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.
“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).”
Plants do generate heat, as does all life [including reptiles or microbes].
Though mammals generally run much hotter.
Usually “cold mistresses” are deceitful as they really are engaged in a urgent search for heat 🙂
Willis said:
“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.”
Yes, but the atmosphere is not transparent, and I don’t know anyone who says it is (looks like a straw man to me). Remember that the “S-B theoretical temperature of approx. -18 C” represents that average equilibrium radiation coming from about 5,000 KM! NOT FROM THE SURFACE AND NOT THROUGH TRANSPARENT GASES. Adjusting for lapse rate, that makes the surface about 15 C. That can be called a greenhouse effect, if one prefers to do so, but I don’t think that it is mostly due to radiation.
I don’t have near enough time to read all the comments you get and give, but to my knowledge you (or nobody else) still have not countered the points made over and over again by Harry Dale Huffman and the authors of a previous post, points that clearly demonstrate that atmospheres on planets all have positive effects on temperature and that those effects are not affected much, if at all, by the types and amounts of gases in those atmospheres.
Willis-
Thanks for another thought provoking post.
Unlike Brian H @ur momisugly January 9, 2012 at 8:31am, I loved the Haiku. Perhaps if Brian H were more widely read, he would have known that the Haiku is to the Japanese as the sonnet is to the English, and that far from being obscure, Basho is one the most famous of the Haiku poets.
Brian H says:
January 9, 2012 at 8:31 am
old engineer says:
January 9, 2012 at 1:44 pm
Brian, there were no tortured obscure haiku in my post, in fact no haiku were harmed in the writing of the post. Instead, there was a famous haiku by a world renowned poet.
Don’t like it?
Sorry, de gustibus et coloribus et cetera …
w.
Joules Verne: One of the most crucial facts to understand is that the ocean cools primarily through evaporation not radiation. If the ocean doesn’t cool by giving off longwave thermal radiation then it wont’ be warmed that way either. Therefore greenhouse gases that produce downwelling longwave radiation have little effect on the ocean.
What exactly does the downwelling longwave radiation do to the surface of the water?
jae says:
January 9, 2012 at 1:37 pm
I sincerely hope that you are kidding. Near as I can tell Huffman has added nothing but pseudo-science to the mix, unless I missed something, always possible. He did say that the amazing thermal stability of the earth is due to the mass of the atmosphere, a claim so preposterous it made my ears ring. The mass of the atmosphere allows the planet to change temperature daily by tens of degrees. How on earth could just plain mass keep the Earths temperature stable to a half degree per century? jae, you’ve got to get more skeptical here. Huffman’s claims don’t pass the laugh test.
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?
w.
“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.”
The -18 C surface is at roughly 40km above the Earth. Your assumption that the temperature calculated using the Stefan-Boltzmann and the Sun’s flux at the TOA is the temperature of the surface you happen to standing on is false.
Willis Eschenbach
“So give me Huffman’s claims in three sentences, just reading his stuff makes my head hurt. What has he said and why is it important?”
I believe Huffman is overstating his point.
But I think gravity does have an affect.
Gravity from point of view can have all the effect in this universe.
Energy is all about gravity, as in, no gravity basically no energy in this universe.
But in terms affects on greenhouse effect, I think has some effect.
But this effect isn’t quantified enough, as far as I have seen.
An obvious problem is what meant.
But keeping it simple, gravity affect how fast gas molecules would travel.
And gravity is buoyancy. No gravity- no mixing of gas/fluids.
More gravity more mixing.
So you can’t simply ignore gravity- not if you want
a complete theory.
So what is preventing the Earth from reaching 90C each day? Albedo, the shorter day, what exactly is cooling our planet?
Septic Matthew says:
January 9, 2012 at 1:54 pm
Matthew, please don’t encourage the Joules Verne type of lunacy. There is a school of thought out there that claims that longwave radiation can’t heat the ocean. They go so far as Joules Verne, who makes the further idiotic claim that the ocean
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.
Not one of those folks can answer a simple question: where does the energy come from to keep the ocean liquid, if not from the downwelling infrared energy from the GHGs?
There’s nowhere near enough solar energy hitting the ocean to keep the ocean from freezing. Global average solar radiation hitting the surface is only about 170 W/m2. We know the global average upwelling longwave radiation from the surface is about 390 W/m2, and solar only contributes about 170 W/m2 … so what is providing the rest of the energy needed to keep the ocean from freezing? Not one advocate of that crazy idea (that the ocean can’t absorb infrared) can answer that question.
In the face of such willful blindness, any response is a bad idea. Or as they say, DFFT … don’t feed the trolls. This thread is not about oceanic IR absorption, and I don’t want to get lost in that swamp again.
w.
Physics demands, requires and wants equilibrium. That means that the heated side of the moon, once in the shade, will expend its heat until it is the same temperature as the body around it ie. space, ie. about 3 degrees Kelvin. These laws are universal across the whole… universe. The moon has no internal source of heat to disrupt this.
The Earth is incomparable for a variety of reasons. It has internal heat, it has an atmosphere that acts a a restraint on both ends of the scale, and it has oceans that are a ‘dampener’ on heat – oceans take far longer to warm up and cool down than land does.
So I really don’t see where this well-meaning article is trying to take us. The moon and earth are fundamentally different. They cannot be compared. The moon is a cold rock that will forever be trying to radiate its excess sunny side heat into space according to the laws of physics so that everything is the same, with no impediment provided by atmosphere, oceans etc. End of story.
Oh, and Harry Dale Huffman isn’t the one claiming heating by atmospheric mass, that sounds like Nikolov Zeller. Harry emphatically states that is wrong (perpetual motion like) in the link below, and also sums up his argument fairly succinctly. You asked for three sentences though, so here’s three from that comment.
“Keeping it simple, the atmospheres must be like sponges, or empty bowls, with the same structure (hydrostatic lapse rate), filled with energy by the incident solar radiation to their capacity to hold that energy. In short, compressing the lower atmosphere doesn’t heat it, it merely allows it to retain more heat energy per volume than the lower-pressure levels above. All of the energy is provided by the Sun. The pressure distribution simply dictates vertical temperature distribution, which constitutes the structure, or energy-retaining form, of the “bowl” I likened the atmosphere to.”
http://theendofthemystery.blogspot.com.au/2010/11/venus-no-greenhouse-effect.html?showComment=1325125898177#c5729196180038388134
gbaikie says:
January 9, 2012 at 2:14 pm (Edit)
Could someone please translate this for me? That’s worse than Huffman himself. There is no substance in there, nothing to measure, nothing to grab ahold of. Yes, we can’t ignore gravity … so? Where’s the meat in this sandwich?
There are a lot of people out there who handwave about how by some mysterious mechanism, a perfectly transparent, GHG free atmosphere can warm the planet above it’s S-B temperature. Can’t happen. Violates the Laws of Thermodynamics. Their claim is that by their magic method you could end up with a surface that radiates more than it absorbs. No way for that to occur, that’s perpetual motion.
Notice that none of them can explain the exact mechanism by which it’s supposed to occur. Oh, they’ll repeat the word “gravity” lots of times, and talk a lot about lapse rates and the like. 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? No way! Sheesh, this isn’t rocket science.
There is nothing mysterious about the greenhouse effect. I don’t understand why people think it’s not real. Read my posts “The Steel Greenhouse” and its sequel, “People Living In Glass Planets“. A planetary greenhouse doesn’t require GHGs or an atmosphere, you can build the whole thing out of steel.
w.
The main difference between Earth and Moon is the core heat. The amount of thermal energy under the surface of the Earth (ie down to the core) is several orders of magnitude greater than that in the oceans, let alone the atmosphere. This has a stabilising effect on Earth’s temperatures, especially between day and night and between summer and winter. I have explained this in far more detail on this page of my site: http://climate-change-theory.com/explanation.html
Willis,
Not that you need my help, but I agree with pretty much 100% of what you have said here. I haven’t had time to read every word carefully in the thread, but everything I have read from you seems spot on.
Willis: 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.
Thank you for the response.
“nano pope says:
January 9, 2012 at 2:19 pm
So what is preventing the Earth from reaching 90C each day? Albedo, the shorter day, what exactly is cooling our planet?”
Might start with what is warming our planet.
The sun has a max heat at your distance from it.
The moon at same distance can reach more than 90 C.
One way say it is moon has 1360 watts per square meter of sunlight.
And earth below our atmosphere has about 1000 watts per square meter.
Moon reaches a surface temperature of about 123 C
The earth reach a surface temperature of about 180 F [ 82 C]
Convert 123 and 82 into Kelvin:
396 K and 355 K
cube 396 times it by .0000000567
and get 1394 watts per square meter of sunlight.
cube 355 K times it by .0000000567
And get 900 watts per sq meter.
Earth get more than 900 watts, but air convection takes heat away from surface.
And if you wonder why I say earth can get to 82 C, I am talking about surface
temperature not air temperature in the shade- which how we measure temperature
on earth.
90 C or 363 K
is 987.4 watts per square. If stop most of the air convection losses, you should
be able to get 90 C on the earth surface at noon and a clear sky. higher elevation
should make this easier.
The other element is earth radiate heat gained into space.
So what stops us from getting 90 C air temperature?
Well that would generally mean the surface temperature was as hot or
hotter, and therefore the whole planet would radiating roughly 4 times as much energy
as it got from the sun. It can radiate the same energy as it received from the
sun.
So on small scale if limit conviction and conduction of heat during noon on clear day
you get 90 C. But it’s not noon everywhere nor is it daylight.
In other words the heat is spread out. And though it might possible to get 90 C
not possible on earth to get 120 C from sunlight regardless of how stop heat loss-
need more solar power per square meter [not have 300 or so watts blocked by
our atmosphere].
You can’t have a GHG-free atmosphere, not on Earth anyway. CO2 is a GHG and is a natural component of all that goes on, given off by plants in the dark. Likewise methane, naturally emitted by decomposition.
Sorry if I am repeating other’s points, I don’t have time to read them all.
1) thank you for demonstrating why it is STUPID to compute an average temperature of the earth by dividing the incoming energy over the whole surface. Can we throw out the ridiculous comparison between a bare ball and the earth as we know it now??
2) emissivity is also important. The earth has a much lower emissivity due to the atmosphere, about .7-.8 including the earth underneath it!!!
3) you totally ignored conductivity and thermal mass of the totally transparent atmosphere. Effect will be low admittedly, but will still be there. you also completely ignored the the thermal flows in the surface.
4) I believe vacuum is a great insulator don’t you?? On the moon we have large areas convered by dust and VACUUM!!! That’s right, there is no air to fill the spaces in the dust particles so we end up with a very nice INSULATOR compared to the ground down here!!
5) Sloppy.
Willis Eschenbach says:
January 9, 2012 at 10:30 am
David says:
January 9, 2012 at 5:10 am
Willis says…
”As a result, while the greenhouse effect has done the heavy lifting to get the planet up to its current temperature,…”
How much of the GHE on earth is actually due to the oceans where the residence time of energy is far far longer then any GHG?
None, as I understand the greenhouse effect.
——————————————————————————————————–
Willis, please understand that of course I do not literally mean GHE, when I refer to the oceans; except in the context of thermal capacity. At its most basic only two things can effect the energy content of any system in a radiative balance. Either a change in the input, or a change in the “residence time” of some aspect of those energies within the system. (You may henceforth refer to this as David’s law. (-;) There is a fairly exact correlation between residence time of energy and thermal capacity. As the ocean thermal capacity is thosands of times that of the atmosphere, it appears logical that it is a more effective GHLiquid, then any GHG; your thoughts in this regard are welcome aand requested.
Also, although the average albedo of earth is higher then the moon’s, is it higher at laditudes where TSI is stongest?
Willis responds…”The earth albedo varies by location, by time of day, and by time of year, so it’s hard to answer your question. Where the TSI is the strongest (tropics) the albedo is part of the dynamic system keeping the earth from overheating, This means albedo also varies by temperature. It is higher where the temperature is highest, which in turn is where the TSI is greatest, so the answer to your question is generally yes, at least in the tropics.” W. ———————————————————-
At first glance this does not appear logical to me. In general the oceans are a blackbody, absorbing whatever radiation reaches the surface with little reflectivity. The NH has a great deal of landmass north of the tropics, as well as year round snow and ice in the artic, antarctic as well as tremendous winter albedo beyond year round ice. Additionally the incident angle of sunligh creates ever greater reflectance as one moves further from the tropics. A further factor is the poles appear to have a great deal of consistent.cloud cover as I look at the global map on the right side of WUWT home page. For these reasons I would have to see actual meauserment to accept your assertion here, as I suspect that the tropics. especially the southern tropics have the lowest albedo as well as the greatest TSI, especially in January when the earth is thee million miles closer to the sun and TSI is close to 100 W/m2 greater then in July. Your thought here are appeciated as well.
clivebest had the basic idea for feedbacks, but got them backwards. Current albedo is 0.3
so we get (1- 0.3)* 342 watts =239.4 watts. With a sun 70% as luminous as at present, and with a surface covered with oceans and no clouds, we would have received
0.7 (sun)* 1 (no clouds)* 324 watts, same as now. albedo wasn’t 0.45 back then, it was closer to zero.
Alan – that’s right. Albedo reduces for lower incident radiation . As the Earth’s ocean surfaces get heated, the Earth starts to “swet” – producing clouds which reduces the Albedo. The second assumed mechanism at work is that the H2O greenhouse effect increases at lower solar radiation levels ( by higher humidity in upper atmosphere). As more convection clouds form – this leads to more rain out from the atmosphere and a drop in upper atmosphere humidity.
The overall idea is that there is a balance point which is a play-off between the two effects Albedo and GHG. Water covered planets have an infinite sink of water available to maintain this balance over a wide range of solar radiative forcing levels. This has nothing to do with CO2 which is assumed to be absent in the atmosphere.
Is the reference value of 0.11 a visible spatial average or full spectrum, spatial average?
“GHG free atmosphere can warm the planet above it’s S-B temperature. Can’t happen. Violates the Laws of Thermodynamics. ”
Well, I am not convince any atmosphere, roughly with 1 atm with any quantity of greenhouse gases can warm above it’s S-B temperature. You are apparently assuming this could occur.
I am not.
And don’t think Huffman idea can do this either.
Or anything can do this.
Unless warming include huge asteroid strikes or huge, huge super volcano. Supernovas, and huge solar output, also might work.
Great post Willis. I really enjoy reading all your articles.
I’d like to take the no GHG atmosphere thought experiment a bit further. Since the atmosphere cannot radiate, it can only exchange heat with the surface. Eventually the upper atmosphere would warm through conduction. The lapse rate would be near zero which would shut down any vertical convective heat transport since the warming/cooling due to adiabatic expansion would almost instantly kill any vertical motion. It would be the ultimate in super stable atmospheres. There would be no Hadley cells to transport heat from the equator to the poles. There could be some horizontal transport due to surface temperature differences (day – night and equator – pole) but I would guess that they would be very weak without any vertical motion to drive it. I imagine that the atmosphere, particularly up high would have a very uniform temperature over the entire globe.
Is it the green house gases that give us our weather? With GHG back into our thought experiment atmosphere, there is cooling of the upper atmosphere due to outgoing long wave radiation. This give rise to a vertical temperature gradient (lapse rate) which can drive convective transport. I believe convective transport is the source of almost all of our weather.
As a paraglider pilot who likes good thermals, I certainly appreciate green house gases!
Regards
Peter Spear