Guest Post by Willis Eschenbach [note new Update at the end, and new Figs. 4-6]
In climate science, linearity is the order of the day. The global climate models are all based around the idea that in the long run, when we calculate the global temperature everything else averages out, and we’re left with the claim that the change in temperature is equal to the climate sensitivity times the change in forcing. Mathematically, this is:
∆T = lambda ∆F
where T is global average surface temperature, F is the net top-of-atmosphere (TOA) forcing (radiation imbalance), and lambda is called the “climate sensitivity”.
In other words, the idea is that the change in temperature is a linear function of the change in TOA forcing. I doubt it greatly myself, I don’t think the world is that simple, but assuming linearity makes the calculations so simple that people can’t seem to break away from it.
Now, of course people know it’s not really linear … but when I point that out, often the claim is made that it’s close enough to linear over the range of interest that we can assume linearity with little error.
So to see if the relationships really are linear, I thought I’d use the CERES satellite data to compare the surface temperature T and the TOA forcing F. Figure 1 shows that graph:
Figure 1. Land only, forcing F (TOA radiation imbalance) versus Temperature T, on a 1° x 1° grid. Colors indicate latitude. Note that there is little land from 50S to 65S. Net TOA radiation is calculated as downwelling solar less reflected solar less upwelling longwave radiation. Click graphics to enlarge.
As you can see, far from being linear, the relationship between TOA forcing and surface temperature is all over the place. At the lowest temperatures, they are inversely correlated. In the middle there’s a clear trend … but then at the highest temperatures, they decouple from each other, and there is little correlation of any kind.
The situation is somewhat simpler over the ocean, although even there we find large variations:
Figure 2. Ocean only, net forcing F (TOA radiation imbalance) versus Temperature T, on a 1° x 1° grid. Colors indicate latitude.
While the changes are not as extreme as those on land, the relationship is still far from linear. In particular, note how the top part of the data slopes further and further to the right with increasing forcing. This is a clear indication that as the temperature rises, the climate sensitivity decreases. It takes more and more energy to gain another degree of temperature, and so at the upper right the curve levels off.
At the warmest end, there is a pretty hard limit to the surface temperature of the ocean at just over 30°C. (In passing, I note that there also appears to be a pretty hard limit on the land surface air temperature, at about the same level, around 30°C. Curiously, this land temperature is achieved at annual average TOA radiation imbalances ranging from -50 W/m2 up to 50 W/m2.)
Now, what I’ve shown above are the annual average values. In addition to those, however, we are interested in lambda, the climate sensitivity which those figures don’t show. According to the IPCC, the equilibrium climate sensitivity (ECS) is somewhere in the range of 1.5 to 4.5 °C for each doubling of CO2. Now, there are a several kinds of sensitivities, among them monthly, decadal, and equilibrium climate sensitivities.
Monthly sensitivity
Monthly climate sensitivity is what happens when the TOA forcing imbalance in a given 1°x1° gridcell goes from say plus fifty W/m2 one month (adding energy), to minus fifty W/m2 the next month (losing energy). Of course this causes a corresponding difference in the temperature of the two months. The monthly climate sensitivity is how much the temperature changes for a given change in the TOA forcing.
But the land and the oceans can’t change temperature immediately. There is a lag in the process. So monthly climate sensitivity is the smallest of the three, because the temperatures haven’t had time to change. Figure 3 shows the monthly climate sensitivities based on the CERES monthly data.
Figure 3. The monthly climate sensitivity.
As you might expect, the ocean temperatures change less from a given change in forcing than do the land temperatures. This is because of the ocean’s greater thermal mass which is in play at all timescales, along with the higher specific heat of water versus soil, as well as the greater evaporation over the ocean.
Decadal Sensitivity
Decadal sensitivity, also called transient climate response (TCR), is the response we see on the scale of decades. Of course, it is larger than the monthly sensitivity. If the system could respond instantaneously to forcing changes, the decadal sensitivity would be the same as the monthly sensitivity. But because of the lag, the monthly sensitivity is smaller. Since the larger the lag, the smaller the temperature change, we can use the amount of the lag to calculate the TCR from the monthly climate response. The lag over the land averages 0.85 months, and over the ocean it is longer at 2.0 months. For the land, the TCR averages about 1.6 times the monthly climate sensitivity. The ocean adjustment for TCR is larger, of course, since the lag is longer. Ocean TCR is averages about 2.8 times the monthly ocean climate sensitivity. See the Notes below for the calculation method.
Figure 4 shows what happens when we put the lag information together with the monthly climate sensitivity. It shows, for each gridcell, the decadal climate sensitivity, or transient climate response (TCR). It is expressed in degrees C per doubling of CO2 (which is the same as degrees per a forcing increase of 3.7 W/m2). The TCR shown in Figure 4 includes the adjustment for the lag, on a gridcell-by-gridcell basis.
Figure 4. Transient climate response (TCR). This is calculated by taking the monthly climate sensitivity for each gridcell, and multiplying it by the lag factor calculated for that gridcell. [NOTE: This Figure, and the values derived from it, are now updated from the original post. The effect of the change is to reduce the estimated transient and equilibrium sensitivity. See the Update at the end of the post for details.]
Now, there are a variety of interesting things about Figure 3. One is that once the lag is taken into account, some of the difference between the climate sensitivity of the ocean and the land disappears, and some is changed. This is particularly evident in the southern hemisphere, compare Southern Africa or Australia in Figures 3 and 4.
Also, you can see, water once again rules. Once we remove the effect of the lags, the drier areas are clearly defined, and they are the places with the greatest sensitivity to changes in TOA radiative forcing. This makes sense because there is little water to evaporate, so most of the energy goes into heating the system. Wetter tropical areas, on the other hand, respond much more like the ocean, with less sensitivity to a given change in TOA forcing.
Equilibrium Sensitivity
Equilibrium sensitivity (ECS), the longest-term kind of sensitivity, is what would theoretically happen once all of the various heat reservoirs reach their equilibrium temperature. According to the study by Otto using actual observations, for the past 50 years the ECR has stayed steady at about 130% of the TCR. The study by Forster, on the other hand, showed that the 19 climate models studied gave an ECR which ranged from 110% to 240% of the TCR, with an average of 180% … go figure.
This lets us calculate global average sensitivity. If we use the model percentages to estimate the equilibrium climate sensitivity (ECS) from the TCR, that gives an ECS of from 0.14 * 1.1 to 0.14 *2.4. This implies an equilibrium climate sensitivity in the range of 0.2°C to 0.3°C per doubling of CO2, with a most likely value (per the models) of 0.25°C per doubling. If we use the 130% estimate from the Otto study, we get a very similar result, .14 * 1.3 = 0.2°C per doubling. (NOTE: these values are reduced from the original calculations. See the Update at the end of the post for details.]
This is small enough to be lost in the noise of our particularly noisy climate system.
A final comment on linearity. Remember that we started out with the following claim, that the change in temperature is equal to the change in forcing times a constant called the “climate sensitivity”. Mathematically that is
∆T = lambda ∆F
I have long held that this is a totally inadequate representation, in part because I say that lambda itself, the climate sensitivity, is not a constant. Instead, it is a function of T. However, as usual … we cannot assume linearity in any form. Figure 5 shows a scatterplot of the TCR (the decadal climate sensitivity) versus surface temperature.
Figure 5. Transient climate response versus the average annual temperature, land only. Note that the TCR only rarely goes below zero. The greatest response is in Antarctica (dark red).
Here, we see the decoupling of the temperature and the TCR at the highest temperatures. Note also how few gridcells are warmer than 30°C. As you can see, while there is clearly a drop in the TCR (sensitivity) with increasing temperature, the relationship is far from linear. And looking at the ocean data is even more curious. Figure 6 shows the same relationship as Figure 5. Note the different scales in both the X and Y directions.
Figure 6. As in Figure 5, except for the ocean instead of the land. Note the scales differ from those of Figure 5.
Gotta love the climate system, endlessly complex. The ocean shows a totally different pattern than that of the land. First, by and large the transient climate response of the global ocean is less than a tenth of a degree C per doubling of CO2 (global mean = 0.08°C/2xCO2). And contrary to my expectations, below about 20°C, there is very little sign of any drop in the TCR with temperature as we see in the land in Figure 5. And above about 25°C there is a clear and fast dropoff, with a number of areas (including the “Pacific Warm Pool”) showing negative climate responses.
I also see in passing that the 30°C limit on the temperatures observed in the open ocean occurs at the point where the TCR=0 …
What do I conclude from all of this? Well, I’m not sure what it all means. A few things are clear. My first conclusion is that the idea that the temperature is a linear function of the forcing is not supported by the observations. The relationship is far from linear, and cannot be simply approximated.
Next, the estimates of the ECS arising from this observational study range from 0.2°C to 0.5°C per doubling of CO2. This is well below the estimate of the Intergovernmental Panel on Climate Change … but then what do you expect from government work?
Finally, the decoupling of the variables at the warm end of the spectrum of gridcells is a clear sign of the active temperature regulation system at work.
Bottom line? The climate isn’t linear, never was … and succumbing to the fatal lure of assumed linearity has set the field of climate science back by decades.
Anyhow, I’ve been looking at this stuff for too long. I’m gonna post it, my eyeballs are glazing over. My best regards to everyone,
w.
NOTES
LAG CALCULATIONS
I used the Lissajous figures of the interaction between the monthly averages of the TOA forcing and the surface temperature response to determine the lag.
Figure N1. Formula for calculating the phase angle from the Lissajous figure.
This lets me calculate the phase angle between forcing and temperature. I always work in degrees, old habit. I then calculate the multiplier, which is:
Multiplier = 1/exp(phase_angle°/360°/-.159)
The derivation of this formula is given in my post here. [NOTE: per the update at the end, I’m no longer using this formula.]
To investigate the shape of the response of the surface temperature to the TOA forcing imbalance, I use what I call “scribble plots”. I use random colors, and I draw the Lissajous figures for each gridcell along a given line of latitude. For example, here are the scribble plots for the land for every ten degrees from eighty north down to the equator.
Figure N2. Scribble plots for the northern hemisphere, TOA forcing vs surface temperature.
And here are the scribble plots from 20°N to 20°S:
Figure N3. Scribble plots for the tropics, TOA forcing vs surface temperature.
As you can see, the areas near the equator have a much smaller response to a given change in forcing than do the extratropical and polar areas.
DATA AND CODE
Land temperatures from here.
CERES datafile requisition site
CERES datafile (zip, 58 MByte)
sea temperatures from here.
R code is here … you may need eyebeach, it’s not pretty.
All data in one 156 Mb file here, in R format (saved using the R instruction “save()”)
[UPDATE] Part of the beauty of writing for the web is that my errors don’t last long. From the comments, Joe Born identifies a problem:
Joe Born says:
December 19, 2013 at 5:37 am
My last question may have been a little obscure. I guess what I’m really asking is what model you’re using to obtain your multiplier.
Joe, you always ask the best questions. Upon investigation, I see that my previous analysis of the effect of the lags was incorrect.
What I did to check my previous results was what I should have done, to drive a standard lagging incremental formula with a sinusoidal forcing:
R[t] = R[t-1] + (F[t] – F[t-1]) * (1 – timefactor) + (R[t-1] – R[t-2]) * timefactor
where t is time, F is some sinusoidal forcing, R is response, timefactor = e ^ (-1/tau), and tau is the time constant.
Then I measured the actual drop in amplitude and plotted it against the phase angle of the lag. By examination, this was found to be an extremely good fit to
Amplitude as % of original = 1 – e ^ (-.189/phi)
where phi is the phase angle of the lag, from 0 to 1. (The phase angle is the lag divided by the cycle length.)
The spreadsheet showing my calculations is here.
My thanks to Joe for the identification of the error. I’ve replaced the erroneous figures, Figure 4-6. For Figs. 5 and 6 the changes were not very visible. They were a bit more visible in Figure 4, so I’ve retained the original version of Figure 4 below.
NOTE: THE FIGURE BELOW CONTAINS AN ERROR AND IS RETAINED FOR COMPARISON VALUE ONLY!! 
NOTE: THE FIGURE ABOVE CONTAINS AN ERROR AND IS RETAINED FOR COMPARISON VALUE ONLY!!
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Thanks for another another thought-provoking view of the big picture, Willis.
I have what I hope will be a constructive suggestion. I think your graphs in this article could be more informative if you used the absolute value of latitude instead of latitude. The color differences between the polar regions seem to track each, and fewer colors would make them simpler to read. Of course this would squash out some of the information distinguishing land vs sea differences between the northern vs southern hemispheres. Or maybe you do a both charts, and the difference between them would show something about those land / sea differences?
There is also the assumption that all types of forcing can be simply converted into watts. I don’t think so. Solar shortwave directly heats the surface, which gets much hotter on sunny days of the same air temperature (go ahead, put you hand on your car in the sun vs shade in Texas). This high surface temperature both leads to more longwave radiation (which is a 4th power of temperature function) and to more evaporation. In contrast, the greenhouse effect of water vapor keeps the air warm at night (or not in a desert, leading to very cold nights). This explains (in my view) why the main effect of GHG in recent decades has been warming of nighttime minima rather than daytime maxima. The rise in station records (and divergence between station and satellite data) is mainly due to the (min+max)/2 artifice of computing a daily value.
Greg: “Joe, you seem familiar with this stuff.”
I hope I haven’t misrepresented myself. I’m no scientist, just a retired lawyer who’s (mis?)remembered isolated facts that experts told me over the years. Without going through your linked page in detail, though, I’d say it uses the same math I did above.
Thank you, John! As always, Prof. Eschenbach is ‘way ahead of the pack on that concept as well. Please see: http://wattsupwiththat.com/2009/06/14/the-thermostat-hypothesis/
Willis, fascinating work. It goes again to my belief that regionalism dominates the “global” record, that what we have rammed down our throats is (my term) Computational Reality, not Representational Reality, i.e. “facts” about the world that are derived from 100% correct mathematical methods of taking numbers apart and putting them together again, but not facts that give a correct description of what is going on in the world in which people live. Kudos.
Something sparked at your comment about temps not above 30*C:
In the spirit of Computational vs Representational Reality, I wondered about temperature distributions. Instead of a map of the world, if we were to look at frequency plots of temperature of the world as an annual stat, how would that look for the highs and lows at a planetary level?
The theory of CAGW has the hot areas getting beastly hot in the future, frying the planet, right? If we were to look at annual top 5*C level and didn’t see any top-end change or percentage of total change, we’d be inclined to believe that the “hotter” world was less cold, not more hot.
More regionalism, not globalism.
To me, the bottom line is that CO2 “climate sensitivity” is a fudge factor that has no physical relationship. Try doing your plots substituting ln(CO2) for SST(skin surface temperature). I expect atmospheric concentrations to be a lagging function of energy embalance. We know it follows temperature.
Willis
Great data graphing, discussion, and giving us new ways to examine, explore and understand what is happening.
On lags, suggest exploring lags of 90 deg (Pi/2) on the annual and Schwab solar cycles.
i.e. 3 month lag for the annual and 2.75 year lag for the ~11 year solar cycle.
You may also find it useful to explore the integral of the fluxes.
See Key evidence for the accumulative model of high solar influence on global temperature David R.B. Stockwell, August 23, 2011
It seems this ‘linearity’ stuff is just another name for extrapolation science.
Nature does not do straight lines.
Those who do must practice unnatural science, or psuedo-science as it is more usually known.
David L. Hagen says: Great data graphing, discussion, and giving us new ways to examine, explore and understand what is happening. On lags, suggest exploring lags of 90 deg (Pi/2) on the annual and Schwab solar cycles.
You cannot really look at a fixed in a system with so many different things going. Unless there is one massively over-riding variation (like the annual one).
If you think there is 90 deg lag you need to differentiate (or integrate) one of the variables. In fact you need to study both , which is what this was about:
http://climategrog.wordpress.com/?attachment_id=399
Mr. Eschenbach… I’m writing to confirm that your first graph is accurate and spot-on. It’s obvious because if you rotate it 180 degrees, it show a definite hockey stick. Thanks for bringing it to my attention. I’m using it for my next peer reviewed study on tempurature proxies.
Signed: Michael E Mann.
lgl says:
December 19, 2013 at 2:47 am
Thanks, lgl. In fact, I’m using the lag to remove the effect of the annual cycle, which reveals the longer term (decadal or TCR) values.
w.
As I see it the real issue is not linearity per se. It is something more basic; the assumption that there is a simple deterministic relationship between forcing and temperature anomalies. This is possible only if natural variability is insignificant on time scales of decades to centuries so that changes in temperature over those time scales must be direct responses to forcing. I am not convinced that this is the case.
Tim Folkerts says:
December 19, 2013 at 5:31 am
Say what? No matter what is moving the results away from linearity, the end result is that temperature is NOT linearly related to TOA forcing.
All you’ve done is identified one of the many reasons the relationship is NOT linear. So while your claim that “convection carries lots of energy from the equator to the poles” is certainly true, it doesn’t follow from that fact that we can say that the relationship is linear.
w.
Thank you again.
What is “eyebeach”?
What is the full reference to “the study by Otto”?
Can you quickly summarize how the grid-specific TCRs were estimated? were the calculated from GCMs? (not necessary if described in “the study by Otto”.)
Just out of curiosity, have you saved your many posts in .doc or .pdf formats for easy reference and downloading?
To clarify, I have started doing this myself by copying and pasting. Today’s is called TOATEMPNonlinearity20131219.doc; it’s in the Eschenbach\wuwt folder. The hot links in your post are hot links in the doc, and the figures copy nicely. I am always a little suspicious of transcribing errors. I think that “The collected climate writings of Willis Eschenbach” would make a nice addition to the Springer series” on climate, should it interest you to collect them..
When I do a drag and drop on the first graphic I get a bunch of chinese characters….???????????
Willis, my point is that the first graph is not expected to be linear. The linear behavior (if it indeed turns out to be linear) would be related to the GLOBAL CHANGE in temperature as a function of a global FORCING CHANGE. The fact that the graph is not a straight line tells us NOTHING about ∆T = lambda ∆F Your first graph shows how temperature and forcing are related as you change position, rather than how temperature and forcing are related as you change time.
If anything, you should plot the CHANGE in temperature of each grid point during the year vs the CHANGE in radiative forcing for the year. Some thing like “the grid cell at 42N, 99E averaged 2 W/m^2 more radiation than last year (∆F) and warmed up 0.7 C (∆T) since last year”. That would give you the ‘climate sensitivity’ for that point for that year (0.35 C/(W/m^2) in that case). I think THAT plot would be interesting to see (more interesting than Graph 1) — there should be a lot of scatter but also a general positive slope (ie areas with less radiation than last year should cool; areas with more radiation than the previous year should warm).
I think that is much closer to the graphs you plotted later (but it is not completely clear to me how you did the later graphs). This also seem like an easy way to get the longer-term changes. Take the temperature change for a given cell from Jan 2003 to Jan 2013. Find the radiative imbalance over that time. Divide the two. There’s the decade climate sensitivity for that cell.
Stoat has some commentary on all of this.
http://scienceblogs.com/stoat/
Stoat’s commentary here:
http://scienceblogs.com/stoat/
The work of J Eggert seems to indicate that any forcing from CO2 is also limited.
It appears to be logarithmic below about 280ppm, then FLAT above that.
http://johneggert.files.wordpress.com/2010/09/agw-an-alternate-look-part-1-details1.pdf
To use audio parlance.. its like having a compressor with a hard limiter set.
Now as the CO2 concentration is not uniform around the globe (in both time and location), there may still be areas where some increase in forcing is still possible, but as the general level of forcing increases, there are less and less places with concentration of less than 280ppm for less and less part of the day, until eventually, no more extra forcing is possible.
Thanks Willis, I’ve added your ECS estimate to a compilation of 9 others, averaging out to an ECS of ~0.45, right in line with your mean estimate of 0.4 C
http://hockeyschtick.blogspot.com/2013/12/observations-show-ipcc-exaggerates.html
Joe Born says:
December 19, 2013 at 5:37 am
Joe, you always ask the best questions. Upon investigation, I see that my analysis of the effect of the lags was incorrect.
What I did to check my previous results was what I should have done, to drive a standard lagging incremental formula with a sinusoidal forcing:
R[t] = R[t-1] + (F[t] – F[t-1]) * (1 – timefactor) + (R[t-1] – R[t-2]) * timefactor
where t is time, F is some sinusoidal forcing, R is response, timefactor = e ^ (-1/tau), and tau is the time constant.
Then I measured the actual drop in amplitude and plotted it against the phase angle of the lag. By examination, this was found to be an extremely good fit to
Amplitude as % of original = 1 – e ^ (-.189/phi)
where phi is the phase angle of the lag, from 0 to 1. (The phase angle is the lag divided by the cycle length.)
The spreadsheet showing my calculations is here.
I’ll redo the calculations shortly. It won’t make a lot of difference. The main effect will be to reduce the multiplication factor due to the lag. This in turn will reduce the estimate of the overall sensitivity, and also increase the land/ocean difference.
Thanks as always for finding my mistakes, that’s how we move forwards. I’ll redo the graphics and change the text to reflect the proper calculations.
w.
stephen wilde says:
” is atmospheric pressure on the ocean surface.”…………………………
“Of course, that brings us full circle back to atmospheric mass and gravity leaving the radiative characteristics of GHGs nowhere in comparison.”
many thumbs up, stephen !! (if we had thumbs on this forum)
Nice work, Willis. You quickly demonstrated the lack of linear response between forcing and temperature and laid bare another aspect of the ineptitude of modern climate science.
The cyclical, oscillating nature of the scribble plots reminds me of those tracing in sand by pendulums.
The scatter plots could be paintings by elephants.