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.
Replay to Kevin-UK
The only reason that I have commented on the article by Willis is that I have great respect for the blog site and have found some great articles by the specialists in their own fields. However, the field of radiation and heat balance is so complex that it really should not be open to ‘let us all join in for our thoughts’. The topics of that nature can only be properly addressed in the scientific journals, and believe me, there are lot of journals there that have not been ‘contaminated’ by the proponents of imaginary global warming. I would highly recommend to type in Google scholar names “Gerhard Kramm and Ralph Dlugi” published in Natural Sciences in 2011, which will give you a free PDF file to read. Also, I believe that Alan Siddons has contributed in the past to this blog site – that is the guy who knows this area – check the archives or Google his name. Since it seems that Willis did some reading on the topic, I think that he would contribute much more by summarising what the separate chapters in the book were saying about greenhouse gasses, rather than to venture into this field with his own ideas.
As to the major discovery that I was part of, it did drastically improve the quality of life of millions of people in the last 20 years, since this was the first effective drug for treatment of migraine. Just ask any migraine sufferer how miserable life can be. Since drug discovery is one of the most regulated sectors, each country has its own independent regulatory bodies, one in US is called FDA, and they use their own experts in field of biology, chemistry, toxicology and statistics and check all the original data that the company has produced in ten years of the research. That is the normal way that all experimentally based sciences, outside the so called ‘climate sciences’ operate.
Darko Butina, UK
ferd berple says:
January 9, 2012 at 1:49 am
Thanks, ferd. This why I said that the very close correspondence between theoretical and observed was likely in part coincidental, because there are other temperature differences. In addition to the day/night temperature differences you have the difference between the equator and the poles. However, on the moon at least, I think that they are small enough to be ignored in a first cut. Let me give you my reasoning, you tell me what you think.
• The lunar surface warms quite rapidly as soon as the sun rises, up to about 0°C. Above that temperature the warming proceeds much more slowly, and in line with the changing strength of the sun. This implies that unlike the earth, the surface roughness of the moon means that low solar angles above the horizon are no impediment to rapid warming.
• The results of the equatorial-polar difference need to be area-averaged. This greatly reduces the effect of the lowest (polar) temperatures on the average, since they represent such a small percentage of the surface area. The amount of sunlight falling on an area decreases with the cosine of the latitude. But the surface area is also falling by cos(lat), so the effect is greatly reduced from what might be expected at first glance.
Cold indeed … but bear in mind that these represent a very, very tiny fraction of the lunar surface.
My conclusion? More funds are needed to send me to the moon to take some more temperatures … “Someday, Alice … to the moon …”
My regards,
w.
Bill Illis says:
January 9, 2012 at 5:45 am
“The darkside of the Moon does receive reflected sunlight and thermal radiation from the Earth.”
I believe you mean the nearside. When the darkside is also farside, it of course does not receive radiation from the Earth. That said, a 32K increase in nearside night temperatures is highly significant, since it is close to the 43K temperature measured in the lunar polar and other areas that exist in permanent shadow. Next step: to see whether the farside has even cooler minimum temperatures in permanent shadow.
Kasuha says:
January 9, 2012 at 2:07 am
Not true. As happens on the earth, since the atmosphere actually touches the planet’s surface, heat is transferred by conduction.
w.
clivehbest says:
January 9, 2012 at 2:15 am
Very interesting, Clive, thanks. There’s another subtle effect that I always called the “moon breeze” but is more properly termed the “terminator wind”. This is a wind that accompanies the leading edge of the moonlight (the “terminator” between light and dark). Because the lighted side is warmer, a gentle breeze blows from cold to warm across the terminator. One of my favorite winds.
w.
Willis, the flat world model that is used to calculate the average does not make sense. As you correctly say the radiation changes with the 4th power of the temperature, so temperature cannot be averaged in a linear dependency, it does not make sense.
If we would have a planet with 50°K on the sunny side and 10°K on the dark side the averaged temperature would be 30°K which is not what the planet radiates.
The total radiation would be:
sigma*50**4+sigma*10**4=2*sigma*Taverage**4
If we compute the temperature of equivalent radiation will result 42°K. So 42 is the average temperature between 10 and 50 in terms of equivalent radiation (btw. “Answer to the Ultimate Question of Life, the Universe, and Everything is 42”) .
The same for the moon, if the sunny side is 60°C (333°K sic) and the cold side -175°C (98°K) the equivalent radiation temperature is 280°K which is +7°C
So the model where the sun’s radiation is divided through 4 and spread over the whole earth is leading to wrong results.
Averaging temperature as an arithmetic mean is leading to nowhere – it is a fictive value of no physical meaning.
Thanks for the posting, let me know if you see things differently or I got my calculations wrong.
Baa Humbug says:
January 9, 2012 at 2:19 am
Thanks, Baa. The moon is only eclipsed by the earth for a few hours, not days. Bear in mind that a solar eclipse from the moon is the same as a lunar eclipse from the earth … If you look at the underlying data in the cite given under Fig. 1, it shows the thermal record of such an eclipse.
I don’t understand how this idea is supposed to work. How will the atmosphere get warmer on average than the surface? Where will the energy come from to maintain it at a warmer temperature than the surface? Why will it not warm the surface, if it is warmer than the surface?
All the best,
w.
markus says:
January 9, 2012 at 2:58 am
For the purposes of first-order calculations such as we are doing here, AFAIK the answer is yes.
w.
Stephen Wilde says:
January 9, 2012 at 3:23 am
Because gravity doesn’t add energy to the atmosphere on an ongoing basis.
w.
Honorable says:
If daylight on earth lasted 14.5 days, instead of 12 hours, there would be huge temperature swings on earth that I would like someone to calculate.
Similarly, if daylight on the moon lasted 12 hours instead of 14.5 days, temperature swings on the moon would be much smaller.
The different lengths of a day on the moon and on the earth probably account for more of the temperature swings than the presence or not of an atmosphere. How much more? Could someone tell me?
—————-
Both poles are without sun for much more than 14 days and yet the temperature does not drop to anywhere near the level on the dark side of the moon. This is mainly due to the movement of warm air from the tropics which maintains the tropopause at about 200K. The existence of this relatively stable layer of the atmosphere quite close to the ice surface (it is only about 6500 metres at the poles and the ice surface is close to this height in many places) means that further cooling is not possible. So if you are asking for a calculation for the earth as it is with an atmosphere then this is an indication of what you might get. Contrary to your guess the atmosphere is the main determinant of temperature swings but the actual calculation which would have to model air flows in response to a 14 day cycle is beyond my ability and (I would suggest) a bit pointless.
Very interesting post. A few points though, what impact does the ocean have on night time cooling rates, surely it would change the earths behaviour from the moons. Secondly, how would the albedo change without cloud cover in a clear atmosphere, surely the earth would obsorb more energy and thus have a higher average temperature. Also, the earth constantly emits heat as its core cools – I a negligiable affect day to day for us, but how signficant does it become in a clear atmosphere i.e. does it determine a minimum surface temperature at night (for example higher than the moons as its cold through) which increases the average? Just some thoughts, all things that people should already have assessed before they got all hung up on co2!
Diurnal change in temperature, convection of heat and the earths thermal mass has been something that should be considered for a long time but often neglected when considering the earths climate. In climate models I understand convection is a secondary calculation after the heat trapping of GHG’s and therefore all of the warming affect is applied to GHG’s and their affect is overstated as a result.
“The surface of the Moon is colder than the surface (and lower layer of the atmosphere) of the Earth for the same reason a man without a blanket, during a cold night, is colder than a man under a blanket. ”
A man is engine creating 100 watts- in one hour: 360,000 watts.
A dead man isn’t going to be kept warm with a blanket.
gnomish says:
January 9, 2012 at 3:43 am
Thanks, gnomish, glad someone noticed.
You’re not following the reasoning. The reason the temperature average changes is that the radiation is proportional to T^4, and radiation (energy) is conserved, while temperature is not conserved. As a result, we can have different temperature averages which all have the same average radiation.
w.
Willis,
As ever an excellent and interesting post, taking a different look at things.
Your approach here may solve a different question, the Faint Early Sun Paradox. You discussed this in your previous post on the thunderstorm thermostat http://wattsupwiththat.com/2009/06/14/the-thermostat-hypothesis/ in which you summarise the question as:
“In contrast to Earth’s temperature stability, solar physics has long indicated (Gough, 1981; Bahcall et al., 2001) that 4 billion years ago the total solar irradiance was about three quarters of the current value. In early geological times, however, the earth was not correspondingly cooler. Temperature proxies such as deuterium/hydrogen ratios and 16O/18O ratios show no sign of a 30% warming of the earth over this time. Why didn’t the earth warm as the sun warmed?”
Following the approach of this post, it is not the temperature that needed to warm 30% over 4 billion years, but the average radiation, which would need to rise from about 180 W/m2 to 240 W/m2. Or via Stefan Boltzmann from about -36C to -18C.
The length of day 4 billion years ago was around 7 hours ( http://www.ptep-online.com/index_files/2009/PP-16-02.PDF) rather than 24, so with only 3.5 hours warming and 3.5 hours cooling, the diurnal range would be perhaps only around quarter that at present. So cutting 3/4 of the cooling effects of temperature swings form the ancient Earth means that it would have around 12C less ‘swing cooling’ than we’ve got today. So it would be around -24C rather than -36C.
So given a 30% dimmer sun, the ancient earth is about -24C rather than -18C today before atmospheric effects. Nothing too paradoxical about that.
Yes – This must be one key factor in resolving the Faint Sun paradox. The negative “climate feedback” from BB radiation is highly temperature asymmetric to any change in radiation DS. So DT =DS/(4*sigma*T^3). Changes to surface radiation are mostly due to 3 things – 1) Solar radiation 2) Albedo 3) Greenhouse gases. The unique feature of the Earth is that it is 70% covered by liquid water which acts to regulate the greenhouse effect AND changes Albedo through cloud formation. There is geological evidence of liquid oceans on Earth 4 billion years ago when the sun was 30% less bright. This can only be possible if somehow the Earth self-regulates its temperature through water. One simple modle of how this could occur for “water worlds” like Earth is the following.
Let’s assume that there are simple relationships both for low clouds and net greenhouse effects upon incident solar energy. Defining x = S0/342 as the normalized solar flux on a Water World relative to that incident on Earth today and taking albedo of water as 0.1 we make the following (arbitrary) assumptions.
1. Low Cloud Cover is assumed to be driven through evaporation only by solar heating: Total cloud cover (CC) is assumed to be CC = 0.4*x. The albedo for low convection clouds is taken simply as 0.5 so. This results in a planet albedo which varies as 0.1+0.2*x. This value is chosen so that the planet albedo today is 0.3 (about the same as that on Earth).
2. The net total normalised greenhouse effect g is assumed to depend inversely on x. Water evaporation and high clouds at low x yield a high g value which the decreases as higher forcing drives evaporation leading to a lower lapse rate and more direct latent heat loss to the upper atmosphere. Today g is 0.3 and the (arbitrary) proposal is that g depends inversely on increasing x so g= 0.3/x. Therefore would therefore imply that 4 billion years ago g was 0.45.
Then the global Energy balance is simply:
(0.9-0.2x)S0 = SU(1.0-0.3/x), where S0(now) is 342 watts/m2
–> SU = ((0.9-0.2x)x*342)/(1-0.3/X)
–> Tsurf(x) = T(now)*4th root(SU(x)/SU(now))
The result of this simulation can be seen here
The objective of all this is just to show HOW a water covered planet could self regulate its temperature, and it also has something to say about climate feedbacks. IPCC GCM models assume net positive feedbacks with radiative forcing. They all average around 2 watts/m2/degC If such feedbacks are assumed to be true then the Earth would have boiled off its oceans long ago as solar radiation increased by 30%. Even more contradictory is working backwards from current average global temperature of 288K
We fix the current temperature to be the observed 288K and work backwards by subtracting DT from solar forcing every million years. It is here that we see the basic problem of assuming linear positive feedback. If the temperature falls enough so that 4sigmaT^3 = F then we get a singularity. (a href=”http://clivebest.com/blog/wp-content/uploads/2011/09/hindcast.png”>You can see this calculation here.
In the context of this simple model positive feedbacks would appear to be ruled out.
Willis says: 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.
I know what you mean, but have to take issue with the terminology. GHG never provides “extra energy”, it might act as a reservoir of energy and *return* some of that energy.
On a planetary scale, even this effect is liable to be small. The thermal (energy) capacity of gas is very low compared to rock, so even if you were to take the energy accumulated in the entire atmosphere and apply it to the surface of a planet the effect would be small (and one-time … at least until it had heated up again.
As for energy transfer, from warm areas to cold, if we think about a non GH gas, the only way it can be warmed is through conduction — contact with the planetary surface (since by definition radiation passes straight through it). This is going to limit how fast the gas can acquire energy, and since the same applies to it delivering energy (physical contact and conduction) the effect is going to be small.
Then consider the volume of gas required (GH or not) to make any significant difference, and the fact that you would need a constant supply of warm gas making contact with the ground, and the velocity of the winds required to distribute sufficient energy to make a significant difference by this mechanism.
David says:
January 9, 2012 at 5:10 am
None, as I understand the greenhouse effect.
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.
“ferd berple says:
January 9, 2012 at 1:49 am
Willis, did your calculations take into account the temperature difference between the equator and the poles? From looking at Figure 1, if you used that for your data it will not give an accurate result because it reflects an average of temperature between the equator and poles. The temperature difference between the lunar equator and poles is greater than between night and day averages.
“Most notable are the measurements of extremely cold temperatures within the permanently shadowed regions of large polar impact craters in the south polar region,” said David Paige, Diviner’s principal investigator and a UCLA professor of planetary science. “Diviner has recorded minimum daytime brightness temperatures in portions of these craters of less than -397 degrees Fahrenheit. These super-cold brightness temperatures are, to our knowledge, among the lowest that have been measured anywhere in the solar system, including the surface of Pluto.” ”
This referring to permanent shadowed craters, which can get to 20 K.
But you correct there is average surface temperature difference as you go poleward,
a difference is not as extreme. But very significant.
Harry Dale Huffman says:
January 9, 2012 at 6:22 am
Your claim is that the temperature stability of the earth is due to the weight of the atmosphere itself … riiiight … yet another universe heard from.
w.
gbaikie says:
January 9, 2012 at 10:22 am
A dead man isn’t going to be kept warm with a blanket.
______
Actually, that depends on how long he’s been dead. The decomposition of a body can generate a lot of heat, and wrapping that dead body in a blanket certainly alters the rate at which the decomposing body loses heat. This doesn’t even take into account the added activity of the maggots etc. that will want to have a nice meal and generate even more heat under that blanket.
But in comparing the Moon as a “dead” body and the Earth as a “living” body, it certainly is true that the Moon generates far less (but not zero) LW radiation than does the Earth, and furthermore, most don’t realize that the Earth’s surface generates more LW energy than it absorbs in SW energy.
Cathy says:
January 9, 2012 at 7:24 am
Thanks, Cathy. Whenever I can discuss a question without math I do so, because I figure each equation in my post loses me about 10% of the readers. So I’m working on it … but some topics, like this one, you can’t even begin to approach without math.
All the best,
w.
darkobutina says:
January 9, 2012 at 7:58 am
Advice to Darko:
1. Your credentials are of no interest to me, only your words, and your words are both personally nasty and scientifically meaningless.
2. You have not quoted a single claim that I made that you think is wrong. In fact, you have not even contradicted a thing I said … yet you claim that I am wrong. This is a very cowardly approach, but more to the point, it is unscientific. If you have a scientific objection, break it out, because up ’til now, you’re just breaking wind.
Darko, you seem to want me to write a critique of some book that I have never read … why is it that educated fools like yourself think you are qualified to tell other people what they should write about?
I write about what interests me. If you think I’m wrong, then at least have the balls to quote my words that you think are in error and tell us what you think is wrong.
And if you are just going to whine, as in your post above, Darko, then go away and whine someplace else. Don’t go away mad. Just go away. I neither need nor like whiners.
w.
“Kasuha says:
January 9, 2012 at 2:07 am
I have three points.
– IR radiation is the only way how surface temperature is transferred from solid surface to atmosphere. If a moon had atmosphere that is perfectly transparent to IR, that atmosphere would do nothing with its surface temperature.”
The air would warmed from hot surface. Any simple gas wall heater [no fans] shows that.
[Hot poisonous gas heats an heat exchange before being vented and warmed
metal {heat exchanger} heats the air in the room]
“- Earth albedo of 0.3 is partially given by clouds and other atmospheric effects. You can’t simply imagine Earth without atmosphere but having the same albedo.”
Whatever.
“- Albedo of a solid body affects not only its absorption of incoming radiation but also its release of outgoing radiation. It’s not correct to assume Earth absorbs energy according to its albedo and then cools down as fast as Moon does.”
Any heated surface regardless of color will radiate same amount of heat [roughly].
A. C. Osborn says:
January 9, 2012 at 8:40 am
Isn’t it great how the GHGs prevent such wide swings in temperature as experienced by the moon, except of course in deserts, where it doesn’t do a very good job.
I wonder why that is?
Because the most powerful green house gas is water vapor, and the relative absence of water and water vapor is exactly what makes a desert.
“* The moon hides behind the earth for a few days each cycle (is it 7 days?) where it receives no insolation at all. All emission no absorption. Is this reflected in the first graph, if so where?”
The Moon’s day and orbit around earth about 28 days. [It’s tidal locked- always has one side facing the Earth].
The Moon orbit is such that not all orbits cross earth’s shadow. Nor does the Moon’s shadow
blocks the sun on earth with every orbit [fairly rare].
Related: during lunar eclipse
http://www.diviner.ucla.edu/blog/?p=610
Measures cooling of surface when earth is blocking the sunlight.
@cal: I get your point but poles might not be such good examples to the extent that when it is day, it is the equivalent of a permanent sunrise (i.e. the sun does not do so much warming). What would happen at the equator if days lasted 14.5 days followed by an equally long night. I would not be surprised if temperature would rise to 60 degrees, but that is a pure guess.
Finally, your interesting pole argument does not clarify what would happen on the moon if days lasted 12 hours instead of 29 times longer.