Guest Post by Willis Eschenbach
Anthony Watts has pointed to a curious new paper in his article “Climate Craziness of the Week: The AGU peddles a mammoth climate change theory” I thought I’d use it as an example of how I take a first cut at whether a theory is reasonable or not. The new paper claims that the extinctualization of the mammoths warmed the world.
The original article is reviewed on ScienceNow, and is accompanied by this image:
Figure 1. Mammoths, the animals that can blow both hot and cold.
Gotta love these folks, no matter what happens it changes the climate. I discussed in my post “Anthropogenic Decline in Natural Gas” the previous study that claimed that the loss of mammoth flatulence when the mammoths were extinctified was the cause of radical global cooling. Now the same mammoth extinctivication is claimed to have caused global warming. Here is the new claim:
Earth system scientist Chris Doughty of the Carnegie Institution for Science in Stanford, California, and colleagues decided to find out whether the change in Betula [birch tree] proliferation was connected to the disappearance of the mammoths. They started by studying Betula pollen records compiled from soil cores taken in Siberia and Beringia. Next, the team examined mammoth fossil records to establish the timeline for their disappearance from the region. They also used studies of elephant-feeding habits to estimate the impact of the loss of the mammoths on the grasslands, and they applied climate models to compute the effect of the vegetation change on global temperatures.
The results, the researchers report in a paper to be published in an upcoming issue of Geophysical Research Letters, suggest that when the mammoths disappeared, the Betula trees expanded across Beringia, forming forests that replaced as much as one-quarter of the grassland. The trees’ leaves, which are darker than grasses, absorbed more solar radiation, and their trunks and branches, which jutted above the snowpack, continued the effect even in winter. The researchers calculated that the mammoths’ disappearance contributed at least 0.1˚C to the average warming of the world around 15,000 years ago. Within Beringia, the warming due to the loss of the mammoths was probably closer to 0.2˚C, the team concluded.
To figure out if something like this makes sense, I generally do a back-of-the-envelope type of calculation. My cut on this particular one is as follows:
1. Figure out the surface area that we are talking about.
2. Figure out the change in albedo.
3. Figure out the change in forcing and thus the change in temperature.
First, the area. At the time in question, the mammoths were centered in an area called “Beringia”, which stretched from 60° to 75°N, and from 150°W to 170°E. This area comprises 0.6% of the surface area of the planet. Let’s triple that to make sure we have a conservative estimate, so we have 2% of the surface area.
Next, the change in albedo. “Albedo over the boreal forest” gives the following figures:
Representative daily average albedo values in summer are 0.2 over grass, 0.15 for aspen, and 0.083 for the conifer sites. In winter the corresponding mean albedo for snow-covered grass, aspen, and conifer sites with snow under the canopy are 0.75, 0.21, and 0.13. … . Forest albedo increases at all sites in winter (with snow on the ground under the canopy) as the ratio of diffuse to total solar flux increases.
From this we can see that the difference is small in the summer. It is theoretically larger in the winter, but in the winter there is very little heating from the sun because it is so low on the horizon. In addition, this increases the albedo of all surfaces, because of the increased reflectance due to the low angle of incidence. Finally, the low birch trees described in the source article would have greater winter albedo than the aspen, because more of the snow would show through underneath.
So lets use .2 and .8 for the summer and winter albedo for grass, and .15 and .55 for the summer and winter albedo for dwarf birch. These average out to .5 for grass and 0.35 for dwarf birch. This means birch growth increases the absorbed sunlight by about 50%. However, not all of the land surface will be changed. Let’s be real generous and say that half the land surface in the mammoth area is actually where they graze, although it is likely much less than that. There’s a lot of barren land that far north, mountains and bogs and such. So the increase in absorbed sunlight might be 25%. Then the authors (above) say that the extinguination of the mammoths would change a quarter of the grazing area. So we’re down to about a 6% change in albedo. (In fact it will be less, because the higher winter albedo affects less incoming sun, but we’ll leave it at that to make sure the figures are conservative).
Now, how much will that change the absorbed sunlight? Well, Anne Wilber et al. put the annual surface sunlight absorbed by the surface at 60°-75°N (the mammoth range) at 100 W/m2. They also give an average albedo for the area of 0.34.
But the most interesting thing about the Wilber et al. study is this: in the far northern regions, the average net short wave (the amount of sunlight absorbed by the surface) has almost nothing to do with the surface conditions. Figure 2 shows the map of the downwelling short wave (DSW, the amount of sunlight striking the surface) and the net short wave (NSW, the amount of sunlight absorbed by the surface) averaged over the year.
Figure 2. Solar flux. (a) Solar radiation striking the surface (downwelling shortwave, DSW). (b) Absorbed solar radiation (net shortwave, NSW) at the surface.
In Fig. 2(b) we see that while in the tropical regions there are clear differences between things like deserts, rainforests, and the ocean, this is not true in the far North. Up there in Mammothville, you can see very little difference between energy absorbed by the ocean and the land. In addition there is very little variation within the land itself, with the exception of the perpetual ice cover of Greenland.
This is for two reasons. First, the surface radiation in the far north is dominated by clouds, not the surface. Second, the composition of the surface makes little difference. The surface albedo is high because of the low angle of the sun, not because of the exact composition of the surface.
In any case, we can see that any changes in the surface albedo of the far north, such as the change due to mammoth extinctualations, do not affect the overall albedo very much. The Wilber et al. study puts the change in ground cover as explaining only about 2% of the absorbed sunlight. That’s the maximum that changing the surface albedo will do.
So the maximum change from mammoth extinguishment is 2% of the absorbed sunlight due to surface albedo, times 100 W/m2 insolation in the mammoth area, times 2% of the surface covered by mammoths, times a 6% increase in absorbed sunlight from the surface change due to birch growth. This gives us a change of about 0.0025 watts per square metre … which using the Stefan-Boltzmann law gives us a temperature change of .00045°. This would be increased by the greenhouse effect by about 35%. That would give us a temperature change of 0.0006° …
Now my estimate could be low by an order of magnitude (a factor of 10). Seems doubtful, because I’ve used fairly conservative numbers. But it’s certainly possible. Mammoths might have covered a larger area, my other estimates could have been low, this kind of calculation is usually only good to within an order of magnitude.
And it’s possible that it is out by two orders of magnitude. But I’d say that was very doubtful. And that’s how far wrong it would have to be to match their estimate of a .1°C change from mammoths.
My conclusion? Nothing firm, because this is a back-of-the-envelope calculation. However, the calculation says that it’s very doubtful that mammoth exstrangulation caused the planet to warm … I’d have to see a whole lot of very solid data before I’d believe that one.
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Mike D. says:
July 2, 2010 at 4:13 pm
You are correct. However, I restricted myself to the northern area, because that’s where the authors claimed that the albedo contrast between grasses (which get covered by snow) and birch trees (which don’t) is high. Everywhere else, the birch trees and the grasses would have about the same albedo, so swapping one for the other wouldn’t make much difference in absorbed sunlight.
Also, Beringia (unlike much of the NH extratropics) was relatively ice free during the last glacial.
Excerpted from another source:
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The Beresovka mammoth was found in a sitting position, although it had slumped down the slope probably in a frozen block before discovery.28 The unique position of this mammoth indicates that the sliding probably did not change the original position of the mammoth at death. Even the trees were still generally upright in the material that slid down the hill.29
Russian researcher Tolmachoff reported several upright mammoth carcasses in Siberia. One of the carcasses was found in 1839, on the Shangin River, a tributary to the Indigirka River, in an upright position and protruding from a cliff.31 Another upright mammoth was also discovered in a cliff on the New Siberian Islands.32 Tolmachoff33 himself found parts of the skeleton of a mammoth on the coast of the Arctic Ocean, “… protruding out of frozen bluff in a more or less upright position.” He mentions in words similar to Howorth’s how Brandt was impressed about these upright mammoths:
Brandt was very much impressed by the fact that remnants of the mammoth, carcasses and skeletons alike, sometimes were found in poses which indicated that the animals had perished standing upright, as though they had bogged.34
Strangely, scientists investigating three woolly mammoths and two woolly rhinos, including the Beresovka mammoth, found they all died by suffocation.35 For a live animal to die of suffocation, it had to be buried rapidly or drowned.
Several of the carcasses have broken bones. Both of the upper front leg bones and some of the ribs of the Selerikan horse were broken.36 It was also missing its head. The Beresovka mammoth had a broken pelvis, ribs, and right foreleg.37 It takes quite a force to break the bones of a mammoth. The broken bones have inspired the story that the Beresovka mammoth was grazing on grass and buttercups when it accidentally fell into a crevasse in the permafrost. Then it was rapidly covered and suffocated.38 Buttercups, as well as leaves and grasses, were found in the mouth of the Beresovka mammoth between its teeth and tongue.39
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Source: http://www.answersingenesis.org/home/area/fit/chapter1.asp
jorgekafkazar says:
July 2, 2010 at 10:38 am
…..Science-weasels seem to think that in the social upheaval that follows a UN takeover, they will be at the top of the heap. Not so. Remember what happened in Russia? Intellectuals were among the first to be decimated by the new socialist regime. Their continued existence was unnecessary and…inconvenient.
http://www.ibiblio.org/expo/soviet.exhibit/attack.html
________________________________________________________________________
Not to mention dangerous since they had already proven they were activist types AND traitors.
Thanks for the reference. I have been looking for it for a while.
JJB MKI says:
July 2, 2010 at 11:22 am
“[…] I’m no mathematician, so I’d appreciate any thoughts from people here on whether my reasoning is valid: A modeler can only include known parameters in a model, even if the specific values of these are vague trends. […]”
Interesting ideas but the problem is much simpler than that: The modelers of current GCM’s estimate a lot of parameters at their whim because they don’t know them. To this day they don’t know whether aerosols have a warming or cooling net effect. They use this degree of freedom to optimize the parameters in such a way that the GCM’s do a correct hindcasting of the past 100 years. In this process, they practically end up with curve fitting and get no prove or disprove about whether they have the physics right. In other words, they make the models output the correct temperature series by tuning parameters.
They know that it’s a whimsical approach but can’t say so publicly; it would jeopardize further funding. It’s an open secret hidden behind a bewildering array of complicated-sounding papers (which are all bogus science because they build on the flawed pseudo-evidence delivered by flawed models).
So many mamooth carcasses found in sitting or standing position would indicate a sudden, abrupt, extremely fast cooling like the one shown in the blunder movie The Day After tomorrow.
An increase of sudden cooling events of short duration in the weather (as Heinrich events) could explain it. I would like to have a time travel machine…
I did not bother to read the initial paper. Did anyone bother to compute the temperature change from the albedo variation due to the mammoth fur itself? It’s adorned with pretty dark fur. So it means that the less mammoth there are, the lighter the globes becomes and cools down further.
Seriously, I find that their jump from correlation to causation is utterly appalling, and even more appalling is that this kind of stuff finds research budgets, and certainly is held as sensical by some of the newer generation of future scientists. THAT is the real menace.
I have an Albedo calculation model and can confirm Willis’ numbers are about right.
But why do the climate scientists spend so much time studying a small increase in a few small birch trees when not one of them has actually calculated the Albedo affect from the all that snow, glacier and sea ice during the ice ages which were also melting at this time period.
The extent of glaciers and sea ice (which have the highest Albedos of any surfaces) decreased by over 40 million km^2 and you can’t find a reasonable estimate of this affect anywhere. (Hansen has an artificially low one and there are a few other half-hearted attempts but the scientists have time to simulate effectively a Zero birch tree effect but not time for the Albedo of the Earth as a whole during the ice ages or 15,000 years ago).
More likely they’ve got causation backwards, assuming their correlation inference is correct.
DirkH says:
July 2, 2010 at 7:38 am
Curious Yellow says:
July 2, 2010 at 5:22 am
You didn’t get it, don’t turn a statement with a caveat into definitive. That’s all.
Willis:
Actually, this is a big “DUH.”
The very first mammoth bones discovered (at least by western scientists) were all the way over in Europe, and the range of some of the subspecies extended down all the way into Nicaragua and Honduras. That is one helluva range – the length of Russia plus the length of the Rocky Mountains plus the length of the Sierra Madres. Why does this study only talk about ones in Beringia? (or did I misunderstand this point?)
FYI: In the Arctic Ocean, the New Siberian Islands and Liakhov Island north of Siberia quite a distance from Beringia have entire hills composed of mammoth bones mixed with the dirt. The hills are piles of bones, essentially, and are about 200 feet high. BTW, mixed with the mammoth bones are the bones of rhinoceros and hippopotamus. No one has ever explained what the heck those animals were doing off the northern coast of Siberia.
Also, the nearest real trees to those islands are about 1,000 miles to the south. There is no evidence that trees ever lived that far north, which begs the question: Where was there enough food for the mammoths in the far, far north of Siberia, much less on the islands to the north?