Guest Post by Willis Eschenbach
I’ve been reflecting over the last few days about how the climate system of the earth functions as a giant natural heat engine. A “heat engine”, whether natural or man-made, is a mechanism that converts heat into mechanical energy of some kind. In the case of the climate system, the heat of the sun is converted into the mechanical energy of the ocean and the atmosphere. The seawater and atmosphere are what are called the “working fluids” of the heat engine. The movement of the air and the seawater transports an almost unimaginably large amount of heat from the tropics to the poles. Now, none of the above are new ideas, or are original with me. I simply got to wondering about what the CERES data could show regarding the poleward transport of that energy by the climate heat engine. Figure 1 gives that result:
Figure 1. Exports of energy from the tropics, in W/m2, averaged over the exporting area. The figures show the net of the energy entering and leaving the TOA above each 1°x1° gridcell. It is calculated from the CERES data as solar minus upwelling radiation (longwave + shortwave). Of course, if more energy is constantly entering a TOA gridcell than is leaving it, that energy must be being exported horizontally. The average amount exported from between the two light blue bands is 44 W/m2 (amount exported / exporting area).
We can see some interesting aspects of the climate heat engine in this graph.
First, like all heat engines, the climate heat engine doesn’t work off of a temperature. It works off of a temperature difference. A heat engine needs both a hot end and a cold end. After the working fluid is heated at the hot end, and the engine has extracted work from incoming energy, the remaining heat must be rejected from the working fluid. To do this, the working fluid must be moved to some location where the temperature is lower than at the hot end of the engine.
As a result, there is a constant flow of energy across the blue line. In part this is because at the poles, so little energy is coming from the sun. Over Antarctica and the Arctic ocean, the sun is only providing about a quarter of the radiated longwave energy, only about 40 W/m2, with the remainder being energy exported from the tropics. The energy is transported by the two working fluids, seawater and air. In total, the CERES data shows that there is a constant energy flux across those blue lines of about six petawatts (6e+15 watts) flowing northwards, and six petawatts flowing southwards for a total of twelve petawatts. And how much energy is twelve petawatts when it’s at home?
Well … at present all of humanity consumes about fifteen terawatts (15e+12) on a global average basis. This means that the amount of energy constantly flowing from the equator to the poles is about eight-hundred times the total energy utilized by humans … as I said, it’s an almost unimaginable amount of energy. Not only that, but that 12 petawatts is only 10% of the 120 petawatts of solar energy that is constantly being absorbed by the climate system.
Next, over the land, the area which is importing energy is much closer to the equator than over the sea. I assume this is because of the huge heat capacity of the ocean, and its consequent ability to transport the heat further polewards.
Next, overall the ocean is receiving more energy than it radiates, so it is exporting energy … and the land is radiating more than it receives, so it is getting energy from the ocean. In part, this is because of the difference in solar heating. Figure 2, which looks much like Figure 1, shows the net amount of solar radiation absorbed by the climate system. I do love investigating this stuff, there’s so much to learn. For example, I was unaware that the land, on average, receives about 40 W/m2 less energy from the sun than does the ocean, as is shown in Figure 2.
(Daedalus, of course, would not let this opportunity pass without pointing out that this means we could easily control the planet’s temperature by the simple expedient of increasing the amount of land. For each square metre of land added, we get 40 W/m2 less absorbed energy over that square metre, which is about ten doublings of CO2. And the amount would be perhaps double that in tropical waters. So Daedalus calculates that if we make land by filling in shallow tropical oceans equal to say a mere 5% of the planet, it would avoid an amount of downwelling radiation equal to a doubling of CO2. The best part of Daedalus’s plan is his slogan, “We have to pave the planet to save the planet” … but I digress).
Figure 2. Net solar energy entering the climate system, in watts per square metre (W/m2). Annual averages.
You can see the wide range in the amount of sunlight hitting the earth, from a low of 48 W/m2 at the poles to a high of 365 W/m2 in parts of the tropics.
Now, I bring up these two Figures to highlight the concept of the climate system as a huge natural heat engine. As with all heat engines, energy enters at the hot end, in this case the tropics. It is converted into mechanical motion of seawater and air, which transports the excess heat to the poles where it is radiated to space.
Now, the way that we control the output of a heat engine is by using something called a “throttle”. A throttle controls the amount of energy entering a heat engine. A throttle is what is controlled by the gas pedal in a car. As the name suggests, a throttle restricts the energy entering the system. As a result, the throttle controls the operating parameters (temperature, work produced, etc.) of the heat engine.
So the question naturally arises … in the climate heat engine, what functions as the throttle? The answer, of course, is the clouds. They restrict the amount of energy entering the system. And where is the most advantageous place to throttle the heat engine shown in Figure 2? Well, you have to do it at the hot end where the energy enters the system. And you’d want to do it near the equator, where you can choke off the most energy.
In practice, a large amount of this throttling occurs at the Inter-Tropical Convergence Zone (ITCZ). As the name suggests, this is where the two separately circulating hemispheric air masses interact. On average this is north of the equator in the Pacific and Atlantic, and south of the equator in the Indian Ocean. The ITCZ is revealed most clearly by Figure 3, which shows how much sunlight the planet is reflecting.
Figure 3. Total reflected solar radiation. Areas of low reflection are shown in red, because the low reflection leads to increased solar heating. The average ITCZ can be seen as the yellow/green areas just above the Equator in the Atlantic and Pacific, and just below the Equator in the Indian Ocean.
In Figure 3, we can see how the ITCZ clouds are throttling the incoming solar energy. Were it not for the clouds, the tropical oceans in that area would reflect less than 80 W/m2 (as we see in the red areas outlined above and below the ITCZ) and the oceans would be much warmer. By throttling the incoming sunshine, areas near the Equator end up much cooler than they would be otherwise.
Now … all of the above has been done with averages. But the clouds don’t form based on average conditions. They form based only and solely on current conditions. And the nature of the tropical clouds is that generally, the clouds don’t form in the mornings, when the sea surface is cool from its nocturnal overturning.
Instead, the clouds form after the ocean has warmed up to some critical temperature. Once it passes that point, and generally over a period of less than an hour, a fully-developed cumulus cloud layer emerges. The emergence is threshold based. The important thing to note about this process is that the critical threshold at which the clouds form is based on temperature and the physics of air, wind and water. The threshold is not based on CO2. It is not a function of instantaneous forcing. The threshold is based on temperature and pressure and the physics of the immediate situation.
This means that the tropical clouds emerge earlier when the morning is warmer than usual. And when the morning is cooler, the cumulus emerge later or not at all. So if on average there is a bit more forcing, from solar cycles or changes in CO2 or excess water vapor in the air, the clouds form earlier, and the excess forcing is neatly counteracted.
Now, if my hypothesis is correct, then we should be able to find evidence for this dependence of the tropical clouds on the temperature. If the situation is in fact as I’ve stated above, where the tropical clouds act as a throttle because they increase when the temperatures go up, then evidence would be found in the correlation of surface temperature with albedo. Figure 4 shows that relationship.
Figure 4. Correlation of surface temperature and albedo, calculated on a 1°x1° gridcell basis. Blue and green areas are where albedo and temperature are negatively correlated. Red and orange show positive correlation, where increasing albedo is associated with increasing temperature.
Over the extratropical land, because of the association of ice and snow (high albedo) and low temperatures, the correlation between temperature and albedo is negative. However, remember that little of the suns energy is going there.
In the tropics where the majority of energy enters the system, on the other hand, warmer surface temperatures lead to more clouds, so the correlation is positive, and strongly positive in some areas.
Now, consider what happens when increasing clouds cause a reduction in temperature, and increasing temperatures cause an increase in clouds. At some point, the two lines will cross, and the temperature will oscillate around that set point. When the surface is cooler than that temperature, clouds will form later, and there will be less clouds, sun will pour in uninterrupted, and the surface will warm up.
And when the surface is warmer than that temperature, clouds will form earlier, there will be more clouds, and higher albedo, and more reflection, and the surface will cool down.
Net result? A very effective thermostat. This thermostat works in conjunction with other longer-term thermostatic phenomena to maintain the amazing thermal stability of the planet. People agonize about a change of six-tenths of a degree last century … but consider the following:
• The climate system is only running at about 70% throttle.
• The average temperature of the system is ~ 286K.
• The throttle of the climate system is controlled by nothing more solid than clouds, which are changing constantly.
• The global average surface temperature is maintained at a level significantly warmer than what would be predicted for a planet without an atmosphere containing water vapor, CO2, and other greenhouse gases.
Despite all of that, over the previous century the total variation in temperature was ≈ ± 0.3K. This is a variation of less than a tenth of one percent.
For a system as large, complex, ephemeral, and possibly unstable as the climate, I see this as clear evidence for the existence of a thermostatic system of some sort controlling the temperature. Perhaps the system doesn’t work as I have posited above … but it is clear to me that there must be some kind of system keeping the temperature variations within a tenth of a percent over a century.
Regards to all,
w.
PS—The instability of a modeled climate system without some thermostatic mechanism is well illustrated by the thousands of runs of the ClimatePredictionNet climate model:
Note how many of the runs end up in unrealistically high or low temperatures, due to the lack of any thermostatic control mechanisms.
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Stephen 3:55am: “The basic facts are:…”
You need to include basic fact of albedo so net sun proportionally warms surface and atm. And…
i) There is no S-B height off the surface. The solid/water surface radiates always at the surface, need to modify rest of your narrative by eliminating any ref. “S-B height” to line up with text books. On Earth, the sun warms the surface not the mass of gaseous atm. (as in atm. contracting in the gas giants).
ii) Ok, better to start here with your narrative (i.e. w/atm. radiation), eliminate “S-B height” implication above surface in the rest.
Stephen 3:55am: “The basic facts are:…” (Little help mod.s with tag)
You need to include basic facts of albedo so net sun proportionally warms surface and atm. And…
i) There is no S-B height off the surface. The solid/water surface radiates always at the surface, need to modify rest of your narrative by eliminating any ref. “S-B height” to line up with text books. On Earth, the sun warms the surface not the mass of gaseous atm. (as in atm. contracting in the gas giants).
ii) Ok, start here with your narrative (i.e. w/atm. radiation), eliminate “S-B height” implication above surface in the rest.
Ah,
I see where my narrative needs correction.
The S-B height as normally defined must be the same as the effective radiating height since the S-B equation is a radiative only equation.
However, conduction causes a temperature gradient from the surface up to a higher point in the atmosphere such that above and below that point the actual temperature differs from that predicted by the S-B equation.
I have been using the term ‘S-B height’ to refer to that height.
The point in the atmosphere where temperature again becomes ‘right’ for the S-B equation still becomes detached from the effective radiating height but we need a new name for it.
Has anyone ever given it a name ?
Alternatively, we can say that conduction as a non radiative process seeks to separate the actual temperature profile of the atmosphere from the effective radiating height but that convection then ramps up or down to prevent any such divergence.
That seems a bit neater.
If, at any time, convection fails to match up the net thermal effect of radiative and conductive processes combined then it is during the subsequent equilibriation process that system temperatures can rise or fall and the atmosphere expand or contract.
Ultimately, though, the system energy content (and therefore temperature) always returns to that set by mass and gravity.
wayne says:
January 4, 2014 at 4:13 am
Hogwash. Take a look at the graph again:
Now, you claim that “all matter absorbs and emits infrared … at all frequencies”. But LOOK AT THE DAMN DIAGRAM. For many of the gases shown, they definitely do NOT absorb “at all frequencies”. See those white areas? In those areas, the gases absorb and emit ZERO. Not “a little bit”. Zero. Why? Because they can’t physicall absorb or emit energy at that frequency. Oxygen cannot absorb even the smallest amount of energy at a wavelength of 2µm. It has no physical way to do so. Because oxygen is a diatomic gas, it can only absorb/emit in a few very narrow frequency bands.
As I said before, the graph makes it obvious that many gases only absorb/emit at only a few specific narrow thermal IR frequency bands … and you guys seem to believe that.
So why is it so hard to understand that there are gases that are just slightly worse absorbers/emitters than oxygen, gases like argon that don’t absorb/emit at any thermal IR frequencies?
Look, in school I too was told that all matter emits and absorbs at all frequencies as you claim above … but it simply isn’t true. It’s true of all solid matter, which is how the meme persists … but a quick look at the graph above should disabuse you of your claim that all matter absorbs and emits at all frequencies.
w.
Willis 9:30am: “But LOOK AT THE DAMN DIAGRAM.”
Please do so yourself, ver-r-ry damn closely. The top one does not go to zero anywhere as wayne and I describe for you. There is never 0% absorption (100% transmission) and in some cases there is 100% absorption (0% transmission).
The trouble with the lower 6 is graphic only, they are built with a displaced zero since they really never go to zero either if one expands the y-axis enough to read 0.0 appropriately. No photon beam of any freq. can get 100% through a mass (solid, liquid, gas, plasma) without some non-zero attenuation. Text book basic physics shows why.
NB: they can measure attenuation of exoplanets atm. not knowing the composition.
I’m with Willis on the issue relating to the radiative characteristics of individual gases but still query his position on the matter of conduction and convection.
It seems to me that the thermal effect of conduction is negated by the thermal effect of convection otherwise radiative equilibrium would not be possible.
Due to the real world physical nature of planets one cannot have conduction without convection contrary to Willis’s thought experiment.
That leaves the only remaining issue as to whether the radiative characteristics of atmospheres can overcome the effects of mass and gravity in setting the energy content of a planet with an atmosphere.
Radiative characteristics can clearly alter the effective radiating height but can they affect total system energy content ?
It seems to me that changing the effective radiating height then affects both conduction and convection (to an equal and opposite extent to the radiative change) so as to cancel out the thermal effect of a change in the radiative capability of an atmosphere.
Indeed, it is essential to Willis’s own thermostat mechanism that something of that nature occurs.
Just referring to tropical convection is not enough on its own.
One really has to relate the tropical changes to the entire global air circulation which is something that I have been trying to get Willis to attend to for several years past.
Could it be the case that Willis’s own evidence in support of a thermostatic mechanism is evidence in support of my proposition that changes in conduction and convection necessarily negate changes in radiative capability but that the principle should be applied globally and not just to the level of tropical thunderstorm activity ?
The best form of words to describe my concepts has yet to be crystallised as witness the objections of Trick and others but I’m currently of the opinion that I only need to change the terminology rather than the basic principles.
One way or another, however one describes it, there is a global thermostat as per Willis’s basic contentions and it must be a matter of changes in conduction and convection offsetting changes in the radiative capability of atmospheres.
That said, I do agree with Trick and wayne that all matter has some radiative capability but in my view that just causes a change in effective radiating height which is then offset in turn by a change in conduction and convection to leave system equilibrium temperature (or rather system energy content) intact as per Willis’s thermostat mechanism.
The essential point is that conduction and convection must be the negative system response to any changes in radiative capability.
Then, since the basic system temperature or energy content is determined by mass rather than radiative capability our trivial changes in atmospheric CO2 content have no measurable effect compared to natural variations caused by sun and oceans.
To summarise:
Changing the effective radiating height by altering the atmosphere’s radiative capability affects conduction which potentially does have a thermal effect.
That change in conduction is then negated by a change in convection with the end result that the radiative change has a zero thermal effect but does have a miniscule global air circulation effect.
Stephen 2:23pm: “I’m with Willis on the issue relating to the radiative characteristics of individual gases…”
Monatomic argon too? If so, how does Stephen explain the non-zero at any wavelength top graph in Willis’ post? If argon was shown as a component, Ar (et. al. actually) graph would provide the nearly straight non-zero line along the bottom in the top graph.
..there is a global thermostat as per Willis’s basic contentions…
What is this thermostat set temperature in K? Modern science would more precisely write earth/atm. diabatic system is more like forced open loop stable control system in theory (radiation in, radiation out). The adiabatic system inside the surface/TOA control volume is more like stable closed loop feedback control system theory.
When you carry a full to the brim hot coffee cup up the stairs – do you look at it or look away? One is closed loop, the other is open loop. Some people I have observed are more stable in one mode than the other. I test myself and find I am more stable looking at it. Some look away as they over control the thing otherwise.
2:37pm: “…the radiative change has a zero thermal effect…”
Energy is conserved, change in radiative energy cannot have a zero thermal effect unless balanced which means radiation is UNchanged to have zero thermal effect. Radiation increases entropy.
Trick says:
January 4, 2014 at 2:01 pm
Willis 9:30am: “But LOOK AT THE DAMN DIAGRAM.”
Please do so yourself, ver-r-ry damn closely. The top one does not go to zero anywhere as wayne and I describe for you. There is never 0% absorption (100% transmission) and in some cases there is 100% absorption (0% transmission).
The trouble with the lower 6 is graphic only, they are built with a displaced zero since they really never go to zero either if one expands the y-axis enough to read 0.0 appropriately. No photon beam of any freq. can get 100% through a mass (solid, liquid, gas, plasma) without some non-zero attenuation. Text book basic physics shows why.
NB: they can measure attenuation of exoplanets atm. not knowing the composition.
+++++++++++
In Willis’ defense, when you write ” The top one does not go to zero anywhere as wayne and I describe for you. There is never 0% absorption”
This is true, I think, because there are many gases included, more so than the sum of the 6 gases below the total absorption and scattering plot. Am I wrong here?
Mario 5:07pm: The individual components wouldn’t go to 0.0 either if the zero on ordinate wasn’t suppressed. Note the top Willis’ graph says “total absorption and scattering” shown. The others aren’t labeled. Not sure what is shown on their ordinate. See also wayne’s link inverted.
Trick said:
“Change in radiative energy cannot have a zero thermal effect unless balanced which means radiation is UNchanged to have zero thermal effect”
The radiation in and out is unchanged.
My point is that a change in radiative capability within an atmosphere is offset by a change in conduction and convection in an equal and opposite internal system response.
The thermal effect of surface radiation is constantly being balanced by the thermal effect of conduction and convection so as to leave radiation in and out in balance for the atmosphere as a whole.
That is the only way I can think of that provides a thermostat effect and it fits in with Willis’s observations about tropical convection and maximum sea surface temperatures.
Trick said:
“What is this thermostat set temperature in K? Modern science would more precisely write earth/atm. diabatic system is more like forced open loop stable control system in theory (radiation in, radiation out). The adiabatic system inside the surface/TOA control volume is more like stable closed loop feedback control system theory.”
It appears to be 33C above the S-B temperature.
In referring to a diabatic loop (forced by energy in) and a separate closed adiabatic loop are you not conceding the principles set out in my old article about just such an arrangement which you seemed to argue against at the time ?
My contention is indeed that the adiabatic loop is closed and simply circulates energy constantly between surface and atmosphere leaving the diabatic loop of solar energy in and longwave energy out in radiative balance.
Radiative capability changes within the atmosphere then only affect the adiabatic loop which can change speed or scale as necessary which in turn changes the ratio of KE and PE in the atmosphere so as to keep the surface temperature stable.
Stephen 2:16am: “In referring to a diabatic loop (forced by energy in) and a separate closed adiabatic loop are you not conceding…”
Not conceding. I’ve found best to use those “loop” terms in reply to Stephen b/c Stephen alone understands them. The rest of modern science observes them as cited here (1997 updated 2009, 2012) which also discusses Willis’ chart and his current quest on understanding CERES data and “Earth is presently absorbing 0.85 ± 0.15 W/m2” with a cited description of actual text book physics. Not just a narrative.
http://www.globalwarmingart.com/wiki/File:Greenhouse_Effect_png
“(Themostat setpoint) appears to be 33C above the S-B temperature.”
Then the anomaly would be 0.0K with some consistent hysteresis (like your house thermostat) and clearly this is not the case recently & especially over eons.
My point has always been if Stephen’s adiabatic cycle simply “speeds up” or “slows down” to counter radiative changes then surface Tmean=288K would have been the “setpoint” since “In the beginning…”. Clearly, surface Tmean anomaly charts show this is not the case in whatever cherry picked time frame suits a view.
Also my point has been if “…the basic system temperature or energy content is determined by mass… then show how to calculate Tmean from just the atm. mass & net solar. Haven’t seen that done yet. There is a better way using 1st law and measured data: gross solar, albedo, surface & atm. emissivity in the text books (cite Bohren 2006 p. 33).
“Tmean=288K would have been the “setpoint” since “In the beginning…”. Clearly, surface Tmean anomaly charts show this is not the case in whatever cherry picked time frame suits a view.”
Please clarify.
The anomaly charts just show variations around the set point and do not disprove its existence.
“There is a better way using 1st law and measured data: gross solar, albedo, surface & atm. emissivity ”
Albedo and emissivity are mostly a function of mass (ignoring water clouds and other particulates for the moment) which leads to net solar so I don’t see your point.
By deducting mass induced albedo and emissivity effects from gross solar that gives net solar and applying the 1st law then gives Tmean from atm.mass and net solar
Ahhh…Stephen 6:45am: I am in chatty mood. Properly caffeinated.
“Please clarify.” Observations (surface&satellite) clearly show there is no thermostat, no set point because surface Tmean isn’t set at 288 (or any other number) plus hysteresis. Cite Dines 1917, Hunt 1986. Callendar 1938 had 283K, KT97 had it at around 287K from ERBE; recently from CERES closer 289K. Clearly anomaly observations are not consistent with a 288K thermostat set point + consistent hysteresis over recent thermometer times or over eons.
“Albedo and emissivity are mostly a function of mass…By deducting mass induced albedo and emissivity effects from gross solar that gives net solar and applying the 1st law then gives Tmean from atm.mass and net solar.” Then calculate albedo from atm. mass (total mass an easy lookup), calculate atm. emissivity from mass. Show how to calculate surface Tmean from net solar + atm. mass. You can’t. Only in your narrative alone do these unphysical concepts surface.
“..so I don’t see your point.” I know. Read the text books cited then. See my points. Find them easily actually if only you would read the basic science. Get cracking.
Here, use Willis’ argon atm. as a thinking tool. Use the link I gave again:
http://www.globalwarmingart.com/wiki/File:Greenhouse_Effect_png
Question for Stephen to think thru. Given earth atm. same mass and net solar same, but composition change to argon. According to Stephen narrative surface Tmean would still be 288K from same mass and same net solar. However the blue area (in Radiation Transmitted by the Atm.) would not remain the same as in Stephen’s narrative – blue would significantly reduce but not to 0.0 (as Willis debates).
I ask Stephen: What would Ar Tmean become? 288K as thermostat set point? What would the adiabatic (tan, green dotted loop) and diabatic (white) numbers shown become? The same by adjusting green loop “speed”? Hardly. Composition matters (as well as mass, specific heat, emissivity, orbit et. al.).
Hint: One can est. Ar atm. surface Tmean from Bohren 2006 p. 33 construct. As in any planetary, exoplanet science work going on today (another hint: they don’t use atm. mass & net solar). Even Venus surface Tmean was predicted ahead of experiment (1960s) from Dr. Bohren’s et. al. construct – this happened a decade after Venus was thought by some narratives to be able to support life (1950s) as we know it. Text book science theory & experiment won the day, not narrative.
Going by that energy budget cartoon I’d say that the ‘greenhouse effect’ of 350 in Earth’s mixed atmosphere should actually be,say, 345 absorbed by conduction and only 5 or less absorbed by GHGs.
If one then increases GHGs to.say, 10 then the conduction / convective exchange slows down so that it then only handles 340 leaving radiative balance unchanged and the surface temperature unchanged.
If one then switches to a radiatively inert atmosphere the whole greenhouse effect is from conductive absorption and all outward radiation is from the surface. Adjust the numbers accordingly.
Stephen 10:20am: ”…conduction / convective exchange slows down…and the surface temperature unchanged.”
Stephen’s narrative is free of Fourier conduction law b/c he hasn’t read Bohren 1998 p. 337 where science long holds conduction is proportional to delta T. If conduction between surface (warmed by sun) and cooler atm. slows down then the delta T is less not unchanged in Stephen’s incorrect narrative.
“Adjust the numbers accordingly.” Here Stephen concedes. Previously Stephen wrote given no atm. mass or net solar change means since Tmean set by these factors according to Stephen previously – no adjustment for argon, Tmean remains 288K. Dr. Bohren’s construct however adjusts the numbers accordingly and effectively calculates the new argon atm. surface Tmean as Stephen now concedes. There is more than atm. mass and net solar setting Tmean. But I bet Stephen eventually backslides as per customary trait.
“conduction is proportional to delta T”
But only at a given rate of convection.
The faster is convection the more conduction can occur and vice versa.
The same deltaT can result from variable combinations of radiation and conduction because each is of opposite sign.The rate at which energy is shifted from the surface by convection influences the amount of conduction that can occur.
The amount of energy diverted to conduction has an effect on the proportion of surface radiation that can escape to space.
More conduction and less radiation or less conduction and more radiation.
The surface energy cannot do two things at once.
There is a constant interplay between conduction / convection on the one hand and radiation on the other.
As a result of that varying interplay deltaT stays stable over time but in practice the system is always a little out of equilibrium and constantly varies one side or the other of the set point determined by mass and gravity.
T mean stays at 288K if net solar and atmospheric mass and the strength of the gravitational field stay the same but internal system variability provoked mainly by solar and oceanic changes means that T mean is never actually achieved or not for long.
“Adjust the numbers accordingly.”
You can adjust the numbers to show no effect from Argon as compared to an atmosphere with greater radiative capability.
Just juggle the proportions of conduction and radiation within the energy allocation for the greenhouse effect.
The speed of convective overturning acts as the modulating factor between the two processes.
The more convective overturning the faster the surface can divert radiation to conduction and vice versa.