Guest Post by Willis Eschenbach
I’ve been reflecting over the last few days about how the climate system of the earth functions as a giant natural heat engine. A “heat engine”, whether natural or man-made, is a mechanism that converts heat into mechanical energy of some kind. In the case of the climate system, the heat of the sun is converted into the mechanical energy of the ocean and the atmosphere. The seawater and atmosphere are what are called the “working fluids” of the heat engine. The movement of the air and the seawater transports an almost unimaginably large amount of heat from the tropics to the poles. Now, none of the above are new ideas, or are original with me. I simply got to wondering about what the CERES data could show regarding the poleward transport of that energy by the climate heat engine. Figure 1 gives that result:
Figure 1. Exports of energy from the tropics, in W/m2, averaged over the exporting area. The figures show the net of the energy entering and leaving the TOA above each 1°x1° gridcell. It is calculated from the CERES data as solar minus upwelling radiation (longwave + shortwave). Of course, if more energy is constantly entering a TOA gridcell than is leaving it, that energy must be being exported horizontally. The average amount exported from between the two light blue bands is 44 W/m2 (amount exported / exporting area).
We can see some interesting aspects of the climate heat engine in this graph.
First, like all heat engines, the climate heat engine doesn’t work off of a temperature. It works off of a temperature difference. A heat engine needs both a hot end and a cold end. After the working fluid is heated at the hot end, and the engine has extracted work from incoming energy, the remaining heat must be rejected from the working fluid. To do this, the working fluid must be moved to some location where the temperature is lower than at the hot end of the engine.
As a result, there is a constant flow of energy across the blue line. In part this is because at the poles, so little energy is coming from the sun. Over Antarctica and the Arctic ocean, the sun is only providing about a quarter of the radiated longwave energy, only about 40 W/m2, with the remainder being energy exported from the tropics. The energy is transported by the two working fluids, seawater and air. In total, the CERES data shows that there is a constant energy flux across those blue lines of about six petawatts (6e+15 watts) flowing northwards, and six petawatts flowing southwards for a total of twelve petawatts. And how much energy is twelve petawatts when it’s at home?
Well … at present all of humanity consumes about fifteen terawatts (15e+12) on a global average basis. This means that the amount of energy constantly flowing from the equator to the poles is about eight-hundred times the total energy utilized by humans … as I said, it’s an almost unimaginable amount of energy. Not only that, but that 12 petawatts is only 10% of the 120 petawatts of solar energy that is constantly being absorbed by the climate system.
Next, over the land, the area which is importing energy is much closer to the equator than over the sea. I assume this is because of the huge heat capacity of the ocean, and its consequent ability to transport the heat further polewards.
Next, overall the ocean is receiving more energy than it radiates, so it is exporting energy … and the land is radiating more than it receives, so it is getting energy from the ocean. In part, this is because of the difference in solar heating. Figure 2, which looks much like Figure 1, shows the net amount of solar radiation absorbed by the climate system. I do love investigating this stuff, there’s so much to learn. For example, I was unaware that the land, on average, receives about 40 W/m2 less energy from the sun than does the ocean, as is shown in Figure 2.
(Daedalus, of course, would not let this opportunity pass without pointing out that this means we could easily control the planet’s temperature by the simple expedient of increasing the amount of land. For each square metre of land added, we get 40 W/m2 less absorbed energy over that square metre, which is about ten doublings of CO2. And the amount would be perhaps double that in tropical waters. So Daedalus calculates that if we make land by filling in shallow tropical oceans equal to say a mere 5% of the planet, it would avoid an amount of downwelling radiation equal to a doubling of CO2. The best part of Daedalus’s plan is his slogan, “We have to pave the planet to save the planet” … but I digress).
Figure 2. Net solar energy entering the climate system, in watts per square metre (W/m2). Annual averages.
You can see the wide range in the amount of sunlight hitting the earth, from a low of 48 W/m2 at the poles to a high of 365 W/m2 in parts of the tropics.
Now, I bring up these two Figures to highlight the concept of the climate system as a huge natural heat engine. As with all heat engines, energy enters at the hot end, in this case the tropics. It is converted into mechanical motion of seawater and air, which transports the excess heat to the poles where it is radiated to space.
Now, the way that we control the output of a heat engine is by using something called a “throttle”. A throttle controls the amount of energy entering a heat engine. A throttle is what is controlled by the gas pedal in a car. As the name suggests, a throttle restricts the energy entering the system. As a result, the throttle controls the operating parameters (temperature, work produced, etc.) of the heat engine.
So the question naturally arises … in the climate heat engine, what functions as the throttle? The answer, of course, is the clouds. They restrict the amount of energy entering the system. And where is the most advantageous place to throttle the heat engine shown in Figure 2? Well, you have to do it at the hot end where the energy enters the system. And you’d want to do it near the equator, where you can choke off the most energy.
In practice, a large amount of this throttling occurs at the Inter-Tropical Convergence Zone (ITCZ). As the name suggests, this is where the two separately circulating hemispheric air masses interact. On average this is north of the equator in the Pacific and Atlantic, and south of the equator in the Indian Ocean. The ITCZ is revealed most clearly by Figure 3, which shows how much sunlight the planet is reflecting.
Figure 3. Total reflected solar radiation. Areas of low reflection are shown in red, because the low reflection leads to increased solar heating. The average ITCZ can be seen as the yellow/green areas just above the Equator in the Atlantic and Pacific, and just below the Equator in the Indian Ocean.
In Figure 3, we can see how the ITCZ clouds are throttling the incoming solar energy. Were it not for the clouds, the tropical oceans in that area would reflect less than 80 W/m2 (as we see in the red areas outlined above and below the ITCZ) and the oceans would be much warmer. By throttling the incoming sunshine, areas near the Equator end up much cooler than they would be otherwise.
Now … all of the above has been done with averages. But the clouds don’t form based on average conditions. They form based only and solely on current conditions. And the nature of the tropical clouds is that generally, the clouds don’t form in the mornings, when the sea surface is cool from its nocturnal overturning.
Instead, the clouds form after the ocean has warmed up to some critical temperature. Once it passes that point, and generally over a period of less than an hour, a fully-developed cumulus cloud layer emerges. The emergence is threshold based. The important thing to note about this process is that the critical threshold at which the clouds form is based on temperature and the physics of air, wind and water. The threshold is not based on CO2. It is not a function of instantaneous forcing. The threshold is based on temperature and pressure and the physics of the immediate situation.
This means that the tropical clouds emerge earlier when the morning is warmer than usual. And when the morning is cooler, the cumulus emerge later or not at all. So if on average there is a bit more forcing, from solar cycles or changes in CO2 or excess water vapor in the air, the clouds form earlier, and the excess forcing is neatly counteracted.
Now, if my hypothesis is correct, then we should be able to find evidence for this dependence of the tropical clouds on the temperature. If the situation is in fact as I’ve stated above, where the tropical clouds act as a throttle because they increase when the temperatures go up, then evidence would be found in the correlation of surface temperature with albedo. Figure 4 shows that relationship.
Figure 4. Correlation of surface temperature and albedo, calculated on a 1°x1° gridcell basis. Blue and green areas are where albedo and temperature are negatively correlated. Red and orange show positive correlation, where increasing albedo is associated with increasing temperature.
Over the extratropical land, because of the association of ice and snow (high albedo) and low temperatures, the correlation between temperature and albedo is negative. However, remember that little of the suns energy is going there.
In the tropics where the majority of energy enters the system, on the other hand, warmer surface temperatures lead to more clouds, so the correlation is positive, and strongly positive in some areas.
Now, consider what happens when increasing clouds cause a reduction in temperature, and increasing temperatures cause an increase in clouds. At some point, the two lines will cross, and the temperature will oscillate around that set point. When the surface is cooler than that temperature, clouds will form later, and there will be less clouds, sun will pour in uninterrupted, and the surface will warm up.
And when the surface is warmer than that temperature, clouds will form earlier, there will be more clouds, and higher albedo, and more reflection, and the surface will cool down.
Net result? A very effective thermostat. This thermostat works in conjunction with other longer-term thermostatic phenomena to maintain the amazing thermal stability of the planet. People agonize about a change of six-tenths of a degree last century … but consider the following:
• The climate system is only running at about 70% throttle.
• The average temperature of the system is ~ 286K.
• The throttle of the climate system is controlled by nothing more solid than clouds, which are changing constantly.
• The global average surface temperature is maintained at a level significantly warmer than what would be predicted for a planet without an atmosphere containing water vapor, CO2, and other greenhouse gases.
Despite all of that, over the previous century the total variation in temperature was ≈ ± 0.3K. This is a variation of less than a tenth of one percent.
For a system as large, complex, ephemeral, and possibly unstable as the climate, I see this as clear evidence for the existence of a thermostatic system of some sort controlling the temperature. Perhaps the system doesn’t work as I have posited above … but it is clear to me that there must be some kind of system keeping the temperature variations within a tenth of a percent over a century.
Regards to all,
w.
PS—The instability of a modeled climate system without some thermostatic mechanism is well illustrated by the thousands of runs of the ClimatePredictionNet climate model:
Note how many of the runs end up in unrealistically high or low temperatures, due to the lack of any thermostatic control mechanisms.
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Konrad says:
December 22, 2013 at 7:16 pm
I fear I don’t understand that. “Energy flowing from the surface to space” doesn’t drive tropospheric convective circulation. The circulation is driven by the massed thunderstorms of the ITCZ. These create the deep convection that make the whole thing go ’round …
w.
Willis,
I’m glad you gave Steve Mosher yet another thrashing. I was tempted to, but he’s, as you say, such a waste of time. Yes, he seemed smart at one time, but something happened over time which seems to have made him unable to be either objective or humble. I realize that’s somewhat the definition of a tr*ll, but I don’t think he’d accept that appellation. So what is he?
The foibles of the thermostat on the downside are far more nervous-making than are those on the upside. There are no historical or paleohistorical instances of harm from upside changes (droughts being cold dry air phenomena), but many of downside swings. Another (of a superfluity) fatal flaw of CAGW.
lets see. intertia ,,,,,,or some magical thermostat that makes a clunky analogy more analogical
Steven Mosher,
You should go to Engineering School to learn how awful a mistake this is. There is no Inertia, nor whatever intertia is, in the climate. Inertia is momentum, M x V, a simple scalar quantity. Heat and energy and power and flux, the last being what “Climate Scientists” think is a “forcing,” no inertia to be found anywhere, nor “intertia.”
Willis makes a strong point that increasing temperature, wherever, could and may be already causing an increase in clouds, which would be a true “regulator.” Without this sort of regulator the planet’s climate would have run away, in either direction, long ago.
I am not sold on either the posited “Snowball Earth,” nor Hansen’s “Fire = Venus” planet. Willis makes a strong point that either extreme would have happened long ago without some sort of regulator in the system. IPCC freely admit that they cannot model clouds.
Engineers are hired because any sort of energy costs money, and wasting money is offensive to the people who actually have to pay. Mosher, whatever it is you do for a living, it is not engineering.
Willis Eschenbach says:
December 22, 2013 at 8:53 pm
OK, not gas giants either …. any other exceptions you’d care to note?
Venus comes to mind…
Willis said:
“The other thing which bears constant restating is that the system can speed up without heating up, by increasing the throughput of the working fluid. This moves more energy polewards, without much increase in surface temperature.
Which of course is one more mechanism whereby an increase in forcing may not lead to an increase in temperature.”
Which has been exactly my point for years.
GHGs may initially act to slow down energy throughput but that is negated by a circulation change that speeds up throughput again to keep the system stable.
The change in speed of throughput is manifested by circulation shifts that we see as ‘climate change’.
The natural changes in throughput speed from oceanic and solar variability being many magnitudes greater than from changes in GHG amounts.
“The larger point that Willis is making is that magical incantations about pressure that people like Stephen Wilde make do not get him around having to conserve energy and thus make his various conjectures nothing but pseudoscientific nonsense.”
Nothing magical.
Work against gravity in uplift (cooling) is matched by work with gravity (warming) on descent.
Energy is conserved.
Nothing to do with gravitational collapse.
joeldshore said:
[This, of course, assumes the environmental lapse rate doesn’t change, which is a good first approximation. In reality, the environmental lapse rate in the tropics is expected to decrease a little bit because the moist adiabatic lapse rate is a decrease function of temperature…and so this produces a negative feedback, i.e., causes the surface temperature to increase somewhat less than the above considerations predict.]
GHGs do change the environmental lapse rate and in the case of water vapour it is a lot. Check the difference between the dry and moist lapse rates.
Ozone actually reverses the environmental lapse rate above the tropopause.
The effects are then negated for the system as a whole by speed of throughput changes (circulation shifts) as Willis correctly observes.
re the graph of lower stratospheric temp Willis posted in comment-1510262
http://wattsupwiththat.files.wordpress.com/2013/12/uah-msu-stratospheric-temperature.jpg?w=560
Despite the obsession of everyone to look for (linear) trends, this graph anything but linear and those incapable of thinking in anything but Excel fitted straight lines will miss the point.
Both events resulted in a drop in temperature (by eye about 0.3 and 0.6K respectively).
The initial disruption of the weaker, earlier event lasted about 2.5 years, for Mt.P it lasted about 4 years. (I think Willis’ grey lines are a short, though that’s subjective without a formal criterion).
There was an essentially flat period between the two, although one could suggest a slight rebound. Similarly after Mt.P there is clear rebound bump, though post 97 is essentially flat.
So the information shown here would suggest that despite the initial warming spike the decadal scale effect of both eruptions was permanent drop in stratospheric temperature.
We have the advantage here of seeing a clear signal of both events relatively unperturbed by the sort of large scale variability that confounds clear identification in the surface records.
As I understand the explanation of the warming spike it is due to blocking of incoming solar due to changes in the composition of the stratosphere. The same argument then leads to the conclusion the persistent drop in LST after each event indicates less blocking of solar (this has been discussed elsewhere in detail).
This means that the net effect of these major eruptions is an ADDITIONAL radiative input to the lower climate system, not the exaggerated cooling “forcing” that is used counter balance the speculative amplification CO2 effects.
How much of the late 20th c. warming was caused the climate’s response to those events that is witnessed in the stratosphere data?
Willis said:
“Seems there’s been a misunderstanding, Stephen. The people I call “pressure heads” are those that think that on a planet with a GHG-free atmosphere, say an argon atmosphere, that pressure alone can raise the temperature of the surface”
Noted and thanks but I think you may find that even a nearly radiatively inert argon atmosphere will have a warmer surface than S-B predicts due to uneven surface heating and the consequent convective circulation.
It isn’t the pressure alone that does it but rather the time delay in energy throughput resulting from the conversion of kinetic energy at the surface to gravitational potential energy higher up during uplift and then reconversion back to kinetic energy during descent.
That is how your thermostat really works.
The clouds and thunderstorms are a consequence of the rising air being rich in water vapour and are thus a side effect rather than a driving force.
Greg on December 22, 2013 at 3:12 pm
phlogiston says:“Off of” is a cacophonous new American-English grammar construct. What does it mean? Its horrible, stop it!“
Construct” is a verb. Construction is the noun. Abuse of verbs as nouns is a horrible American-English habit, stop it! Grammar is a noun , grammatical is the adjective. Abusing nouns as adjectives is a horrible American-English habit, stop it!
Use of nouns as adjectives and verbs as nouns is becoming a reality in vernacular english. OK its not high english but it pales into insignificance next to “off of”.
Folks (now I’m using US vernacular) are reading too much into this article and criticising it unfairly. Willis did not – I’m sure – intend it as a new climate model of everything. He just points out the fact, beyond dispute, that the climate system is a heat engine, which follows from the equally uncontroversial assertion that the equator is closer to the sun than the poles (and sunlight has a shorter path).
Two terms are very conspicuous by their absence from this debate: they are “dissipative” and “far from equilibrium”. These descriptors strongly characterise the climate heat engine and they are also the major pre-requisites of a system to enter dynamical chaos and exhibit nonlinear pattern formation.
Important insights into the climate heat engine would flow from this understanding, but they are not doing so. It is sad to see that half a century after the discoveries of Lorenz, Feigenbaum, Mandelbrot, Prigogine and many others, mainstream science still turns a blind eye toward chaotic and nonlinear dynamics and pattern. A valid scientific revolution is being extinguished by predjudice.
Willis Eschenbach says:
December 22, 2013 at 9:23 pm
—————————————————-
“I fear I don’t understand that. “Energy flowing from the surface to space” doesn’t drive tropospheric convective circulation. The circulation is driven by the massed thunderstorms of the ITCZ. These create the deep convection that make the whole thing go ’round …”
Perhaps I should have written energy flowing from the surface to space via both radiative and non-radiative transports.
I would have to disagree that thunderstorms make the “whole thing go ’round”?
Previously you stated that “A heat engine needs both a hot end and a cold end.”
Moist convective uplift and release of latent heat in Hadley circulation is the “hot end”.
Radiative energy loss to space at altitude is the “cold end”.
Comments from Dr. Spencer in 2009 indicated that he believed almost all tropospheric circulation would cease in the absence of radiative gases (except for a very thin near surface layer), and such a static atmosphere would trend isothermal through gas conduction.
(I found Dr. Spencer’s 2009 comments after conducting simple empirical experiments after 2011 on relative heights of energy entry and exit from tall gas columns and its effect on Raleigh-Bernard circulation and average temperature. I was backtracking to find out who else knew.)
While Dr. Spencer’s claim may seem dramatic, it is completely in line with the results of my gas column experiments.
Willis, I’m going to have to ask for clarification. Do you believe strong vertical tropospheric circulation in the Hadley, Ferrel and Polar cells can continue in the absence of radiative cooling at altitude?
Willis said:
“The other thing which bears constant restating is that the system can speed up without heating up, by increasing the throughput of the working fluid. This move more energy polewards, without much increase in surface temperature.”
Why and when would it speed up without heating up? And surely if there is an upper limit on tropical surface temperature, moving more energy polewards will increase the total surface temperature.
I would reckon that the poleward transport of energy is differential between the ocean and atmosphere. More atmospheric energy is transported poleward when the jet streams are more poleward, and more warmer ocean is transported poleward when the jet streams move towards the equator.
Steven Mosher says: @ur momisugly December 22, 2013 at 7:49 am
“Despite all of that, over the previous century the total variation in temperature was ≈ ± 0.3K. This is a variation of less than a tenth of one percent….
######################
lets see. intertia ,,,,,,or some magical thermostat that makes a clunky analogy more analogical
>>>>>>>>>>>>>>>>>>>>>>>>
Or a specific set of conditions, continent configurations that have kept the Holocene temperature unusually stable GRAPH
And these graphs GRAPH 1 and GRAPH 2 showing overall cooling.
“conducting simple empirical experiments after 2011 on relative heights of energy entry and exit from tall gas columns ”
You could get an isothermal structure from a tall glass column with a perfectly flat base, vertical sides and evenly illuminated at the base.
Not so for a rough surfaced, rotating sphere illuminated from a point source of light. In that case you would always get cooling with altitude because of the density variations arising throughout the volume occupied by the gases and the consequent circulation.
– Bob Weber says:
December 22, 2013 at 4:02 pm
It’s been a pleasure checking this article out Willis. If the clouds are a throttle, where is the engine? And what is the fuel? A throttle that acts as a thermostat is very interesting. –
Engine is ocean. Fuel is sunlight.
Fuel is source of energy. Throttle controls how much fuel/energy gets to engine.
But also need brakes. Ocean is engine and brakes [:) jake brake??].
And Ocean is also a flywheel.
But the land surface is also a engine, it’s just not the main engine.
Land not a main engine because it’s low percentage of total surface area- particularly in tropics
where most sunlight reaches Earth. And Ocean is more of engine per square km of area.
So ocean area of same area as land is a more powerful engine.
So oceans dominate Earth global climate and weather. And it’s mostly the tropical ocean.
Which is all well known. Or everyone knows El Niño and .La Niña have large effect upon weather and global climate. Everyone knows Europe is warmer due to the Gulf Stream.
Everyone know coastal regions have more milder weather- doesn’t get as cold nor get as hot- but mostly doesn’t get as cold when in night and winter.
Land has higher temperatures, but not higher average temperature. Land warms the air during the day, but doesn’t warm air much during night.
And the atmosphere is also an engine. It’s whole focus of “greenhouse efect” but it’s a minor
engine, and also minor flywheel. Or instead flywheel it’s like the mass or load of vehicle.
And we ocean evaporating and condensation- more flywheel/battery/load/governor/regenerative braking.
So land is only place you get high surface and air temperatures. But high surface [skin] temperature and high air temperature has little to do with increasing global aveage temperature- or the Moon would have a high average temperature. High global average temperature is all about retaining heat, and ocean retains heat for centuries of time.
So the main factor of why our world has what might seem a high average temperature is largely or nearly exclusively about the Earth’s oceans. Or put a deep global ocean of water on the Moon and Moon will have a much higher average temperature.
Ulric Lyons asked
“Why and when would it speed up without heating up?”
Because the additional energy is in the form of gravitational potential energy and not kinetic energy.
The change in size or speed of the convective heat engine changes the ratio of kinetic energy and gravitational potential energy within the atmospheric gases so as to keep radiation out to space equal to radiation in from space. That also involves keeping the surface temperature stable despite forcing elements that try to destabilise it.
The phase changes of water are an additional ‘lubricant’ which increases the efficiency of the engine so that less violent circulation changes are needed to maintain stability.
If cloudiness changes occur then that alters the proportion of top of atmosphere incoming radiation that enters the oceans and so mimics a change in top of atmosphere insolation and will change the surface temperature.
Even then the system will maintain stability by adjusting the speed of energy throughput via circulation adjustments.
gbaikie said:
“So the main factor of why our world has what might seem a high average temperature is largely or nearly exclusively about the Earth’s oceans.”
Yes.
Been saying that for years. See The Hot Water Bottle Effect.
For energy retention purposes the oceans must be regarded as part of Earth’s atmosphere.
As someone else said “The atmosphere is the continuation of the oceans by other means”.
It would be interesting to calculate the thermodynamic efficiency of this global heat engine and compare it with the best man made heat engines. For instance the boiler turbine condenser cycle of a modern power plant operating near the critical point is at best around 50%.
Leif writes “Neither is Jupiter nor Venus [for that matter]. These bodies are not contracting”
Jupiter is thought to be contracting. Thats where it gets its extra energy from.
Leif also wrote “These bodies are not contracting, their atmospheres are just obeying the usual gas law: PV = nRT”
But the atmosphere of Venus is CO2 as a supercritical fluid which doesn’t behave like an ideal gas.
TimTheToolMan says:
December 23, 2013 at 5:02 am
Jupiter is thought to be contracting. Thats where it gets its extra energy from.
That contraction is of minor importance and certainly not in the outer layers. Most of Jupiter’s energy is simply left over from its formation.
TimTheToolMan says:
December 23, 2013 at 5:37 am
But the atmosphere of Venus is CO2 as a supercritical fluid which doesn’t behave like an ideal gas.
No, only the lowest part near the surface is. Most of the atmosphere is not and is still hot and under high pressure.
cagwsceptic says:
December 23, 2013 at 4:16 am
It would be interesting to calculate the thermodynamic efficiency of this global heat engine and compare it with the best man made heat engines.
================
I posted just such a back of the envelope calculation awhile back. The efficiency was about 20%.
-TimTheToolMan says:
December 23, 2013 at 5:37 am
But the atmosphere of Venus is CO2 as a supercritical fluid which doesn’t behave like an ideal gas.
No, only the lowest part near the surface is. Most of the atmosphere is not and is still hot and under high pressure.-
Yes. But increased earth atmosphere by 20 times, this would be the supercritical part, and add 70 times more of the Earth’s 1 atm atmosphere that would the part not supercritical.
Or:
… “above the critical point for carbon dioxide, it can adopt properties midway between a gas and a liquid. More specifically, it behaves as a supercritical fluid above its critical temperature (304.25 K) and critical pressure (72.9 atm” ….
http://en.wikipedia.org/wiki/Supercritical_carbon_dioxide
Or it’s supercritical for about first 4 km of elevation above surface.
Disfused sunlight reaching Venus surface, and it seems it would be less disfused at 4 km elevation. But I suppose it’s mostly significant in terms of having better transfer of heat, so I suppose allows better global uniformity of temperature [or less wind is required to transfer heat].
I have wondered if supercritical CO2 has anything to do with explaining Venus high temperature,
but mostly I think it’s large atmosphere and the clouds [droplets of H2SO4] which heated by sunlight. And sulfuric acid rain which occurs at a much higher elevation in the Venus atmosphere which could explain mostly why Venus is hot.
Though it possible also could have something with Venus planetary interior heat being so well insulated by the dense atmosphere.