Guest post by Bob Irvine
SUMMARY
This paper outlines an idea or hypothesis that should be discussed. This idea has the huge advantage of being supported by all the available data both from over the last thousand years or more, the last 60 or 70 years and the last 20 years.
We have a chance here to solve the global warming debate and standoff. It is quite possible that both sides of the debate have some truth on their side. I believe there is a strong case that the climate sensitivity or temperature response to a given forcing not only depends on the size of that forcing but also on the nature of that forcing. I have attempted to mount a case for the idea that a given LONG WAVE GHG forcing will have considerably lower temperature response than a similar SHORT WAVE solar forcing.
The alarmists may well be correct. There is a lot of evidence from the Last Glacial Maxima and Volcanoes and other areas that climate sensitivity is quite high (about 0.8, i.e. requil. T=0.8xrF). Certainly, this can be seen on geological scales. These estimates are based on Short Wave Solar Forcings. The trouble starts when they try to apply these high sensitivities to the enormous increase in Long Wave GHG forcing that has occurred in the last 60 or 70 years. They mistakenly assume that a given GHG forcing will have the same equilibrium temperature response as a similar Solar Forcing and then find it difficult or impossible to make the meagre temperature response over recent years fit their high sensitivities.
The riddle is neatly solved if we accept the concept of “Effective Climate Forcing”. In other words, we accept that a given Long Wave GHG Forcing has a lower climate sensitivity than a similar Short Wave Solar Forcing. It is in fact intuitively unlikely that these two forcings have the same efficacy as is assumed by the IPCC and others.
INTRODUCTION
The efficacy of a given forcing is an estimate of its efficiency in provoking an equilibrium temperature response in the earth’s system. The IPCC and others assume that a given change in GHG forcing will produce a temperature response that is approximately equal to the temperature response from a similar change in solar forcing.
That this is not necessarily the case is discussed in the literature. Joshi et al 2003, Hansen and Nazarenko 2004 and Shine et al 2003 all conclude that the same forcing can have a different temperature response depending on its nature or geographic location.
Forster and Taylor 2006, “Climate Forcings and Climate Sensitivities Diagnosed from Coupled Climate Model Integrations “ make the case that ”Effective Climate Forcing” is a much more useful way of estimating climate sensitivity than conventional; one size fits all, Radiative Forcing. They make their case succinctly in the following quote;
“Imagine, for example, that the atmosphere alone (perhaps through some cloud change unrelated to any surface temperature response) quickly responds to a large radiative forcing to restore the flux imbalance at the TOA (Top Of Atmosphere), yielding a small effective climate forcing. In this case the ocean would never get a chance to respond to the initial Radiative forcing, so the resulting climate response would be small and this would be consistent with our diagnosed “effective climate forcing” rather than the conventional “Radiative forcing.”
In the quote above a shorter response time at the TOA produces a lower climate sensitivity. Hansen, Sato and Kharecha confirm and support this in their paper “Earth’s Energy Imbalance and Implications”, by saying
“On a planet with no ocean or only a mixed layer ocean, the climate response time is proportional to climate sensitivity. ………..Hansen et al (1985) show analytically, with ocean mixing approximated as a diffusive process, that the response time increases as the square of climate sensitivity.”
If it can be shown that the restoration of the flux imbalance at the TOA is quicker for a perturbation in GHG forcing than it is for a similar perturbation in solar forcing, then this would imply a lower climate sensitivity for GHG forcing than solar forcing.
DISCUSSION
It is in fact intuitively unlikely that the earth’s system would respond in almost exactly the same way to a change in Long Wave GHG forcing as it would to a change in Short Wave solar forcing, as the IPCC and others assume.
It is established physics that Long wave Radiation from GHGs only penetrates the oceans to a depth of a fraction of a millimetre. The oceans are virtually opaque to these wave lengths. Short Wave solar radiation, on the other hand, penetrates the ocean to a depth of 10 meters or more and it is counter intuitive to assume that this established fact would have close to zero effect on flux imbalance restoration times at the TOA.
Despite this matter being pivotal to any understanding of the earth’s climate response to increasing Anthropogenic GHGs (AGHG), I have been unable to find any literature supporting the IPCC’s position that solar forcing and GHG forcing have the same efficacy after the ocean/ atmosphere interface has been considered. The references mentioned by the IPCC in their reports only refer to the global nature of the two forcings and only take into account feedbacks that are related to a temperature response. These do not apply in this case. Basically, the fact that the oceans are opaque to GHGs is due to the nature of the forcing and not accounted for if the feedbacks considered are only related to a temperature response. Similarly, to assume, as the IPCC does, that GHG forcing and Solar forcing have the same “effective climate forcing” simply because they are both global in nature, also, does not take account of the opaqueness of the oceans to the wave length reemitted by GHGs.
The blogosphere does make an attempt at explaining the IPCC’s position. The only defence I am aware of is that the top fraction of a millimetre of the ocean is heated up by the Long Wave Radiation (LWR) reemitted by GHGs. This then acts as a blanket slowing the release of energy from the ocean, thereby effectively warming the ocean by nearly exactly the same amount as a similar solar forcing that penetrates the ocean to a depth of 10 meters or more.
Not only is it highly improbable that these two entirely different mechanisms would have almost exactly the same effect on OHC (Ocean Heat Content), but it can be shown by means of a simple experiment, (Appendix 1), that nearly all the Long Wave GHG energy is returned almost immediately to the atmosphere and space as latent heat of evaporation. It, therefore, has little effect on OHC. It is, also, likely that the restoration of the flux imbalance at the TOA is quicker for a perturbation in GHG forcing than it is for a similar perturbation in solar forcing.
It is apparent that the situation described in the Forster and Taylor (2006) quote above is relevant to GHG forcing. In short, the” Effective Climate Forcing” of a GHG change is likely to be considerably less than the “Effective Climate Forcing” of a similar solar change.
CORROBORATION
It is an intriguing possibility that both sides of the Global Warming debate could be correct to some extent. The IPCC and others estimate climate sensitivity by reference to three factors, none of which apply to climate sensitivity derived from a GHG forcing.
These three factors are;
- They use “Absolute Radiative Forcing” instead of “Effective Radiative Forcing” (Forster and Gregory 2006)
- They use sensitivities based on Solar Forcing which clearly do not apply to GHG Forcing. For example, sensitivities calculated from the Last Glacial Maxima (LGM) or volcanoes are essentially based on Solar Forcing and, therefore, do not apply to GHG Forcing. (Annan & Hargreaves 2006).
- They use feedbacks that are dependent on an initial temperature response and, therefore, do not take account of the opaqueness of the oceans to Long Wave Radiation from GHGs. (All the Global Climate Models , GCMS)
The IPCC and others may have produced some good science that gives reasonably accurate climate sensitivity estimates for a change in solar forcing. Unfortunately, these are unlikely to apply to a GHG Forcing.
Interestingly, Idso 98 uses real world experiments that, largely, do apply to GHG Forcing and their climate sensitivity is considerably lower than the IPCC’s consensus.
The sceptics, on the other hand, are fairly obviously quite correct when they say that the high sensitivities postulated by the alarmists do not fit with the measured temperature record of the 20th and 21st century.
The best way to show this lack of correlation is to compare the amount of energy put into the system by human GHGs, as represented by equilibrium temperature, with actual temperature as measured in the thermometer age since 1880.
The green line in Fig. 1 equates to a sensitivity of 0.8 (rT = 0.8 x rF) which gives an equilibrium temperature increase of 3.0°C for a doubling of human CO2, the IPCC’s central position. In 2010 the difference between the green line and blue line (actual temperature) was an unlikely 1.4°C. If present trends continue, as is likely, that gap would be close to 2.0°C in 5 years’ time.
FIG, 1 The IPCC’s upper (purple), central (green) and lower (red) equilibrium temperature predictions using their climate sensitivity to forcing. The forcings were calculated for all the human GHGs using concentrations given in 4AR and the generally accepted conversion formula, rF=5.35xln(C/Co) WM-2 where C is current concentration and CO is starting concentration. These are compared with actual temperature (blue). For comparison purposes all graphs were zeroed in 1880.
NOTE; It is generally believed that equilibrium temperatures are approximately 1.5 times transient temperatures (4AR) and that aerosol cooling has masked any human induced GHG warming. These are the two factors the alarmists use to attempt to explain the gap between reality and the IPCC’s calculated equilibrium temperatures from AGHGs.
There are also major inconsistencies with the Ipcc’s explanation for the warming from 1910 to 1940. Bob Tisdale discusses these inconsistencies at WUWT on the 20th April 2013.
The only realistic explanation for this lack of correlation ( FIG, 1) is that the IPCC’s sensitivities are far too high and that the “Effective Radiative Forcing” for Long Wave GHGs is considerably lower than the “Effective Radiative Forcing “ for Short Wave solar.
APPENDIX 1
This experiment is attributed to Tallbloke and shows unequivocally that Long Wave radiation from GHGs has little or no effect on Ocean Heat Content. Short Wave Solar radiation, on the other hand, penetrates the oceans to a depth of ten meters or more and, therefore, adds significantly to OHC.
Konrad: Empirical test of ocean cooling and back radiation theory
Posted: August 25, 2011 by tallbloke in atmosphere, climate, Energy, Ocean dynamics
Some background –
Willis Eschenbach had a guest posting over at WUWT in which he claimed that LWIR could heat Earth’s oceans. Myself and several others on the thread contended that this LWIR was likely to be stopped by the evaporative skin layer and would not slow the exit of heat from the oceans. Numerous requests for empirical evidence to support Willis’s claim only resulted in one inapplicable study used by the “Hockey Team” to support such claims. After several hundred comments without empirical evidence being offered, I gave up reading and designed and conducted an empirical experiment that shows that any effect of backscattered LWIR on the cooling rate of water would be negligible.
What follows is an edited version of the experiment design and results as posted on the WUWT thread. I would encourage others to conduct similar experiments to check my results. The equipment required is not overly expensive and the results can be observed in minutes. The results appear to show the measurable difference between reflecting LWIR back to warm water when it is free to evaporatively cool and when it can only cool through conduction and radiation.
What is required –
– Two identical probe type digital thermometers with 0.1 degree resolution
– Two identical insulated water containers. I used rectangular 200ml Tupperware style containers, insulated on their base and sides with foil and Styrofoam. I cut away the clip on rim from each lid to create a frame to clip down cling film for Test B of the experiment.
– One IR reflector. I used an A4 sheet of 10mm Styrofoam with aluminium foil attached with spray adhesive.
– One IR window. I built an A4 size “picture frame” of 10mm square balsa wood strips and stretched cling film over it.
– One 1 litre measuring jug
– Two small identical computer fans. I used Suron 50mm centrifugal blowers powered by a 6v gel cell battery
– Extra cling film
– Optional extras – kitchen timer, an A4 ”dark cool sky” panel of matt black aluminium with peltier cooling, glamorous lab assistant of choice.
What to do –
– Position probe thermometers in identical positions in both water containers. I placed the tips 10mm below the water line by drilling force fit holes in the sides of the containers.
– Position IR reflector and IR window 50mm above either water container. You may need to build two Styrofoam side walls, but air must be free to move over the surface of the water. (The use of the IR window is to ensure that air flow is similar over each water container.)
– Position the computer fans to blow across the water surface of each container, but do not turn on.
– Fill jug with warm water, stir, then fill each water container from the bucket. I used water around 40C as the ceiling was around 18C not a 3k sky.
– When and equal amount of water is in each container, turn on the computer fans.
– Observe the temperature change over time for each tank. Less than half an hour is required for such a small amount of water. You should observe that both tanks cool a the same rate (TEST A).
– Now the important bit – Repeat the experiment, but this time lay a small sheet of cling wrap on the surface of the water in each water tank. This allows cooling through radiation and conduction but prevents evaporation. You do not need the computer fans on in this test. You should be able to observe that while both containers cool slower than before, water under the IR reflector cools slowest (TEST B).
Interpretation –
In TEST A the water cools more quickly, however the two water containers temperatures remain very close to each other over time. This indicates that backscattered LWIR has a very limited effect on the rate of cooling for water when it is free to evaporatively cool.
In TEST B both water containers cool more slowly than test A, but a divergence in temperature between the two water containers is readily detectable. The container under the foil sky cools more slowly than that under the cling wrap sky. This indicates that backscattered LWIR from a warm material can slow the rate at which that material cools, if radiation and conduction are the only methods for cooling.
Test A represents the evaporative cooling conditions in the real oceans. Test B represents how the climate scientists have modelled the oceans with regard to backscattered LWIR. From what I have observed, backscattered LWIR can slow the rate at which substances cool. However in the case of liquid water that is free to cool evaporatively this effect is dramatically reduced. It would appear that including the oceans in the percentage of Earth’s surface that could be affected by backscattered LWIR may be a serious error. Earth’s oceans cover 71% of the planets surface. If backscattered LWIR cannot measurably affect liquid water, then CO2 cannot cause dangerous or catastrophic global warming.
I have conducted further tests using a “cold sky” panel cooled with ice water over the top of the cling film IR window. While the temperature divergence in the evaporation restricted test B does not appear faster, it does appear to diverge for longer.
I would encourage others to conduct similar empirical experiments and share their observations. I would be interested in comments in further experimental design, or empirical evidence related to the LWIR question.
Typical TEST A
| Time | Cling Wrap Screen | Foil screen |
| 0 | 37.1 | 37.1 |
| 5 | 33.2 | 33.2 |
| 10 | 29.4 | 29.4 |
| 15 | 27 | 26.9 |
| 20 | 25.5 | 25.5 |
| 25 | 24.5 | 24.5 |
Typical TEST B
| Time | Cling Wrap Screen | Foil screen |
| 0 | 38.2 | 38.2 |
| 5 | 36.3 | 36.6 |
| 10 | 34.8 | 35.3 |
| 15 | 33.5 | 34.2 |
| 20 | 32.6 | 33.4 |
| 25 | 31.5 | 32.6 |
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Kristian says:
“What is reduced is ‘the heat transfer rate’ between the warmer body and the cooler. Q. This does not affect the surface temperature of the warmer body. Only the surface temperature of the cooler one.”
Uh …. if the rate of heat loss is reduced then the temperature of the “warmer body” will be higher at some time interval later than it would have been without the “cooler body’s” radiation.
http://www.asterism.org/tutorials/tut37%20Radiative%20Cooling.pdf
I take it that the “hitch a ride ” and the “off with his head” flags that made a brief appearance, are now in the “don’t try this at home”, folder. Good place to store them, I say.
Kristian: “Er, rgb, you got this exactly wrong. It says it is 300K radiating 460 W/m^2 both before AND after you put the opaque layer outside it.”. Maybe review the words…
RGB said: “This specific example is ALMOST a perfect (if oversimplified) model for greenhouse warming, if you switch from a constant temperature source to a constant power source.” So, in that case, you are no longer at a constant temperature and therefore no longer at constant 460 W/m². Seems you shouldn’t have tried to correct him there. Robert’s describing what was just discussed in depth over at Tallbloke’s TalkShop.
I just wish rgb would have made the logical jump to include in his comment with a partial of non-interacting window radiation (the non-GHG lines) simultaneously escaping then he indeed would have a very close model for a planet’s atmospheric greenhouse effect. Would have been good hearing how he would see that view of a “leaky shell” around a sphere of constant power.
Wayne,
The plate has a constant temperature because it has a constant energy supply from its heat source. With a variable heat source, the temperature would not be constant.
So rgb got it wrong. It says very clearly that the plate is at a temperature of 300K, radiating 460 W/m^2 as a result, both before AND after the insulating layer is in place. After the new layer has reached equilibrium with the plate (its heat source), it emits 230 W/m^2 to space, half of what the plate emits to it. Radiation balance at this point. The plate has the same temperature and the same emitted power as before.
It also states very clearly that the insulating layer cools down to equilibrium with the plate, hence it was warmer than 252K to begin with but has no heat source of its own, so will depend on the constant flux of 460 W/m^2 from the plate.
The total heat loss flux from the plate, Q = 460 W/m^2, goes half into warming the insulating layer and keeping up its equilibrated temperature (Q’), half from the new layer to space (Q”): Q = Q’ + Q”, 460 W/m^2 = (460 – 230) + 230. This is the exact equivalent to the Carnot cycle: W = Qh – Qc, where Q=Qh, Q”=Qc and Q’=W:
http://i1172.photobucket.com/albums/r565/Keyell/Carnot_zps4049e783.jpg
No need to invent secondary heating of the plate to achieve radiative balance, beyond what its heat source can manage on its own. Before the insulating layer was emplaced, the power from the plate’s heat source went into warming the plate only (one object). After, the same amount of power goes into warming the plate AND the new layer (two separate objects). Hence the smaller flux to space. It’s that simple …
The leakiness of a shell around a sphere irradiated by a constant power source is important.
In the real world that leakiness is achieved by non radiative mechanisms and is given huge power by evaporation with its 5 to 1 net cooling effect (see enthalpy of vaporisation).
Add to that the minimal resistance to changes in energy flow rates from space at near absolute zero and the fact is that changes in the internal energy flow rate from any factor other than more mass, more gravity or higher ToA irradiation are easily cancelled by equal and opposite changes in the energy flow rate from changes in circulation enabled by changes in total atmospheric volume.
In theory of course one ‘needs’ a higher temperature to support a faster flow rate if there are no volume and circulatory adjustments but when such adjustments are as freely enabled as they are around a sphere floating in space no significant change in temperature is required.
As soon as one tries to ‘add more energy’ from any cause other than more mass, more gravity or more irradiation it goes straight to PE (not heat) at the cost of a volume and circulation change.
As a gas expands, the average distance between molecules grows. Because of intermolecular attractive forces (see Van der Waals force), expansion causes an increase in the potential energy of the gas. The increase in potential energy thus implies a decrease in kinetic energy and therefore in temperature.
So, if GHGs slow down energy throughput (which is not certain anyway), the atmosphere changes volume and circulation pattern to negate that effect for little or no change in system temperature because the extra energy in the air goes readily to PE rather than KE.
The similar volume and circulation changes induced by solar and oceanic variability are magnitudes greater than those achievable by all GHGs combined let alone CO2 on its own or our contribution to CO2.
If one were to propose a residual ‘warming’ effect it could not be measured within natural variation in any event.
In the end, for all practical purposes, the atmospheric temperature around a planet is set by mass, (held within a gravitational field and irradiated) and not composition though composition can influence the circulation pattern.
***
rgbatduke says:
April 22, 2013 at 9:17 pm
***
rgb, the dragonslayers can’t seem to be reasoned with. They give legit skeptics a bad name…
“In the real world that leakiness is achieved by non radiative mechanisms…”
Sorry Stephen, no, you read me wrong, that leaking through the shell is the “window” radiation that exits directly to space and has nothing to do with non radiative mechanisms.
wayne.
In your radiative thought experiment you are right but in the real world there are additional non radiative energy transfers between surface and the shell.
I hope I am not disrupting your flow of logic by opening it up in that way.
In fact the real world is comprised of a vast number of shells each one molecule deep stacked upon one another from surface to space.
Non radiative mechanisms determine the rate at which energy flows up (and down) through the stack of shells with the net outcome only apparent at the top where energy out inevitably equals energy in subject to oscillations around the mean.
HenryP says:
April 22, 2013 at 11:08 am
don’t worry about Phil.
he never got anything from what I tried to tell him….
Because what you were trying to tell me was nonsense. As you have repeated in this thread you don’t understand the results of the earthshine paper you linked to. Absorption by the atmosphere in the near IR bands of the incoming solar spectrum heats the atmosphere, it doesn’t cool it!
Richard111 merely pointed to a fact that what we already knew, namely that (more) CO2 also acts as (more of) a coolant…..
Indeed it does…..in the thermosphere, as pointed out in the NASA paper! It also acts as a coolant in the stratosphere as is well documented by Clough and Iacono (e.g. JGR, vol 100, 1995)
Kristian: “So rgb got it wrong. It says very clearly that the plate is at a temperature of 300K, radiating 460 W/m^2 as a result, both before AND after the insulating layer is in place.”
I’ll not go much deeper into this here, but Kristian, Dr. Brown changed the parameters, but I do now see where he also made a mistake bt stating 230 for the layer. But also, you seem to be thinking that the temperature of the center object will not change, that is not correct. If the power is constant, not the temperature, like from all of the equipment inside the ISS, yes, the temperature is going to rise with each isotropically radiating layer added about it. That is why the ISS needs such a sophisticated system to keep it cool — not to keep it warm.
Henry@Phil.
you did not get it
but don’t worry, not too many do
even Anthony does not get it
Richard111 is spot on,. CO2 is a coolant.
Co2 is both a coolant and “warmant”
as is water
that is why, ultimately, in the final analysis
CO2 and water are like your father and mother.
Anyone wanting less of either (or talking bad about either)
must be daft
Love you father and your mother!
In my earlier post up above, about the energy flows in the atmosphere, I commented that I couldn’t see any mechanism for moving any significant amount of energy from the atmosphere, back to the non gaseous part of the planet (to warm it more, if yoy will); and I still can’t.
But it seems unavoidable, that the earth’s surface Temperatures are higher than they would be, if the atmosphere was absent. I don’t dispute that it is.
The argument above about shells and things, seems like a waste of time and energy to me, as is the dispute between Henry , Phil, et al as to whether CO2 cools or warms the atmosphere; well any GHG for that matter. Clearly if nothing in the atmosphere absorbed any radiation of any species, then the radiation would pass on through and escape, heating nothing. Cearly some of these gases in the atmosphere capture energy, coming and going. Solar radiation coming in, and LWIR going out, both get captured, and raise the atmospheric Temperature, where that occurs. My comment simply asserts (based on physics) that the hotter atmosphere does not raise the Temperature of the surface.
Well of course it doesn’t have to. There is that guy behind the curtain, Sol, who can, and does raise the Temperature of the surface. The sun is really the only source of energy to heat (verb) the surface. (so I discount geothermal energy from the planet, as inconsequential, besides being fairly constant.).
In my view, the way the atmospheric GHGs cause the surface Temperature to be higher, than sans GHGs conditions, is simply the escape delay time.
Some LWIR photons emitted from the surface escape directly to space in under a millisecond, never to be seen again. But the photons captured by the GHG undergo a cascade of absorptions and re-emissions from the same GHGs, and other delaying processes, so that if they do escape it is a delayed escape. I have no idea, what the average delay time is for those intercepted photons, but during that time delay, the sun continues to pour in energy, which can and does heat (verb) the surface.
So eventually, the average inflow from the sun, and the average outflow from the earth, are equal, but there must be a Temperature offset caused by the solar heating during that time offset. Some of the delay processes are quite short, but some are quite long. Together they result in the observed Temperature offset. It’s a Sorcerer’s Apprentice problem. The broom splinters add water to the tank, faster than Mickey Mouse can bail it out again so it overflows.
OK.
So, the atmosphere (O2, N2, and Ar) is transparent to IR and LWIR. In theory, at least.
But 33% of the sun’s energy is absorbed by the atmosphere.
So where in Trenberth’s famous diagram showing the 3 watts of “missing” energy supposedly supplied the greenhouse gasses by his simplified CAGW theory does this “missing” 480 watts of energy get disposed of?
Where is it radiated from, and what does it heat up?
george e. smith
some of the delay processes are quite short, but some are quite long. Together they result in the observed Temperature offset. It’s a Sorcerer’s Apprentice problem. The broom splinters add water to the tank, faster than Mickey Mouse can bail it out again so it overflows.
henry@george
You are not that far away from the truth. You got it mostly: a lot of the delay is actually caused by the evaporation of water (cooling) due to UV radiation of the seas and subsequent condensation of water vapor to clouds and rain (warming) of the atmosphere.
hence the critical situation of the amount of UV coming through the atmosphere
http://blogs.24.com/henryp/2012/10/02/best-sine-wave-fit-for-the-drop-in-global-maximum-temperatures/
As I have been studying climate science for the past 3 or 4 years I have become more and more in awe of the creation and the Creator of how clever the system was designed…….
we only just get to see a glimpse….
“It’s a Sorcerer’s Apprentice problem. The broom splinters add water to the tank, faster than Mickey Mouse can bail it out again so it overflows.”
Quite so. It overflows.
The amount of energy in the form of KE (heat) that the system is capable of holding on to is fixed only by mass, gravity and insolation.
If any other factor tries to slow down energy throughput (for example an increase in GHGs) so as to raise the temperature of the system then volume and circulation changes occur so as to convert any excess KE to PE (increase in volume) or to accelerate the flow of energy through the system (more convection and evaporation).
Of course the system is never in equilibrium due to a vast number of internal system features that constantly interact to disrupt the KE content set by mass, gravity and insolation so one constantly sees oscillations around the mean.
The observable manifestation of those oscillations is latitudinally shifting jets and climate zones which are the negative system response in action and that constitutes climate change,
The effect of our emissions being an imperceptible fraction of natural variability from solar and oceanic influences.
Quite right. Obviously global cooling causes a shift of clouds and precipitation towards the equator, amplifying the cooling effect due to less insolation….