Oh dear, now we have three peer reviewed papers (Lindzen and Choi, Spencer and Braswell, and now Richard P. Allan) based on observations that show a net negative feedback for clouds, and a strong one at that. What will Trenberth and Dessler do next? Maybe the editor of Meteorological Applications can be persuaded to commit professional suicide and resign? The key paragraph from the new paper:
…the cloud radiative cooling effect through reflection of short wave radiation is found to dominate over the long wave heating effect, resulting in a net cooling of the climate system of −21 Wm−2.
After all the wailing and gnashing of teeth over the Spencer and Braswell paper in Remote Sensing, and the stunt pulled by its former editor who resigned saying the peer review process failed, another paper was published last week in the journal Meteorological Applications that agrees well with Spencer and Braswell.
This new paper by Richard P. Allan of the University of Reading discovers via a combination of satellite observations and models that the cooling effect of clouds far outweighs the long-wave or “greenhouse” warming effect. While Dessler and Trenberth (among others) claim clouds have an overall positive feedback warming effect upon climate due to the long-wave back-radiation, this new paper shows that clouds have a large net cooling effect by blocking incoming solar radiation and increasing radiative cooling outside the tropics. This is key, because since clouds offer a negative feedback as shown by this paper and Spencer and Braswell plus Lindzen and Choi, it throws a huge monkey wrench in climate model machinery that predict catastrophic levels of positive feedback enhanced global warming due to increased CO2.
The cooling effect is found to be -21 Watts per meter squared, more than 17 times the posited warming effect from a doubling of CO2 concentrations which is calculated to be ~ 1.2 Watts per meter squared. This -21 w/m2 figure from Richard P. Allan is in good agreement with Spencer and Braswell.
[While the -21wm2 and ~1.2 W/m2 values are correct, the comparison is wrong, and it is my mistake. The values are Top of Atmosphere and Surface, which aren’t the same. This prompts a new rule for me, I shall not publish any posts after midnight again (other than something scheduled previously during the day), because clearly I was too tired to recognize this mistake. I’ll add that I have emailed Dr. Allan regarding the question of feedback on hisfigure 7, and have not received a response. – Anthony]
Here’s the paper abstract, links to the full paper (which I located on the author’s website) follow.
Combining satellite data and models to estimate cloud radiative effect at the surface and in the atmosphere
Richard P. Allan
Abstract: Satellite measurements and numerical forecast model reanalysis data are used to compute an updated estimate of the cloud radiative effect on the global multi-annual mean radiative energy budget of the atmosphere and surface. The cloud radiative cooling effect through reflection of short wave radiation dominates over the long wave heating effect, resulting in a net cooling of the climate system of -21 Wm-2. The short wave radiative effect of cloud is primarily manifest as a reduction in the solar radiation absorbed at the surface of -53 Wm-2. Clouds impact long wave radiation by heating the moist tropical atmosphere (up to around 40 Wm-2 for global annual means) while enhancing the radiative cooling of the atmosphere over other regions, in particular higher latitudes and sub-tropical marine stratocumulus regimes. While clouds act to cool the climate system during the daytime, the cloud greenhouse effect heats the climate system at night. The influence of cloud radiative effect on determining cloud feedbacks and changes in the water cycle are discussed.
1. Introduction
Earth’s radiative energy balance (solar radiative energy absorbed and terrestrial radiation emitted to space) determines current patterns of weather and climate, the complexity of which is illuminated by satellite observations of the evolving distribution and diversity of cloud structures. Representing clouds and the physical processes responsible
for their formation and dissipation is vital in numerical weather and climate prediction, yet many approximations must be made in these detailed models of our atmosphere (e.g. Bony et al., 2006; Allan et al., 2007). Observations of cloud characteristics from satellite instruments and in situ or ground-based measurements are crucial for improving understanding of cloud processes and their impact on Earth’s radiative energy balance (Sohn, 1999; Jensen et al., 2008; Su et al., 2010). The energy exchanges associated with cloud formation and precipitation are also a key component of the global water cycle, of importance for climate change (Trenberth, 2011). In this paper, initially presented at a joint meeting of the Royal Meteorological Society and Institute of Physics on Clouds and Earth’s Radiation Balance (Barber, 2011), the utility of combining weather forecast model output with satellite data in estimating the radiative effect of cloud is highlighted. Using a combination of models and satellite data a simple question is addressed: how do clouds influence the radiative energy balance of the atmosphere and the surface.
As an example of the radiative impact of cloud, Figure 1 displays thermal infra-red and visible channel narrow-band images of the European region from the Spinning Enhanced Visible and Infra-Red Imager (SEVIRI) on board the Meteosat-9 satellite (Schmetz et al., 2002).
In both images clouds appear bright: this denotes relatively low infra-red emission to space and relatively high reflection of visible sunlight to space. The hot, generally clear regions of northern Africa are also noticeable in both images since they are associated with substantial thermal emission to space (dark regions in the infra-red image) and high surface reflection from the desert surface (bright in the visible image). The brightest clouds in the thermal image correspond with (1) a trailing cold front extending from the coast of Norway, across Scotland and to the west of Ireland, (2) a developing low pressure system to the west of Iceland, and, (3) a low pressure system in the Mediterranean centred on Sardinia.
These are regions of ascending air with relatively high altitude, low temperature cloud tops which depress the thermal emission to space compared with surrounding regions. These features are also present in the visible image. However, many more cloud structures are also present. There is a prevalence of low altitude cloud over the oceans: this cloud contains large amounts of water droplets which are highly reflective (e.g. Stephens et al., 1978). The imagery captures the complex cellular structure of this cloud (e.g. Jensen et al., 2008) over the region surrounding the Canary Islands. These cloud types are thought to contribute strongly toward uncertainty in climate projections (Bony et al., 2006). While these clouds also strongly attenuate infra-red radiation, their impact on the thermal radiation escaping to space is modest since cloud-top temperatures are not dissimilar to the surface at night and so they do not contribute significantly to the strong natural greenhouse effect of the clear-sky atmosphere.
The altitude and optical thickness of cloud determines the overall radiative impact of cloud, a combination of the warming greenhouse effect and the surface-cooling solar
shading effect. Yet, probably an even stronger influence does not relate to the cloud itself. The time of day and time of year dictate the incident solar radiation and, therefore,
modulates the strength of the short wave reflection: clearly at night the solar influence of cloud is absent.
…
7. Conclusions
Exploiting satellite measurements and combining them with NWP models initialized through assimilation of available observations enables the effect of clouds on the Earth’s radiative energy balance at the surface and within the atmosphere to be quantified for the present day climate. Consistent with previous results (Ramanathan et al., 1989; Su et al., 2010), the cloud radiative cooling effect through reflection of short wave radiation is found
to dominate over the long wave heating effect, resulting in a net cooling of the climate system of −21 Wm−2.
The short wave radiative effect of cloud is primarily manifest as a reduction in the solar radiation absorbed at the surface of −53 Wm−2 for the global multi-annual mean. The magnitude of this effect is strongly modulated by the incoming solar radiation and the dominance of cloud short wave cooling over long wave greenhouse trapping is maximum around local noon (Nowicki and Merchant, 2004) while the cloud long wave heating effect dominates at night.
The long wave greenhouse effect of cloud measured at the top of the atmosphere is manifest primarily as a heating of the atmosphere in the moist tropics, consistent with calculations by Sohn (1999).
Over the marine stratocumulus regions and across higher latitudes the cloud-base emission to the surface becomes substantial and dominates over the reduced outgoing long wave radiation to space resulting in enhanced radiative cooling of the atmosphere and heating of the surface. The cloud radiative influence on the exchange of radiative fluxes between the atmosphere and the surface are intimately linked with the water cycle through radiativeconvective balance. While tropical, high-altitude clouds act to stabilize the atmospheric profile radiatively, clouds over polar regions tend to cool the atmosphere while heating the surface through enhanced atmospheric longwave radiative emission to the surface. In future work it would be informative to categorize these effects by cloud type further (e.g. Futyan et al., 2005) and compare with climate model simulations. These analyses are vital in constraining cloud feedback processes further and in linking to future changes in the water cycle (Stephens, 2005; Bony et al., 2006; John et al., 2009).
A particular challenge is the accurate quantification of surface radiative fluxes due to the sparse ground-based observing network (Roesch et al., 2011) and also monitoring current changes in cloud radiative effect in satellite data, reanalyses and models (Wielicki et al., 2002); combining meteorological reanalyses with satellite data and surface observations provide a vital methodology for meeting these challenges.
Abstract is here: http://onlinelibrary.wiley.com/doi/10.1002/met.285/abstract
Full paper is here: http://www.met.reading.ac.uk/~sgs02rpa/PAPERS/Allan11MA.pdf
UPDATE: Some people in comments including Dr. Roy Spencer, (and as I was writing this, Dr. Richard Allan) suggest that the paper isn’t about feedback (at least in the eyes of IPCC interpretations, but Spencer adds “it could be”). Thus I’ve removed the word from the headline to satisfy such complaints. My view is that clouds are both a feedback and a forcing. Others disagree. That’s an issue that will occupy us all for sometime I’m sure.
Regarding cloud feedbacks, here’s what I noted in the paper in section 6, near the end. Allan is referring to figure 7 which shows (a) net radiation and (b) net cloud radiative forcing:
Substantial negative anomalies in net radiative flux from ERA Interim are apparent in 1998 and 2010, both El Niño years, suggesting that the substantial re-organization of atmospheric and oceanic circulation systems act to remove energy from Earth during these periods.
You can clearly see the famous double peak in the 1998 El Niño, but it is inverted. To me that looks like a thermostat action, and not one with stuck electrical contacts, i.e. a negative feedback. I’ve also updated the text related to the incorrect comparison I made. – Anthony
While that statement is true, I am pretty sure that Hansen, Ruedy, Sato and Lo did predict a monotonic decade on decade rise:
http://www.columbia.edu/~jeh1/mailings/2010/20100601_TemperaturePaper.pdf
Correct me if I’m mistaken. GK
John B,
You are getting totally desperate. Not surprising, since the planet isn’t doing what you want it to. In fact, it is doing what the rest of us want it to. Rarely has the planet’s temperature been so steady and unchanging for so long.
Forget the grant chasing charlatans who “run the numbers” in their computer models. If CO2 had a significant effect, then temperature would closely follow CO2. But it doesn’t. The insignificant [and entirely beneficial] warming from added CO2 is very likely around 1°Cx2CO2 ± 0.5°. That’s nothing to be worried about.
Joe Born. Also in order for your hypothesis to be true… then the amount of additional warming caused by changes in cloud cover MUST be less than the original amount of warming caused by CO2. Thus by your own admission, the net climate sensitivity factor for warming due to CO2 must be less than 2x the CO2 alone. Thus we have a maximum upper bounds of ~1.4C increase for a doubling of CO2. And if clouds are a net negative (most likely case)…. then it is even less than 1.4C.
@JohnB
I respectfully suggest you look at the numbers for yourself – particularly at things like the radiative absorption spectra of all the different GHG’s etc, etc – CO2 is far less than H2O for example….
I don’t wish to be belligerent – but I was the same as you a few years ago. I’d read the media reports and ‘accepted’ the promoted concensus (stupidly believing that the media were probably unbiased!). It was only by chance, really, that I started to look into it deeper (a long story – but I was curious as to the energy budget values). As soon as I saw conclusion after conclusion being unsubstantiated or based on this guess and that guess, this model and that model, etc, I realised it was not ‘settled’ and to be honest, that’s when I became angry. MY area of science, geology and earth sciences, had been ‘contaminated’ with bad unprofessional work (IMO) and the political promotion (and funding grabbing!) was obvious….when you tie that to the likely economic outcomes from the potential AGW ‘protectionist’ policies – I get doubly angry. Then you get the likes of Climategate and the Hockey Stick – and hey, I’m my own little Vesuvius! I hate being misled, and I am now a confirmed skeptic – because the current science has made me that way. If it was so obviously settled, hey, I’d be with you – but I have my professional opinion, and it is not alongside those of the warmists. If the promoted AGW was so clear cut and beyond reasonable doubt, we would not even be here……because the case would be so obvious…. why is it not so?
G. Karst says:
September 20, 2011 at 2:30 pm
John B says:
September 20, 2011 at 1:07 pm
…That is why climate scientists are confident warming will resume. Nobody ever predicted a monotonic, year-on-year rise…
While that statement is true, I am pretty sure that Hansen, Ruedy, Sato and Lo did predict a monotonic decade on decade rise:
http://www.columbia.edu/~jeh1/mailings/2010/20100601_TemperaturePaper.pdf
‘(6) global warming on decadal time scales is continuing without letup. Figure 8, showing decadal mean temperature anomalies, effectively illustrates the monotonic and substantial warming that is occurring on decadal time scales. But because it is important to draw attention to change as soon as possible, we need ways to make the data trends clear without waiting for additional decades to pass.’2010
Correct me if I’m mistaken. GK
———————-
You are not mistaken. And on “decadal timescales” it is still true. the 2000’s were warmer than the 1990’s and the 2010’s will likely be warmer than the 2000’s You can even see that in the chart Smokey linked, if you look at it honestly.
And Smokey: desperation no, frustration maybe.
Not true. Forcing can be any external influence on the system. If cosmic radiation can lever heat from the sun, cosmic radiation is a forcing to that system. It’s not the energy source, but it’s the forcing in that particular system. Forcing and energy source aren’t the same thing. This is why CO2 can be a forcing without furnishing any energy. It levers energy.
Kev-in-Uk says:
September 20, 2011 at 2:41 pm
@JohnB
…
If the promoted AGW was so clear cut and beyond reasonable doubt, we would not even be here……because the case would be so obvious…. why is it not so?
————————
Not sure if you really want an anwser to that, but here is my opinion. The science is sound. Not settled, as science never is, but sound. Why do some people not accept it? Well, some are simply misled by plausible sounding arguments from incredulity (e.g. “how can a trace gas possibly make a difference?”) while for many others I think it is ideological. Primarily, what this group hate is the thought of big government intevention, or whatever it is they wrongly perceive as the ideological basis of climate science. They see AGW as a liberal/socialist-led scam and then are forced to find ways of denigrating the science so as to avoid cognitive dissonance. And still others are just in it to make money – e.g. the ones who write books on the subject.
And of course, AGW is not the only mainstream-accepted idea that attracts contrarians. There are plenty of people who don’t accept evolution, the moon landings, Obama’s nationality, you name it.
John B says:
September 20, 2011 at 2:47 pm
decadal timescales? for millenial changes? You clearly miss the fundemental point that if we have a temp of X deg 10000 yrs ago (Ice Age) – and an increased temp Y of today (not in an ice age) – on the millenial scale, temps MUST have increased decade upon decade, century upon century! Granted, there will have been some cyclical variation due to Milankovitch, etc, etc – but the average temps will ALWAYS be increasing – at least until we start the next ice age period, in which case they will ALWAYS be decreasing…..Hence, the temp rising argument is NOT definitive proof of an anthropogenic influence IMO. Period. It may be an indicator, but even that has been thrown in the ‘doubt’ pile after the fact that despite further increased CO2 over the last decade+ – there has been no significant warming……Period. I won’t even bother with the ‘global temp is a futile metric /fallacy’ point – because that should be relatively obvious to anyone with half a brain – and if we then discussed the measuring methods.. well, you wouldn’t have a leg to stand on! The uncertainty levels go through the roof.
I’ll leave it there – apologies to all other readers if I have had to state the bleedin obvious – and yes, I know, I should not have taken the bait! Sorry.
Kev says: “but the average temps will ALWAYS be increasing”
So, how did we get from the MWP to the LIA?
Joe Zeise says:
and a cloudy night is warmer then a clear sky night.
Only if the preceding day was warm.
Try the situation where you get a clear, cold night, followed by cloud cover the next day.
The following night is going to be cold regardless of whether or not there is cloud cover and it is not going to warm up till you get some direct sun during the day.
ChE says:
September 20, 2011 at 2:51 pm
“If cosmic radiation can lever heat from the sun, cosmic radiation is a forcing to that system.”
Already covered that.
Dave Springer says:
September 20, 2011 at 10:33 am
Dave,
Thanks for responding to my questions. Your explanation regarding long wave radiation makes sense. However, I was really asking about the meaning of the paper. I quoted from the paper (both the abstract and the conclusion) where Allan, the author of the paper, is talking about feedback. It is surprising to me that Spencer and Allan would come here to say the paper is not about feedback when Allan mentions “feedback” nine times in the article. The article certainly says something about feedback. But I still think I am missing something.
Here, I may be mistaken, BUT wouldn’t 1998 – 2008 or also be on “decadal timescales” or ANY sequential 10 yr period, for that matter. Why would you bias to the calender arbitrary decade demarcation? GK
John B – stop being deliberately obtuse. MWP and LIA were shorter term variations in what has been a relentless long term upwards trend – and you know that is the case. To suggest that the past thirty years are significant, when for nearly ten of those tenos have been almost static, is ludicrous.
tenos = temps
John B. wrote: The science is sound. Not settled, as science never is, but sound. Why do some people not accept it?
First, the science is incomplete: one example that is not well understood is illustrated by today’s publication; the role of CO2 in modulating (if it does) the clouds is not well known. Would an increase in CO2 increase the rate at which clouds formed on sunny days and those clouds cooled the evenings — causing a net reduction in mean temperature? Would it have no effect whatsoever? Answers to these questions have not been demonstrated to be true.
Second, most of the projections of the future, if not all of them, are based on models that, one way or another, are simplifications of the actual relationships. If the inaccuracy of such necessary simplifications is negligibly small, such has not been demonstrated to date. Instead, the available models have over-predicted temperature rise over the last decades, and kludges have been added to the models to “account for the missing heat”, an example of which is presented on another thread at WUWT today.
Alcheson says:
September 20, 2011 at 2:39 pm
“Also in order for your hypothesis to be true …the amount of additional warming caused by changes in cloud cover MUST be less than the original amount of warming caused by CO2.”
Well, yes and no. Pay careful attention here, because the point is perhaps subtler than I had imagined.
Yes, if instability is to be avoided, the warming caused by cloud-cover change in response to *only* the temperature change the CO2 caused does indeed have to be less than the temperature change the CO2 alone caused. But this does not include the follow-on increase that occurs when the clouds additionally respond to the temperature changes they caused themselves. When that is included, then the cloud effects can, in theory, be greater than the CO2 effect alone yet avoid runaway. This tail-chasing behavior means that if r is the fraction the initial response–one-half in the thought experiment above–then the ultimate change is 1/(1-r), i.e., two in the thought experiment above.
Again, I’m not saying that’s what happens in real life. I’m just saying that your argument is not exactly bullet-proof.
Werner Brozek says:
September 20, 2011 at 10:04 am
“NetDr says:
September 20, 2011 at 6:54 am
Negative feedback drives the temperature back to it’s “set point”.
Warming causes cooling and cooling causes warming.”
Since Earth is relatively stable temperature wise, would you say Le Chatelier’s principle applies on a global scale so that whatever changes
******************
The short answer is yes !
The feeble early sun paradox says that the sun was 25 % dimmer in the distant past but the temperature was about the same. [No there was no huge amount of CO2 to compensate]
A strongly negative feedback system is highly resistant to change up or down.
Which is why I’m a hard-core Denier, and sneer at lukewarmists, and all who say CO2 will produce at least a little warming. The negative cloud effect is more than enough to easily “overshoot” and overwhelm any warming “impulse” from CO2.
There is NO CO2 GHE.
. Karst says:
September 20, 2011 at 3:50 pm
John B says:
September 20, 2011 at 2:47 pm
You are not mistaken. And on “decadal timescales” it is still true. the 2000′s were warmer than the 1990′s and the 2010′s will likely be warmer than the 2000′s
Here, I may be mistaken, BUT wouldn’t 1998 – 2008 or also be on “decadal timescales” or ANY sequential 10 yr period, for that matter. Why would you bias to the calender arbitrary decade demarcation? GK
——————————-
Yes, of course the calendar decades shouldn’t matter. But that is not to say that “1998 was warmer than 2008” means anything either. We should look at 10 year running averages, like this:
http://www.thenrgroup.net/news/images/Average-Global-Temperature.gif
Jason says:
September 20, 2011 at 3:59 pm
John B – stop being deliberately obtuse. MWP and LIA were shorter term variations in what has been a relentless long term upwards trend – and you know that is the case. To suggest that the past thirty years are significant, when for nearly ten of those tenos have been almost static, is ludicrous.
——————–
Jason, I was responding to Kev-in-UK, who said “temps MUST have increased decade upon decade”
Clearly not so.
so:
“John B says:
September 20, 2011 at 3:14 pm
Kev says: “but the average temps will ALWAYS be increasing”
So, how did we get from the MWP to the LIA?”
How did we get from the MWP, to the LIA? And how did we get out of the LIA? Wasn’t the level of CO2 monotonous, during that period?
Suggested answer: There was no MWP, or LIA. (Am I close?)
“Large negative cooling effect”. Hmmm … Negative cooling means warming, this look like an unnecessary double negative. Maybe Anthony should revise the title again 🙂 e.g. lose the “negative”.
Or did logic die with Aristotle?
Multi-institutional study group finds strong negative-feedback cooling effect from clouds
http://hockeyschtick.blogspot.com/2011/09/multi-institutional-study-group-finds.html
The Newsletter of the multi-institution Climate Process Team on Low-Latitude Cloud Feedbacks on Climate Sensitivity outlines their significant findings to date:
1. Clouds have a strong negative-feedback cooling effect on climate in both the tropics and extra-tropics
2. A warmer climate enhances [increases] boundary layer clouds resulting in increasing negative-feedback
3. Due to this strong negative-feedback, global climate sensitivity is only 0.41 K/(W m-2) – FAR less than the 3.7 W/m2 + assumed by the IPCC
Introduction:
The Climate Process Team on Low-Latitude Cloud Feedbacks on Climate Sensitivity (cloud CPT) includes three climate modeling centers, NCAR, GFDL, and NASA’s Global Modeling and Assimilation Office (GMAO), together with 8 funded external core PIs led by Chris Bretherton of the University of Washington (UW). Its goal has been to reduce uncertainties about the feedback of low-latitude clouds on climate change as simulated in atmospheric general circulation models (GCMs). To coordinate this multi-institution effort, we have hired liaison scientists at NCAR and GFDL, had regular teleconferences and annual meetings, and developed special model output datasets for group analysis. The cloud CPT web site http://www.atmos.washington.edu/~breth/CPT-clouds.html provides links to all its publications and activities. The cloud CPT has had many interesting subplots; here we focus on two of interesting recent results and its future plans. The results showcase a key CPT strategy – gaining insight from the use of several complementary modeling perspectives on the cloud feedbacks problem.
Two recent findings of the cloud CPT:
(1) The world’s first superparameterization climate sensitivity results show strong negative cloud feedbacks driven by enhancement of boundary layer clouds in a warmer climate.
Superparameterization is a recently developed form of global modeling in which the parameterized moist physics in each grid column of an AGCM is replaced by a small cloud-resolving model (CRM). It holds the promise of much more realistic simulations of cloud fields associated with moist convection and turbulence. Superparameterization is computationally expensive, but multiyear simulations are now feasible. The Colorado State University and UW cloud CPT groups collaborated on the first climate sensitivity analysis of a superparameterized AGCM (Wyant et al. 2006b). The Khairoutdinov-Randall (2001, 2005) superparameterized CAM3, hereafter CAM-SP, was used. Each CRM in CAM-SP has the same vertical levels as CAM3, 4 km horizontal resolution, and one horizontal dimension with 32 horizontal gridpoints.
Following Cess et al. (1989), climate sensitivity was assessed by examining the TOA radiative response to a uniform SST increase of 2K, based on the difference between control and +2K 3.5 year CAMSP simulations. Fig. 2 compares the results to standard versions of the NCAR CAM3, GFDL AM2 and GMAO AGCMs. All these models have similar clear-sky responses, so we just plot the +2K changes in longwave (greenhouse) and shortwave (albedo) cloud radiative forcings (ΔLWCF and ΔSWCF). Since ΔSWCF tends to be larger than ΔLWCF. boundary-layer cloud changes (which have little greenhouse effect compared to their albedo enhancement) appear to be particularly important. The CAM-SP shows strongly negative net cloud feedback in both the tropics and in the extratropics, resulting in a global climate sensitivity of only 0.41 K/(W m-2), at the low end of traditional AGCMs (e.g. Cess et al. 1996), but in accord with an analysis of 30- day SST/SST+2K climatologies from a global aquaplanet CRM run on the Earth Simulator (Miura et al. 2005). The conventional AGCMs differ greatly from each other but all have less negative net cloud forcings and correspondingly larger climate sensitivities than the
superparameterization. The coarse horizontal and vertical resolution of CAM3-SP means that it highly under-resolves the turbulent circulations that produce boundary layer clouds. Thus, one should interpret its predictions with caution. With this caveat, cloud feedbacks are arguably more naturally simulated by superparameterization than in conventional AGCMs [conventional climate models], suggesting a compelling need to better understand the differences between the results from these two approaches.
John B says:
September 20, 2011 at 2:06 pm
Except that there has been no trend in GCRs, so even if GCRs did cause clouds to form, which is still merely conjecture, it would be irrelevant.
There is no trend in GCRs? They change with every sunspot cycle. You are assuming the average is the controlling factor, but why would it be? The are the extremes and the rate of change. These are more likely controlling. Physical phenomenon operate on local and immediate conditions, not trends or averages.
The science is incomplete on cloud formation, which means the science is not settled. If cloud feedback is negative, the models must be tweaked. The results will not please those that believe CO2 if the major factor in earth’s temperatures.