Guest Post by Willis Eschenbach
I’ve been considering the effect that temperature swings have on the average temperature of a planet. It comes up regarding the question of why the moon is so much colder than you’d expect. The albedo (reflectivity) of the moon is less than that of the Earth. You can see the difference in albedo in Figure 1. There are lots of parts of the Earth that are white from clouds, snow, and ice. But the moon is mostly gray. As a result, the Earth’s albedo is about 0.30, while the Moon’s albedo is only about 0.11. So the moon should be absorbing more energy than the Earth. And as a result, the surface of the moon should be just below the freezing temperature of water. But it’s not, it’s much colder.
Figure 1. Lunar surface temperature observations from the Apollo 15 mission. Red and yellow-green short horizontal bars on the left show the theoretical (red) and actual (yellow-green) lunar average temperatures. The violet and blue horizontal bars on the right show the theoretical Stefan-Boltzmann temperature of the Earth with no atmosphere (violet), and an approximation of how much such an Earth’s temperature would be lowered by a ± 50°C swing caused by the rotation of the Earth (light blue). Sunset temperature fluctuations omitted for clarity. DATA SOURCE
Like the Earth, averaged over its whole surface the moon receives about 342 watts per square metre (W/m2) of solar energy. We’re the same average distance from the sun, after all. The Earth reflects 30% of that back into space (albedo of 0.30), leaving about 240 W/m2. The moon, with a lower albedo, reflects less and absorbs more energy, about 304 W/m2.
And since the moon is in thermal equilibrium, it must radiate the same amount it receives from the sun, ~ 304 W/m2.
There is something called the “Stefan Boltzmann equation” (which I’ll call the “S-B equation” or simply “S-B”) that relates temperature (in kelvins) to thermal radiation (in watts per square metre). It says that radiation is proportional to the fourth power of the temperature.
Given that the moon must be radiating about 304 W/m2 of energy to space to balance the incoming energy, the corresponding blackbody lunar temperature given by the S-B equation is about half a degree Celsius. It is shown in Figure 1 by the short horizontal red line. This shows that theoretically the moon should be just below freezing.
But the measured actual average temperature of the lunar surface shown in Figure 1 is minus 77°C, way below freezing, as shown by the short horizontal yellow-green line …
So what’s going on? Does this mean that the S-B equation is incorrect, or that it doesn’t apply to the moon?
The key to the puzzle is that the average temperature doesn’t matter. It only matters that the average radiation is 304 W/m2. That is the absolute requirement set by thermodynamics—the average radiation emitted by the moon must equal the radiation the moon receives from the sun, 304 W/m2.
But the radiation is proportional to the fourth power of temperature. This means when the temperature is high, there is a whole lot more radiation, but when it is low, the reduction in radiation is not as great. As a result, if there are temperature swings, they always make the surface radiate more energy. As a result of radiating more energy, the surface temperature cools. So in an equilibrium situation like the moon, where the amount of emitted radiation is fixed, temperature swings always lower the average surface temperature.
For confirmation, in Figure 1 above, if we first convert the moment-by-moment lunar surface temperatures to the corresponding amounts of radiation and then average them, the average is 313 W/m2. This is only trivially different from the 304 W/m2 we got from the first-principles calculation involving the incoming sunlight and the lunar albedo. And while this precise an agreement is somewhat coincidental (given that our data is from one single lunar location), it certainly explains the large difference between simplistic theory and actual observations.
So there is no contradiction at all between the lunar temperature and the S-B calculation. The average temperature is lowered by the swings, while the average radiation stays the same. The actual lunar temperature pattern is one of the many possible temperature variations that could give the same average radiation, 304 W/m2.
Now, here’s an oddity. The low average lunar temperature is a consequence of the size of the temperature swings. The bigger the temperature swings, the lower the average temperature. If the moon rotated faster, the swings would be smaller, and the average temperature would be warmer. If there were no swings in temperature at all and the lunar surface were somehow evenly warmed all over, the moon would be just barely below freezing. In fact, anything that reduces the variations in temperature would raise the average temperature of the moon.
One thing that could reduce the swings would be if the moon had an atmosphere, even if that atmosphere had no greenhouse gases (“GHGs”) and was perfectly transparent to infrared. In general, one effect of even a perfectly transparent atmosphere is that it transports energy from where it is warm to where it is cold. Of course, this reduces the temperature swings and differences. And that in turn would slightly warm the moon.
A second way that even a perfectly transparent GHG-free atmosphere would warm the moon is that the atmosphere adds thermal mass to the system. Because the atmosphere needs to be heated and cooled as well as the surface, this will also reduce the temperature swings, and again will slightly warm the surface in consequence. It’s not a lot of thermal mass, however, and only the lowest part has a significant diurnal temperature fluctuation. Finally, the specific heat of the atmosphere is only about a quarter that of the water. As a result of this combination of factors, this is a fairly minor effect.
Now, I want to stop here and make a very important point. These last two phenomena mean that the moon with a perfectly transparent GHG-free atmosphere would be warmer than the moon without such an atmosphere. But a transparent atmosphere could never raise the moon’s temperature above the S-B blackbody temperature of half a degree Celsius.
The proof of this is trivially simple, and is done by contradiction. Suppose a perfectly transparent atmosphere could raise the average temperature of the moon above the blackbody temperature, which is the temperature at which it emits 304 W/m2.
But the lunar surface is the only thing that can emit energy in the system, because the atmosphere is transparent and has no GHGs. So if the surface were warmer than the S-B theoretical temperature, the surface would be emitting more than 304 W/m2 to space, while only absorbing 304 W/m2, and that would make it into a perpetual motion machine. Q.E.D.
So while a perfectly transparent atmosphere with no GHGs can reduce the amount of cooling that results from temperature swings, it cannot do more than reduce the cooling. There is a physical limit to how much it can warm the planet. At a maximum, if all the temperature swings were perfectly evened out, we can only get back to S-B temperature, not above it. This means that for example, a transparent atmosphere could not be responsible for the Earth’s current temperature, because the Earth’s temperature is well above the S-B theoretical temperature of ~ -18°C.
Having gotten that far, I wanted to consider what the temperature swings of the Earth might be like without an atmosphere. Basic calculations show that with the current albedo, the Earth with no atmosphere would be at a blackbody temperature of 240 W/m2 ≈ -18°C. But how much would the rotation cool the planet?
Unfortunately, the moon rotates so slowly that it is not a good analogue to the Earth. There is one bit of lunar information we can use, however. This is how fast the moon cools after dark. In that case the moon and the Earth without atmosphere would be roughly equivalent, both simply radiating to outer space. At lunar sunset, the moon’s surface temperature shown in Figure 1 is about -60°C. Over the next 30 hours, it drops steadily at a rate of about 4°C per hour. At that point the temperature is about -180°C. From there it only cools slightly for the next two weeks, because the radiation is so low. For example, at its coolest the lunar surface is at about -191°C, and at that point it is radiating a whopping two and a half watts per square metre … and as a result the radiative cooling is very, very slow.
So … for a back of the envelope calculation, we might estimate that the Earth would cool at about the lunar rate of 4°C per hour for 12 hours. During that time, it would drop by about 50°C (90°F). During the day, it might warm about the same above the average. So, we might figure that the temperature swings on the Earth without an atmosphere might be on the order of ± 50°C. (As we would expect, actual temperature swings on Earth are much smaller, with a maximum of about ± 20-25 °C, usually in the desert regions.)
How much would this ±50° swing with no atmosphere cool the planet?
Thanks to a bit of nice math from Dr. Robert Brown (here), we know that if dT is the size of the swing in temperature above and below the average, and T is the temperature of the center of the swing, the radiation varies by 1 + 6 * (dT/T)^2. With some more math (see the appendix), this would indicate that if the amount of solar energy hitting the planet is 240 W/m2 (≈ -18°C) and the swings were ± 50°C, the average temperature would be – 33°C. Some of the warming from that chilly temperature is from the atmosphere itself, and some is from the greenhouse effect.
This in turn indicates another curiosity. I’ve always assumed that the warming from the GHGs was due solely to the direct warming effects of the radiation. But a characteristic of the greenhouse radiation (downwelling longwave radiation, also called DLR) is that it is there both day and night, and from equator to poles. Oh, there are certainly differences in radiation from different locations and times. But overall, one of the big effects of the greenhouse radiation is that it greatly reduces the temperature swings because it provides extra energy in the times and places where the solar energy is not present or is greatly reduced.
This means that the greenhouse effect warms the earth in two ways—directly, and also indirectly by reducing the temperature swings. That’s news to me, and it reminds me that the best thing about studying the climate is that there is always more for me to learn.
Finally, as the planetary system warms, each additional degree of warming comes at a greater and greater cost in terms of the energy needed to warm the planet that one degree.
Part of this effect is because the cooling radiation is rising as the fourth power of the temperature. Part of the effect is because Murphy never sleeps, so that just like with your car engine, parasitic losses (losses of sensible and latent heat from the surface) go up faster than the increase in driving energy. And lastly, there are a number of homeostatic mechanisms in the natural climate system that work together to keep the earth from overheating.
These thermostatic mechanisms include, among others,
• the daily timing and number of tropical thunderstorms.
• the fact that clouds warm the Earth in the winter and cool it in the summer.
• the El Niño/La Niña ocean energy release mechanism.
These work together with other such mechanisms to maintain the whole system stable to within about half a degree per century. This is a variation in temperature of less than 0.2%. Note that doesn’t mean less than two percent. The global average temperature has changed less than two tenths of a percent in a century, an amazing stability for such an incredibly complex system ruled by something as ethereal as clouds and water vapor … I can only ascribe that temperature stability to the existence of such multiple, overlapping, redundant thermostatic mechanisms.
As a result, while the greenhouse effect has done the heavy lifting to get the planet up to its current temperature, at the present equilibrium condition the effect of variations in forcing is counterbalanced by changes in albedo and cloud composition and energy throughput, with very little resulting change in temperature.
Best to all, full moon tonight, crisp and crystalline, I’m going outside for some moon-viewing.
O beautiful full moon! Circling the pond all night even to the end Matsuo Basho, 1644-1694
w.
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Very interesting article with many good points.
Only problem i see is that the Earth albedo is for a great part clouds and with no GHG gasses you would not have clouds. So the albedo would be much smaller hence much more energy absorbed, and the SB average temperature would be more like -5 to 0C.
There is a small difference that have big impact Willis. You write:
“But without GHGs, the only thing radiating is the surface, and the atmosphere is transparent. How can the surface possibly radiate more to space than it absorbs from the sun?”
You are right in that statement regarding the surface. But the ATMOSPHERE will be warmer than average temperature since it is heated more efficient than cooled by convection. Surface will radiate as much as before but with less temperature swing due to the heat capacity of the atmosphere. The difference is where to measure the temperature, surface or atmosphere.
Doug Cotton says:
January 9, 2012 at 3:02 pm
Thanks, Doug. Core heat provides only tenths of a watt per square metre at the surface. That’s far too small to stabilize anything. If core heat were a major player we wouldn’t have ice and snow staying on the ground, they’d melt from the bottom.
w.
John Billings says:
January 9, 2012 at 3:16 pm
John, that’s why this is what is called a “thought experiment”. I’m trying to see the various reasons why the earth stays so much warmer than its S-B temperature. Part of that is to disentangle the warming due to the atmosphere itself, from warming due to atmospheric GHGs.
w.
Genghis says: January 9, 2012 at 12:04 pm: “Let’s consider two superconducting spheres … ”
Genghis, you have some good thoughts, but you also make a couple mistakes. With the two concentric shells (separated by a vacuum), you will find that the temperature will be the same for both shells. If the outer shell could transfer energy via radiation to the inner shell and warm it up, that would violate the 2nd law of thermodynamics.
Most of the radiation from the inside of the outer shell will not hit the inner sphere, but will indeed return to some other part of the outer shell itself. If you look more carefully, I am sure you will find both surfaces do indeed radiate 100 W/m^w and are at the same temperature.
(If you add an atmosphere, then the situation could change a bit, and the inner surface could indeed be warmer than the outer shell by an amount related to the lapse rate.)
gbaikie says:
January 9, 2012 at 3:28 pm
The earth is well above the S-B temperature. You get your own opinions, but not your own facts.
w.
[I]Alexander Feht says:
January 9, 2012 at 11:43 am
P.S. Couple of people here propose a weird argument about “dead man under a blanket.” Be it known to them that plants are protected from freezing by blankets, though, last time I checked, plants had no internal sources of heat (unless you burn them). Thermal insulation is just that, an insulation — it keeps cold out even if there is no heater inside. Being a Siberian, I remember how much longer after sunset the warmer air is contained in a log cabin covered by deep snow (without any fire or people heating it yet), compared to any structure open to elements.[/I]
Some plants can insulate themselves with snow or “blankets”, but that is rare on the surface. They can come back from roots that are below the freeze line in the soil using it as a blanket. The mechanism really is about anti-freeze in the sap. Conifers have the best version of anti-freeze running in the plant family, which explains their hardiness. It is all about keeping ice crystals from damaging the cells.
Dead men don’t care and the embalming fluid might work as an anti-freeze though…
Hardly any scientists believe that the earth’s core and mantle is producing any energy, other than a modest amount of fission. Unlike a sun, no nuclear fusion can occur. However, I am aware of a theory that does claim creation of energy in planetary bodies, above and beyond any nuclear fission contribution. This theory – subquantum kinetics – has made a number of verified predictions (according to it’s author) See http://etheric.com/LaViolette/Predict2.html. The extension of a mass-luminosity curve to planets, was discovered by Laviolette, and is consistent with his theory of “genic energy”. Not mainstream science, but consider the fact that a Greek physicists says that LaViolette deserves 2 Nobel prizes for his mass-luminosity discovery, and it makes you wonder.
Lance Endersbee has shown that a 21 year moving average of Sea Surface Temperature vs. CO2 at Mauna Loa has a correlation of .9959, while a 1 year moving average is poorly correlated. Meanwhile, Nir Shaviv has shown that solar activity considered as modulated by cloud cover (a function of solar magnetic effects) correlates very well with the short term change in SST (see http://www.sciencebits.com/calorimeter).
This huge gap in timescale between Shaviv’s results and Endersbee’s 21 year moving average results is a mystery, I believe. That’s where LaViolette’s theory may come in. Although I’m not a domain expert, I will say that I don’t expect the heating that Shaviv has studied to take decades to ‘average out’ via various thermal transport processes. However, in LaViolette’s theory, a new source of energy (which he calls ‘genic energy’) is being created WITHIN planetary and solar bodies. Such heat could conceivably take years to work it’s way to the surface of the planet.
Meanwhile, subquantum kinetics has, as it’s governing equations, reaction diffusion equations such that one or more of the ‘substrates’ is electric potential. I will speculatively wonder whether or not the sun’s magnetic effects not only modulate incident radiation on the Earth, but also modulate internal genic energy production within the earth, but via the electric potential substrate which is fundamental in subquantum mechanics.
Some more info on LaViolette’s theories here: http://blog.hasslberger.com/docs/PioneerEffect.pdf . He also has a book out on the subject, now in its 3rd edition. LaViolette has a bachelor’s degree in physics, but a Ph.D. in systems theory. His father was a Ph.D. physicist, who reviewed his work.
See also “Comparison of Subquantum Kinetics to Conventional Physics and Astronomy” at http://www.etheric.com/LaVioletteBooks/SQK-c.html.
G’morning W.
Being a shift worker my responses can be sporadic.
I’ll do my best to express my view. The last time I told my late dad “but you don’t understand” I got a very solid clip across the ear with the response “then explain yourself clearly” lol
There is no “extra” energy. But there is energy “locked away” by the atmosphere unable to radiate it away.
At our hypo planet with non-GHg atmo, the highest insolation is at the equator, tapering down towards the poles.
The air nearest the surface at this point will warm, rise and spread only to be replaced by cooler air from aloft. This process continues for 14 days of daylight.
Although the surface cools at night as your post details, the atmosphere cannot cool as quickly due to the temperature inversion phenom. The air nearest the surface will cool to be the same T as the surface but this will cause it to act like a barrier against the still warm air aloft because it is more dense and cannot rise away from the surface as it did when warming.
At the next dawn the process begins again, but this time we have air aloft that is already warmer than it was 28 days ago (due to not being able to radiate) and is suplemented by further warming for the next 14 days.
The key is temperature inversion. This slows down the conductive cooling rate of the atmosphere which (I think) will accumulate heat until it is at a temperature somewhat very close to that of the surface at noon, the warmest part of the day.
The AVERAGE temperature of the SURFACE will still be much the same as that of the planet with no atmosphere as S-B dictates, but the AVERAGE temperature of the ATMOSPHERE will be much higher.
Hence my statement…
I think commentor coldlynx is saying much the same thing at 11:46am and 3:38pm jan 9th
regards
coldlynx says:
January 9, 2012 at 3:38 pm
The transparent GHG free atmosphere is warmed by conduction from the surface. Where your claim hits the reef is that since heat only flows from warmer to colder, the surface can never warm the atmosphere to be warmer than the surface is. No matter what the difference in efficiency is, the surface can only warm the atmosphere up to the temperature of the surface. Beyond that it can’t go, you can’t make heat flow uphill.
w.
One issue is the differing values for how warm or cold the Moon gets.
I’ve seen numbers saying the surface (really rocks and soil) reaches temperatures of 95C in the sunshine period and I’ve seen values of 120C.
These two different values make quite a difference in how I view the issue. If temperatures reach 120C then its temperature is hotter than it should be and its energy accumulation rate is not much different than the Earth. If it is 95C, then it is cooler than it should be and it cools off and warms up much faster than the Earth.
(Note the Earth would be very different if the rotation rate was 27 days times 24 hours. If the surface temperature accumulated energy at the same rate is does now for 13.5 days, the Earth’s surface temperature would approach 150C near the end of the 13.5 times 24 hours day and of course all the water would boil off and the Land surface would be baked so much that much gas would be liberated from it and we would be on our way to a mini-Venus affect).
Robert Brown says:
January 9, 2012 at 12:00 pm
So … for a back of the envelope calculation, we might estimate that the Earth would cool at about the lunar rate of 4°C per hour for 12 hours.
Sorry, I’m reading and commenting as I go. This is consistent with observations in the very dry, windless desert. To quote the Wikipedia article on Deserts, in hot deserts the daytime peak temperature can be 45C and the minimum temperature right before dawn can be 0C or even cooler. That is dead on your estimate, allowing for the fact that even in the desert there is stratospheric water vapor acting as a GHG to block a little of the heat — along with CO_2 of course.
Your estimate is of enormous consequence, in other words. It suggests that there is almost no greenhouse effect active over hot, dry deserts. Not CO_2 GH. Not H_2O GH. Not CH4 GH. They radiatively cool almost as fast as the dark side of the moon!
______
The estimate of 4C an hour for cooling at the surface over a desert on earth is a pretty good one, but probably not realistic for the cooling seen at the lunar surface when the sun sets. Measurements during lunar eclipses indicate peak rates of about 30C an hour or around 100C during the full length of the eclipse (around 4.5 hours). Of course desert areas are not completely devoid of all water vapor in the atmosphere as the relative humidity is just so low, and you do have the other greenhouse gases which also help to keep the desert from cooling anywhere near the rate seen on the moon. If you left the nitrogen and oxygen, but took every greenhouse gas molecule out of the atmosphere above a desert on earth, you’d certainly get cooling at greater than 4C an hour when the sunlight went away. It might not reach the 30C an hour peak rate as seen on the moon, but, it would be higher than 4C an hour, such that the high to low temperature swing would also be greater.
Willis, if you could please respond to the cogent thoughts expressed here. David says:
January 9, 2012 at 3:24 pm
Willis, for some reason you ignored most of my comment. Is it that bad??
But your statement:
“So give me Huffman’s claims in three sentences, just reading his stuff makes my head hurt. What has he said and why do you think it is important?”
Was handled wekk by nano Pope above.
To repeat the rest of my comment in slightly different, maybe more understandable?, words:
On this planet, the radiative equilibrium occurs at about 5 km above the surface, NOT AT THE SURFACE. Average T is -18 at 5 km, but it is higher at the surface. The atmosphere is not transparent on this planet or any other one, everyone agrees (that’s why your arguments about clear atmospheres are just “out there”). It can be AND IS hotter at the surface of Earth than the equilibrium radiation at 5 km above it dictates, by an amount determined by the lapse rate, which is determined ONLY by heat capacity and gravity.
We agree that that extra heat constitutes the “greenhouse effect.” What we don’t agree on is WHY it is warmer at the surface than at 5 km. I say Huffman and all the others with EMPIRICAL DATA from other planets with atmospheres (as well as some really simple observations here on Earth) trump the radiation cartoons (which, BTW, don’t accomodate your excellent explanation about why “average radiation” doesn’t mean much).
Bill Illis says:
January 9, 2012 at 4:41 pm
One issue is the differing values for how warm or cold the Moon gets.
I’ve seen numbers saying the surface (really rocks and soil) reaches temperatures of 95C in the sunshine period and I’ve seen values of 120C.
These two different values make quite a difference in how I view the issue. If temperatures reach 120C then its temperature is hotter than it should be and its energy accumulation rate is not much different than the Earth. If it is 95C, then it is cooler than it should be and it cools off and warms up much faster than the Earth.
_______
Beside the distance from the sun, which is of course the same as the earth’s distance from the sun, it is the composition of the lunar rocks and soil and their location on the surface of the moon that are the prime factors determining how warm the surface gets in any region. Heat is conducted down through the lunar soil up to several meters, mainly through conduction. Temperatures on the Moon can go as high as 130C during the lunar day and down to around -170C at night. As experiments have shown that the surface of the moon cools off at up to 30C an hour during a lunar eclipse when the sunlit sides goes into earth’s shadow, and around a 100C drop over the course of a 4 to 5 hour eclipse, we see that the lunar soils are giving up LW rather rapidly in the absence of sunlight. If we know the range of the moon’s temperature is 130C down to -170C, and it can cool at 100C in 5 hours, we see that the moon’s first few meters of rocks and soil (the depth to which heat is conducted during the lunar day) cool pretty rapidly, and the surface devoid of sunlight on the moon reaches its coldest in less than 24 hours.
R. Gates says:
January 9, 2012 at 5:26 pm
—————————
This is why I think we need to move the discussion down to the Quantum level and in time. The Moon’s rocks are accumulating energy and then giving up energy when the Sun sets at specific rates. These are far, far, far lower than what we expect compared to the radiation coming in and in the absence of solar radiation. The same is true for the temperature of the atmosphere on Earth at 2 metres high, and especially at the tropopause. The numbers are in the range of 0.01 to 0.00001 joules per second versus the Sun’s energy at 1362 joules per second. It is hard to square.
“This, in spite of the fact that satellites can measure the ocean’s surface temperature from space by measuring the very longwave radiation from the ocean that this credulous gentleman says does not exist.”
argo does that, right? i don’t think it is possible for a satellite to do that.
get out your ir radiation colormometer and see if you can possibly read the surface of some water. i tried it. you can’t because the vapor layer blocks the transmission. so what you read is a layer of vapor – not any surface, ok?
dunno why you continue to conflate a layer of ATMOSPHERE with a PLANETARY SURFACE. atmosphere is not a surface. infrared radiation is not measuring temperature of any ocean. draw the distinction.
the ocean of water is not frozen. there is no sposedta about it. the layer of atmosphere is warmed by it as well. so the model must be wrong.
kadaka (KD Knoebel): Apropos of what orbit the Moon would need to be in in order to have a 24-hour day: It would be a geostationary orbit, which is to say about 22,200 miles above the equator (26,200 miles from the Earth’s center, some 42,000 km). You can see a derivation of this in the wikipedia article for “geostationary orbit.” I suppose the fact that the Moon is so much more massive than the man-made moons currently in geostationary orbit would alter this some–presumably making the geostationary orbit slightly higher.
But the tides we’d get with the Moon in that orbit would make any sea level rise from global warming look insignificant. The tidal “force” is proportional to the cube of the distance between the two bodies. Moving the Moon from its current 239,000 miles to 22,200 miles would increase the tidal force more than 1200 times. So I think I’ll go with increasing the Moon’s speed of rotation; it may be tidally locked now, but how long would it take to become tidally locked again after having been spun up? A long time, I’m thinking, by which time maybe we can find another asteroid to spin it up. (Guess we’d need to evacuate the Moon that time.)
BTW, the idea of altering planetary orbits to solve climate change problems (or was it terraforming?) comes up in one of Jules Verne’s books, if I’m not mistaken.
Willis makes the mistake…”If you are talking about the earth, as far as I know the ground heat flux is on the order of a tenth of a watt per square metre. I’ve run the numbers myself from a couple of directions, and it’s just not all that large.”
If the difference in temperatures between the two objects is large then the conductive effect will also be large. And according to your graph the difference is around 270C. Enormous. Your assumption of the effect of a hypothetical non-GHG atmosphere is flawed on the basis you’re ignoring conduction.
The Moon receives in excess of 1200 W/sq m during the day and nothing at night. This radiation heats the surface to over 107 degrees and up to 123 degrees if you believe NASA
Given the Lunar day is some 27 Earth days the surface heats, probably quickly given how the Earth can heat over the course of a summer day, to the maximum temperature associated with the radiative flux of ~1200 W/sq m. During the long lunar night it is no wonder the temperature continues to plunge to low levels.
The tendency to reduce solar input based on geometry of spheres to an average value is nonsense !!
There is no demonstrated mechanism which validates reducing energy input to an “average” value – especially on a planetry scale – the planetry object is either illuminated and heating or not illuminated and cooling.
This rubbish of quartering the solar insolation and using this to calculate temperatures is simply wrong. All the observational evidence says so.
The Earth is fortunate – our atmosphere and oceans distribute thermal energy from equatorial and near latitudes to polar regions and the upper atmosphere.
Before the Earth has a chance to become “overcooked” because the insolation during the day is much more than 170 W/sq m on average – I estimate that at the equator it reaches a maximum of 4 times that and at 75 degrees latitude the maximum summer figure is about 170 W/sq m.
The thing that make Earth habitable are the period of our day (24 hours), the oceans and the fact that at the equator and near latitudes the surface is mostly water and our convecting atmosphere.
Surely all that matters is the relationship between the radiation from the Sun and the temperature the SB equation sayis associated with that radiation – averaging over the sphere means nothing except to tell you the average rate of energy loss to balance input.
The quarter of the insolation thingie is incorrect – I cannot understand why it persists when common sense and logic dictate there is no demonstrated mechanism how a sphere illuminated on one side and approximated by a disk can reduce the radiative flux from a distant star – this is like saying that I can reduce the radiation from my heater by keeping my back turned – which is obvious nonsense as I have a overheated front and cold kidneys.
Will says:
“The true surface of the Earth is exactly the same as it’s S-B temperature, -18º C. Also known as the effective emission height. ”
And it is BELOW that ‘true’ surface that the GHG effect creates a thermal gradient that results in the solid surface of the planet that most of us reside on being warmer than the effectived emission height.
On average… -grin-
“The earth is well above the S-B temperature. You get your own opinions, but not your own facts. ”
If Earth had a atmosphere as thin or 1/10 the atmosphere as Mars, would you still chose to measure the Earth temperature as air temperature and in the shade?
What is the planetary standard for measuring S-B temperature?
Willis : Just a heads-up, but it would appear that NASA’s page on the Lunar Thermal Environment has been updated (and by up-dated I mean completely re-written) since last Friday.
It now gives the average temperature at the Lunar Equator of 206K (-67C) which strikes me as being somewhat at odds with your quoted average planetary temperature of -77C.
http://www.diviner.ucla.edu/science.shtml
A read through of a the Unified Climate Theory thread on Tallbloke’s blog would indicate that this change was made partially at the prompting of a certain scientist with the initials “NN”
We live in interesting times…….. (:-
Will says:
January 9, 2012 at 4:23 pm
What I and others have been consistently calling the “S-B temperature” in this thread is the temperature the planet would have if it were an airless blackbody. It is the temperature calculated from the S-B equation for the amount of solar energy hitting the planet.
Do try to keep up, there’s a good fellow. And don’t get all snarky when you’re not following what’s going on. It just makes people point at you and laugh, like they’re doing now.
w.