[I’m making this excellent essay a top sticky post for a day or two, I urge sharing it far and wide. New stories will appear below this one. – Anthony]
Guest Post by Willis Eschenbach
Dr. Kevin Trenberth is a mainstream climate scientist, best known for inadvertently telling the world the truth about the parlous state of climate science itself. In the Climategate emails published in 2009, it was revealed that in private he had said:
The fact is that we can’t account for the lack of warming at the moment and it is a travesty that we can’t.
This from a spokesman for the folks who have been telling us for years that the science is settled …
However, the problem seems to be solved. Kevin Trenberth, Distinguished Senior Scientist, (as he is described on his web page) has emailed Joe Romm, Distinguished Senior Climate Alarmist, about the status of Dr. Trenberth’s tireless quest to find the missing heat, stating (emphasis in Romm’s post):
“We can confidently say that the risk of drought and heat waves has gone up and the odds of a hot spot somewhere on the planet have increased but the hotspot moves around and the location is not very predictable. This year perhaps it is East Asia: China, or earlier Siberia? It has been much wetter and cooler in the US (except for SW), whereas last year the hot spot was the US. Earlier this year it was Australia (Tasmania etc) in January (southern summer). We can name spots for all summers going back quite a few years: Australia in 2009, the Russian heat wave in 2010, Texas in 2011, etc.”
I’ll return to the serious question of Dr. Trenberth’s missing heat in a moment. But first, let’s consider Dr. Trenberth’ statement, starting with the section highlighted in bold in Joe’s post, viz:
“We can confidently say that the risk of drought and heat waves has gone up and the odds of a hot spot somewhere on the planet have increased but the hotspot moves around and the location is not very predictable.”
That single sentence contains all the required elements of a good novel—unpredictability, increasing risks, a dangerous moving “hotspot”, confident experts, a planet in peril … all the stuff that goes into an exciting story, it’s perfect for a direct-to-DVD movie.
The only problem with Dr. Trenberth’s statement is that like all novels, it’s fiction. To start with, Dr. Trenberth is very careful not to claim that droughts and heat waves and “hotspots” have actually increased. Did you notice that? You need to watch statements about climate very closely. He didn’t say that the number of droughts or heat waves have gone up. That’s a falsifiable statement, and one which is decidedly not true, so he prudently avoided that pitfall. The IPCC itself has said that we have no evidence of any increases in drought, in heat waves, or in any other climate extremes, despite a couple of centuries involving a couple of degrees of warming. But then, Dr. Trenberth didn’t say droughts or heat waves have gone up, did he?
He said the risk of droughts and heat waves has gone up. He said the “odds of a hot spot somewhere on the planet” have gone up. Presumably, this deep knowledge of the probability of future climate catastrophes has been vouchsafed to Dr. Trenberth by means of the climate models … the same climate models that are part of the “travesty” because they can’t account for the missing heat. He’s citing risks and odds based on climate models that were unable to forecast the current hiatus in warming which has gone on for fifteen years or so now, despite continuing increases in CO2 and methane and black carbon and the like …
The part that I particularly enjoyed is the foreboding, menacing quality of his claim that there is now some roving “hotspot”, whose location “moves around” and “is not very predictable”. Dang, what if the dreaded “hotspot” comes to my town? Does he mean we might be faced with the much-feared phenomenon known locally as “a really hot summer”. We know those summers, when bad things happen, like the time when Jimmy Fugate punched out the eleventh guy, by Jimmy’s actual count, who had said “Hot enough for ya?” to him on that fateful August day … but although I digress, we know the danger is real, because as Dr. Trenberth warns us, the hot spot is on the move, viz:
It has been much wetter and cooler in the US (except for SW), whereas last year the hot spot was the US. Earlier this year it was Australia (Tasmania etc) in January (southern summer). We can name [hot]spots for all summers going back quite a few years …
I gotta admit, this is stunning news. Dr. Trenberth is giving us inside climate information, full of extra scientificity, that every summer some places are extra-hot, while you’d be amazed to find out, other locations have extra-cool summers. We’re in one of the latter where I live. Around here, this has been one of the coolest summers in recent years.
So following in Dr. Trenberth’s trail-blazing footsteps, here’s my new climate theory. It revolves around the dreaded “coldspot”. You may be shocked when I tell you that every summer there’s a “coldspot” somewhere in the world, a place where the summer is much colder than usual. Last year the coldspot was Russia. This year it has moved to Northern California where I live. Here’s what makes coldspots so dangerous, as highlighted by Dr. Trenberth. The coldspot “moves around and the location is not very predictable” … so you should be very afraid, because science.
I mean … are we supposed to take this talk of “moving hotspots” seriously? Is this how desperate the alarmists are getting?
Joe Romm’s quote of Dr. Trenberth closes with this suitably ominous line, which I assume is preparing us for the sequel …
Similarly with risk of high rains and floods: They are occurring but the location moves.
Ahhh, Dr. Trenberth is referring to the dreaded “wetspot”, and he doesn’t mean the one the baby leaves on your shoulder. Did you know that every year during the rainy season there’s a “wetspot” somewhere in the world, a place where it rains more than usual? And did you know the wetspot moves around the world and the location is not very predictable? There’s no end to the insights available in Dr. Trenberth’s concepts …
I have to say, I find Dr. Trenberth’s claims both very depressing and very encouraging. They’re depressing because they are a million miles from science. It’s just a frightening tale for children around the campfire, about how the risks of bad things are rising, and it’s worse than we thought.
But it’s encouraging, because when the intellectual leaders of the climate alarmism movement sink to peddling those kinds of scare stories, it’s a clear indication that they’re way short of actual scientific arguments to back up their inchoate fears of Thermageddon.
In any case, let me move on to the more serious topic I mentioned above, regarding Dr. Trenberth’s infamous “missing heat”. Let me suggest where some of it is going. It’s going back out to space.
One of the main thermal controls on the planet’s heat balance is the relationship between surface temperature on one hand, and the time of day of cumulus and cumulonimbus formation in the tropics. On days when the surface is warmer, clouds form earlier in the day. The opposite is true when the surface is cooler, clouds form later. This control operates on an hourly basis. I’ve shown how this affects the daily evolution of tropical temperature here and here using the TAO moored buoy data. Here’s a bit of what I demonstrated in those posts. Figure 2, from the second citation, shows how cold mornings and warm mornings affect the evolution of the temperature of the ensuing day.
Figure 2. Average of all TAO buoy records (heavy black line), as well as averages of the same data divided into days when dawn is warmer than average (heavy red line), and days when dawn is cooler than average (heavy blue line) for each buoy. Light straight lines show the difference between the previous and the following 1:00 AM temperatures.
The control of the surface temperature is exerted in two main ways: 1) in the morning, cumulus cloud formation reduces incoming solar radiation by reflecting it back to space, and 2) in the afternoon, thunderstorms both increase cloud coverage and remove energy from the surface and transport it to the upper troposphere. We can see both of these going on in the average temperatures above.
The black line in Figure 2 shows the average day’s cycle. The onset of cumulus is complete by about 10:00. The afternoon is warmer than the morning. As you would expect with an average, the 1 AM temperatures are equal (thin black line).
The days when the dawn is warmer than average for each buoy (red line) show a different pattern. There is less cooling from 1AM to dawn. Cumulus development is stronger when it occurs, driving the temperature down further than on average. In addition, afternoon thunderstorms not only keep the afternoon temperatures down, they also drive evening and night cooling. As a result, when the day is warmer at dawn, the following morning is cooler.
In general, the reverse occurs on the cooler days (blue line). Cooling from 1 AM until dawn is strong. Warming is equally strong. Morning cumulus formation is weak, as is the afternoon thunderstorm foundation. As a result, when the dawn is cooler, temperatures continue to climb during the day, and the following 1AM is warmer than the preceding 1 AM.
Regarding the reduction in incoming solar energy, in a succeeding post called “Cloud Radiation Forcing in the TAO Dataset“, I provided measurements of the difference between the shortwave and longwave radiation effects of tropical clouds, based on the same TAO buoy data. The measurements showed that around noon, when cumulus usually form, the net effect of cloud cover (longwave minus shortwave) was a reduction of half a kilowatt per square metre in net downwelling radiative energy.
In addition to that reduction in downwelling radiation, there is another longer-term effect. This is that we lose not only the direct energy of the solar radiation, but also the subsequent “greenhouse radiation” resulting from the solar radiation. In the TAO buoy dataset, the 24/7 average downwelling solar radiation reaching the surface is about 250 W/m2. Via the poorly-named “greenhouse effect” this results in a 24/7 average downwelling longwave radiation of about 420 w/m2. So for every ten W/m2 of solar we lose through reflection to space, we also lose an additional seventeen W/m2 of the resulting longwave radiation.
This means that if the tropical clouds form one hour earlier or later on average, that reduces or increases net downwelling radiation by about 50 W/m2 on a 24/7 basis. This 100 W/m2 swing in incoming energy, based solely on a ± one-hour variation in tropical cloud onset time, exercises a very strong daily control on the total amount of energy entering the planetary system. This is because most of the sun’s energy enters the climate system in the tropics. As one example, if the tropical clouds form on average at five minutes before eleven AM instead of right at eleven AM, that is a swing of 4 W/m2 on a 24/7 basis, enough to offset the tropical effects of a doubling of CO2 …
Not only that, but the control system is virtually invisible, in that there are few long-term minute-by-minute records of daily cloud onset times. Who would notice a change of half an hour in the average time of cumulus formation? It is only the advent of modern nearly constant recording of variables like downwelling long and shortwave radiation that has let me demonstrate the effect of the cloud onset on tropical temperatures using the TAO buoy dataset.
While writing this here on a cold and foggy night, I realized that I had the data to add greatly to my understanding of this question. Remember that I have made a curious claim. This is that in the tropics, as the day gets warmer, the albedo increases. This means that we should find the same thing on a monthly basis—warmer months should result in a greater albedo, there should be a positive correlation between temperature and albedo. This is in contrast to our usual concept of albedo. We usually think of causation going the other way, of increasing albedo causing a decrease in temperature. This is the basis of the feedback from reduced snow and ice. The warmer it gets, the less the snow and ice albedo. This is a negative correlation between albedo and temperature, albedo going down with increasing temperature. So my theory was that unlike at the poles, in the tropics the albedo should be positively correlated with the temperature. However, I’d never thought of a way to actually demonstrate the strength of that relationship at a global level.
So I took a break from writing to look at the correlation of surface temperature and albedo in the CERES satellite dataset. Here’s that result, hot off of the presses this very evening, science at its most raw:
Figure 3. Correlation between albedo and temperature, as shown by the CERES dataset. Underlying data sources and discussion are here.
Gotta confess, I do love results like that. That is a complete confirmation of my claim that in the tropics, as the temperature increases, the albedo increases. Lots of interesting detail there as well … fascinating.
My conclusion is that Dr. Trenberth’s infamous “missing heat” is missing because it never entered the system. It was reflected away by a slight increase in the average albedo, likely caused by a slight change in the cloud onset time or thickness.
My regards to everyone,
w.
Willis said “So my theory was that unlike at the poles, in the tropics the temperature should be positively correlated with the temperature.”
Did you meant to say “…in the tropics the albedo should be positively correlated with the temperature.” ?
Perhaps Josh could come up with a new mascot, a dog named “Hotspot” with a wanderlust and we’re all trying to find him like “Where’s Waldo?”
Willis brings up the Arctic. This brought back memories of a NASA researcher a few years back where he basically talked of melting ice, more clouds, no loss of albedo.
http://cat.inist.fr/?aModele=afficheN&cpsidt=18294421
Terry says:
August 21, 2013 at 6:02 am
Actually, both …
w.
Let’s see. the Hot Spot moves around, it’s location can’t be predicted – just like the pea under one of the three shell.
@Wilis: Does your correlation get better if you just plot summer in NH & summer in SH instead of the yearly average?
Willis You might want to fix a glitch in the post.- You say “temperature should be positively correlated with the temperature” Otherwise a great piece.You might extend this line of investigation to climate. by integrating the tropical radiation balance due to orbital variations (mainly the precession of the equinoxes – see http://journalofcosmology.com/JOC22/Steel_PPPIGW.pdf )
with the changing solar radiation spectrum see the latest SORCE data.
and the changes attributable to the change in incoming GCRs.
That would just about wrap up the the whole climate question. I can ook forward to a post from you along these lines in a couple of weeks – no doubt.
To continue where Jimbo left off:
…climate science. ☺
dbstealey says:
August 21, 2013 at 9:51 am
Surely the entrails of a starved to death polar bear cub are the One True Prognosticatory Sign.
While many have focused on the humorous “spotology”, the real spear into the AGW elephant is the CERES graph. Nice find Willis, it is clear evidence that clouds are a negative feedback where it matter most … in the tropics. I should also note that CERES data also verifies the RSS data showing a clear regime shift from warming to cooling around 2005. CERES is a skeptics best friend.
I love Family Circle, especially when Billy tries to walk a straight line through the neighborhood. Replace Billy with Hotspot and we have the makings of a … wait for it … cartoon! Climate Science reduced to a cartoon. And that’s the end of THAT story!
Sorry folks, only North and south Carolina have “Hot Spots”. We have located them all years ago and have moved on: http://www.hotspotcstore.com/locations.html
I know where Trenberth’s “hot spot” is–he couldn’t find it in the atmosphere, so he looked down on Earth and found multiple hot spots! They just happen to coincide with every coal-fired power plant.
And that explains Obama’s war on coal.
SteveV says:
August 21, 2013 at 3:50 am
The moving hotspot. I believe there is a term for this. It’s called the Texas sharpshooter fallacy.
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Brilliant. However, it surely applies to much more than the moving hotspot.
Eschenbach is right. It would make a great b-movie. One of those scifi movies that are so bad they’re funny. “The Hotspot That Baked Chicago”.
I see spots befors my eyes. Call Trenberth quick. I need to know which spots they are.
choey2 says:
August 21, 2013 at 10:34 am
Eschenbach is right. It would make a great b-movie. One of those scifi movies that are so bad they’re funny. “The Hotspot That Baked Chicago”.
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Since sharks are out, maybe the roving hot spot carries with it buzzards & vultures.
One cannot claim the “odds” of drought have increase if there is no shift in the sampled set.
One cannot claim loaded dice when the sampling to date shows an unloaded distribution. If we start with a hypothesis of “loaded die”, and look at the rolling history of that die and see even distribution (within expected sampling errors), then we can invalidate the hypothesis.
richardscourtney Thanks for your clarifications they are important.
Ken Hall says:
August 21, 2013 at 7:03 am
“So how come physicists have not been able to quantify and measure this new found function of heat, which I now label, ‘sneaky’. This function, apparently, renders heat able to hide away from satellites and even has the ability to sink in water, to depths of deeper than 700 meters, without being detected as it descends. What is the distinctive atomic or molecular mechanism, derived from CO2, which can transform ordinary, rising heat, into first the very sticky heat, (which does not leave the top of the atmosphere, (thus warming the planet according to models)) and then through to this new ‘sneaky’ heat, which can also sink and hide?
I ask because in spite of the alarmists claiming that there are the equivalent of n thousand Hiroshima nuclear blasts worth of heat being added to the atmosphere, the heat is stubbornly refusing to make itself known to all attempts to find it.”
Perhaps an entirely new field of study? Combine ‘sticky heat’ and ‘sneaky heat’ in the new field of ‘Black Heat’? or perhaps ‘Anti-Heat’- since Dr. Trenberth and colleagues can’t seem to find it?
Dear God let us NOT get into another row of exactly what is the definition of the “heat” in the illusive hotspot. Keep that hatchet BURIED!
Dr. Kevin Trenberth, Distinguished Senior Scientist says:
“We can confidently say that […] the odds of a hot spot somewhere on the planet have increased.”
It is supposed to be a scientific proposition, is it? In that case it should be falsifiable, that is, we can unequivocally describe a hypothetical state of affairs, which, if observed, would make its negation true. Something along the lines “It is not the case we can confidently say…”. Or, somewhat more directly and ridiculously:
“We can diffidently say that the odds of a hot spot somewhere on the planet have increased.”
Now, what kind of proposition is that? Its subject matter is not even climate, but the mental state of some climate scientists, that is, their confidence or the lack thereof. As such, it is surely not a scientific proposition, or if it was, it did not belong to the natural sciences, but to sociology, psychology, whatever.
However, we are not interested in those disciplines right now, are we? So, let’s proceed with the kernel of Trenberth’s proposition, which relates to objective reality, not his pals’ stance concerning a certain proposition.
“The odds of a hot spot somewhere on the planet have increased.”
Much better. We only need a clear cut definition of “hot spot” to make it falsifiable. Or rather, a definition of “hot spot (B)”, because there is already a technical term in climate science under the very same name, with a completely different meaning. Ouch. A Distinguished Senior Scientist is surely aware of this inconvenient fact. Anyway.
1. Hot Spot (A): A hypothetical layer high up in tropical troposphere where rate of warming is much faster than close to the surface (not observed).
2. Hot Spot (B): A region close to the surface anywhere on the globe, which happens to be much warmer than its surroundings. Or something to that effect.
We have some 24 years of continuous satellite observations in digital format with reasonable resolution, therefore it should be possible to identify all occurrences of “Hot Spot (B)” in channel TLT (Temperature Lower Troposphere) under any reasonable technical definition of the concept using a simple script. I am not aware of such a study, nevertheless it looks quite feasible.
Its result would either confirm or reject Trenberth’s proposition.
The only question remaining is what fuels the confidence of a Distinguished Senior Scientist in the absence of such study. But that’s a question for psychology and has nothing to do with climate science as such.
and when they got home they found a hook dangling from the car door handle … the hooked killer had just missed 2 more victims …
First the “hotspot” was the relatively rapid warming of the upper troposphere that would be seen if warming were caused by increased CO2, but that hotspot went missing. Then there was Trenberth’s Loch Ness deep ocean hotspot, where the missing heat was supposedly slipping into the abyss, too far down for us to find it. Now he’s claiming that for gauging climate it is weather that matters, not climate. From the upper troposphere to the deep oceans to rank disinformation, and he will probably find a way to go lower still.
P.S. to Willis: awesome albedo correlation discovery. Any speculation on how the tropical albedo effect is likely to change as the world warms or cools? That is, any speculation on the second derivative of albedo with respect to temperature? I’m curious because the second derivative is dramatic in the case of polar albedo effects, making cooling inherently much more dangerous than warming, but what really matters is the planetary second derivative, which requires putting the polar second together in an appropriately weighted sum with the tropical second.
In the polar case the albedo effect gets weaker as the world warms and stronger as the world cools. In the cooling direction, snow and ice descend to latitudes that cover much larger swaths of surface area (which in the northern hemisphere are mostly land, which only needs freezing temperatures to hold snow cover). These lower latitudes also receive more direct insolation, so the albedo effect rapidly increases by both area and the amount of energy reflected per area. In the warming direction the marginal polar albedo effect decreases for the same reasons. There is not much snow and ice left to melt and it is only reflecting away a very oblique insolation anyway.
Thus from our present starting point the polar albedo feedback in the warming direction would seem to be benign in terms of having little power to create any runaway temperature change, but in the cooling direction the albedo feedback is increasingly “vicious,” confirmed by fact that it regularly throws the planet into hundred thousand year long glacial periods. For figuring out what we should be worried about, the second derivative is huge. It marks a strong asymmetry where there is little to worry about in one direction and much to worry about in the other.
But the polar albedo effect is only part of the picture so I’m curious what the tropical second derivative of albedo with respect to temperature might be.