely they do. I don’t see how tropical thunderstorms could rapidly respond to a high latitude eruption like Novarupta in Alaska.
In addition, I think the role of humidity in tropical thunderstorm formation, and all cloud formation, is more important, than I believe Willis does.
I also think the mechanism operates in the temperate to arctic zones, at least in summer. Decreased temperatures > decreased clouds > increased solar insolation > increased SSTs and surface temperatures > increased evaporation > increased humidity, and after some lag temperatures and clouds return to their equilibrium level.
However the key point of this post is that volcanic forcing is neutralised as far as the data shows. And without that someone will have to cut the CO2 factor down to size to restore the energy budget.
Agreed. I remarked to Willis a while back that solid empirical evidence showing the aerosol forcings (both volcanic and anthropogenic) are too high will force the modelers to bring down the CO2 forcing.
Philip Bradley says:
<i.Don’t forget higher latitudes don’t have the governor.
I think its likely they do. I don’t see how tropical thunderstorms could rapidly respond to a high latitude eruption like Novarupta in Alaska.
===
Tropical storms react quickly to tropical SST. There will be other feedbacks in different regions, probably not governors though.
Novarupta was VE6 and the max "cooling" of the temperature anomaly in the tropics was in the winter of the first year whereas most warm this period, hit min in second year. This pattern is shared by Krakatoa which was also very powerful. The recovery max was at start of third year synchronised with the other events.
One of the very strange things that comes out of this stacking, when calendar months are aligned rather than strict delay from eruption date, is the 2.4 year patter. You can only see hints of it in individual events but it becomes very clear when averaging.
http://climategrog.wordpress.com/?attachment_id=278
Could it be accidental? It's a surprisingly clear pattern.
"Agreed. I remarked to Willis a while back that solid empirical evidence showing the aerosol forcings (both volcanic and anthropogenic) are too high will force the modelers to bring down the CO2 forcing."
I have also been making the point repeatedly. Thanks to Willis for picking up the ball.
“Stephen Rasey says:
May 26, 2013 at 8:06 am
@Tenuc at 4:19 am
have a look at the ‘law’ of Maximum Entropy Production (MEP) and Spatiotemporal Chaos to get some insight into reasons why the balance gets restored.
MEP and Chaos are hardly first principles of physics. They are non-unique explainations of observed phenomina. Many chaotic systems do not show quick returns to a baseline. Indeed, the hallmark of chaotic systems is the existance of multiple local stability points. Chaos is an argument that better describes the climate models.”
Are you thinking in anomalies or absolutes?
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More general comment about this article & discussion:
It’s interesting watching people slowly clue in to what Ulric Lyons & Tomas Milanovic said long ago. An insight about human nature may be that sometimes people need to discover things firsthand for themselves in order to appreciate and that once they have done so they may not recognize (or acknowledge) equivalence with what others have said in the past. I suppose that in some sense wheel reinvention is like an insurance policy that saves civilization from losing knowledge in the longer term. But it’s also comical to see Ulric not even acknowledged — very informative about the dimension of human nature known as stubborn pride. FWIW, Ulric: I acknowledge that you were there years ago.
Thank you, Willis, once again, for a masterpiece of logic. I wonder of someone could clarify something for me: At one point the text says that, after an eruption, there should be an increase in the heat contained in the ocean. I’m not quite sure how the physics of that would work, since, presumably, the cause of the temperature drop is reduced insolation. It seems to me that, were the ocean moderating the temperature drop, one would see an increase in the heat being _released_ by the ocean, and therefore a _decrease_ in the heat contained in the ocean.
I would be grateful if someone could help me with my gap in understanding. Thanks!
PV: “FWIW, Ulric: I acknowledge that you were there years ago.”
Ulric Lyons is not a name recognise other than the occasional terse comments here and probably Talkshop. Where did he get to years ago, what have we missed?
I have reviewed my NH tropical stack to try to assess any cooling beyond the circa 2.7 y cycle:
http://climategrog.wordpress.com/?attachment_id=278
To assess the any cooling: the range before eruptions is 0 to -0.2 K , in the following period between 0 and -0.25 . This gives an average drop of 0.025 degrees in the immediate aftermath. It is not obvious whether this is part of a slow long term decline, an initial drop and recovery or a permanent offset.
PS In any case it is an order of magnitude smaller than the 0.25 to 0.3 deg C usually attributed to these events.
Regardless of the statistics, SO2 just doesn’t seem reflective when you work with it regularly under the lights, nor does H2S. H2SO4 does have that weird shimmery character as an aerosol shared with other strong acids, but really, is atmospheric concentration high enough to invoke this? Methinks we are talking of the ability to coalesce droplets or aerosol H2O.
Having found a remarkable pseudo-cyclic pattern in the monthly aligned stack: http://climategrog.wordpress.com/?attachment_id=278
it occurred to me that Willis’ degree.day idea (in fact the cumulative distribution function) would provide a means of flattening out the ripple to look for residual change. Here is the the CDF of hadCRUT4 for southern hemisphere:
http://climategrog.wordpress.com/?attachment_id=280
In all these plots I have averaged calendar months so as to keep the seasonal alignment.
Firstly this confirms my original observation that, on average, there is a general downward trend _before_ the eruptions which must be taken into account when looking for a volcanic cooling signal.
It can be seen that the tropical storm “governor” not only maintains temperature but actually compensates for the number of degree.days . An equal number of warm days make up for those lost to the eruption.
In the temperate latitudes there is a loss of cumulated “degree.day” but this does not mean a net loss of temperature (beyond the existing downward trend).
The CDF being parallel to fitted line corresponds to return to the same temperature. Since it is roughly parallel 6 years after the eruptions, this marks zero net cooling.
Both plots warm after 6 years but this ( the already reported Nino-like events) seems to be due to a curious synchronisity between the years of major events and the stronger climate pulses at about E-5 and E+6 .
The bottom line on all this is that there is not discernible global cooling as a result of major stratospheric eruptions, contrary to the established wisdom.
This false idea has been mainly caused by the lack of recognition of an underlying downward trend in temperatures that is usually already established when these events occur.
I loved the article because it built a simple picture in my mind. We live on a water planet. If anything heats the atmosphere water evaporates, clouds form and cool the earth while convection transports heat to high altitudes where it can escape into space. If anything cools the atmosphere, clouds don’t form and more sunlight gets through to heat the earth and oceans and eventually the atmosphere. That’s a super simple system to keep the earth and atmosphere temperatures within a small range. Volcanoes are a convenient experiment that cool the earth so we can see if the earth and atmosphere respond as expected. Apparently they do. Very compelling.
Unfortunately I doubt that such a simple explanation can move the interests vested in the notion that a twang to the system by humans in the form of CO2 will break the guitar string and it will whip us to death. Oh well, it convinces me. I like simple.
Nick Stokes: People might be interested in …
Thanks for the link.
At any given time, there are 500 active magma fields on land, some 650,000 active seamounts, several million smaller oceanic vents, and a 47,000 mile long Mid-oceanic ridge, which acts like the largest volcano imaginable in terms of volume of lava and gases produced.
Human actvities don’t even compare.
if that were not enough, the average for carbonate rock and carbonate-cemented rock dissolution is roughly one inch per year. They cover 10% to 15% of the crust. Assuming standard H2CO5 in rainwater chemistry, approximately 800 billion tons of CO2 are produced by this, but 12.7 trillion tons of CO2 are removed by this.