By Dr. Roy Spencer, PhD (reprinted from his blog with permission)
UPDATE (12:35 p.m. CDT 19 May 2011): revised corrections of CERES data for El Nino/La Nina effects.
While I have been skeptical of Svensmark’s cosmic ray theory up until now, it looks like the evidence is becoming too strong for me to ignore. The following results will surely be controversial, and the reader should remember that what follows is not peer reviewed, and is only a preliminary estimate.
I’ve made calculations based upon satellite observations of how the global radiative energy balance has varied over the last 10 years (between Solar Max and Solar Min) as a result of variations in cosmic ray activity. The results suggest that the total (direct + indirect) solar forcing is at least 3.5 times stronger than that due to changing solar irradiance alone.
If this is anywhere close to being correct, it supports the claim that the sun has a much larger potential role (and therefore humans a smaller role) in climate change than what the “scientific consensus” states.
BACKGROUND
The single most frequently asked question I get after I give my talks is, “Why didn’t you mention the sun?” I usually answer that I’m skeptical of the “cosmic ray gun” theory of cloud changes controlling climate. But I point out that Svensmark’s theory of natural cloud variations causing climate change is actually pretty close to what I preach — only the mechanism causing the cloud change is different.
Then, I found last year’s paper by Laken et al. which was especially interesting since it showed satellite-observed cloud changes following changes in cosmic ray activity. Even though the ISCCP satellite data they used are not exactly state of the art, the study was limited to the mid-latitudes, and the time scales involved were days rather than years, the results gave compelling quantitative evidence of a cosmic ray effect on cloud cover.
With the rapid-fire stream of publications and reports now coming out on the subject, I decided to go back and spend some time analyzing ground-based galactic cosmic ray (GCR) data to see whether there is a connection between GCR variations and variations in the global radiative energy balance between absorbed sunlight and emitted infrared energy, taken from the NASA CERES radiative budget instruments on the Terra satellite, available since March 2000.
After all, that is ultimately what we are interested in: How do various forcings affect the radiative energy budget of the Earth? The results, I must admit, are enough for me to now place at least one foot solidly in the cosmic ray theory camp.
THE DATA
The nice thing about using CERES Earth radiative budget data is that we can get a quantitative estimate in Watts per sq. meter for the radiative forcing due to cosmic ray changes. This is the language the climate modelers speak, since these radiative forcings (externally imposed global energy imbalances) can be used to help calculate global temperature changes in the ocean & atmosphere based upon simple energy conservation. They can then also be compared to the estimates of forcing from increasing carbon dioxide, currently the most fashionable cause of climate change.
From the global radiative budget measurements we also get to see if there is a change in high clouds (inferred from the outgoing infrared measurements) as well as low clouds (inferred from reflected shortwave [visible sunlight] measurements) associated with cosmic ray activity.
I will use only the ground-based cosmic ray data from Moscow, since it is the first station I found which includes a complete monthly archive for the same period we have global radiative energy budget data from CERES (March 2000 through June 2010). I’m sure there are other stations, too…all of this is preliminary anyway. Me sifting through the myriad solar-terrestrial datasets is just as confusing to me as most of you sifting through the various climate datasets that I’m reasonably comfortable with.
THE RESULTS
The following plot (black curve) shows the monthly GCR data from Moscow for this period, as well as a detrended version with 1-2-1 averaging (red curve) to match the smoothing I will use in the CERES measurements to reduce noise.
Detrending the data isolates the month-to-month and year-to-year variability as the signal to match, since trends (or a lack of trends) in the global radiative budget data can be caused by a combination of many things. (Linear trends are worthless for statistically inferring cause-and-effect; but getting a match between wiggles in two datasets is much less likely to be due to random chance.)
The monthly cosmic ray data at Moscow will be compared to global monthly anomalies the NASA Terra satellite CERES (SSF 2.5 dataset) radiative flux data,
which shows the variations in global average reflected sunlight (SW), emitted infrared (LW), and Net (which is the estimated imbalances in total absorbed energy by the climate system, after adjustment for variations in total solar irradiance, TSI). Note I have plotted the variations in the negative of Net, which is approximately equal to variations in (LW+SW)
Then, since the primary source of variability in the CERES data is associated with El Nino and La Nina (ENSO) activity, I subtracted out an estimate of the average ENSO influence using running regressions between running 5-month averages of the Multivariate ENSO Index (MEI) and the CERES fluxes. I used the MEI index along with those regression coefficients in each month to correct the CERES fluxes 4 months later, since that time lag had the strongest correlation.
Finally, I performed regressions at various leads and lags between the GCR time series and the LW, SW, and -Net radiative flux time series, the results of which are shown next.
The yearly average relationships noted in the previous plot come from this relationship in the reflected solar (SW) data,
while the -Net flux (Net is absorbed solar minus emitted infrared, corrected for the change in solar irradiance during the period) results look like this:
It is that last plot that gives us the final estimate of how a change in cosmic ray flux at Moscow is related to changes in Earth’s radiative energy balance.
SUMMARY
What the above three plots show is that for a 1,000 count increase in GCR activity as measured at Moscow (which is somewhat less than the increase between Solar Max and Solar Min), there appears to be:
(1) an increase in reflected sunlight (SW) of 0.64 Watts per sq. meter, probably mostly due to an increase in low cloud cover;
(2) virtually no change in emitted infrared (LW) of +0.02 Watts per sq. meter;
(3) a Net (reflected sunlight plus emitted infrared) effect of 0.55 Watts per sq. meter loss in radiant energy by the global climate system.
WHAT DOES THIS MEAN FOR CLIMATE CHANGE?
Assuming these signatures are anywhere close to being real, what do they mean quantitatively in terms of the potential effect of cosmic ray activity on climate?
Well, just like any other forcing, a resulting temperature change depends not only upon the size of the forcing, but also the sensitivity of the climate system to forcing. But we CAN compare the cosmic ray forcing to OTHER “known” forcings, which could have a huge influence on our understanding of the role of humans in climate change.
For example, if warming observed in the last century is (say) 50% natural and 50% anthropogenic, then this implies the climate system is only one-half as sensitive to our greenhouse gas emissions (or aerosol pollution) than if the warming was 100% anthropogenic in origin (which is pretty close to what we are told the supposed “scientific consensus” is).
First, let’s compare the cosmic ray forcing to the change in total solar irradiance (TSI) during 2000-2010. The orange curve in following plot is the change in direct solar (TSI) forcing between 2000 and 2010, which with the help of Danny Braswell’s analytical skills I backed out from the CERES Net, LW, and SW data. It is the only kind of solar forcing the IPCC (apparently) believes exists, and it is quite weak:
Also shown is the estimated cosmic ray forcing resulting from the month-to-month changes in the original Moscow cosmic ray time series, computed by multiplying those monthly changes by 0.55 Watts per sq. meter per 1,000 cosmic ray counts change.
Finally, I fitted the trend lines to get an estimate of the relative magnitudes of these two sources of forcing: the cosmic ray (indirect) forcing is about 2.8 times that of the solar irradiance (direct) forcing. This means the total (direct + indirect) solar forcing on climate associated with the solar cycle could be 3.8 times that most mainstream climate scientists believe.
One obvious question this begs is whether the lack of recent warming, since about 2004 for the 0-700 meter layer of the ocean, is due to the cosmic ray effect on cloud cover canceling out the warming from increasing carbon dioxide.
If the situation really was that simple (which I doubt it is), this would mean that with Solar Max rapidly approaching, warming should resume in the coming months. Of course, other natural cycles could be in play (my favorite is the Pacific Decadal oscillation), so predicting what will happen next is (in my view) more of an exercise in faith than in science.
In the bigger picture, this is just one more piece of evidence that the IPCC scientists should be investigating, one which suggests a much larger role for Mother Nature in climate change than the IPCC has been willing to admit. And, again I emphasize, the greater the role of Nature in causing past climate change, the smaller the role humans must have had, which could then have a profound impact on future projections of human-caused global warming.
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tallbloke wrote (May 21, 2011 at 9:25 am) “the variation is much greater than the higher frequency annual variation.”
This can’t be right.
Stephen Wilde wrote (May 21, 2011 at 9:12 am):
“The outcome of that struggle at any given moment being reflected in the surface pressure distribution (especially the position and behaviour of the midlatitude jets) which has an effect on the size and position of the various climate zones.
The regions that see most in the way of climate changes are those situated at or near a climate zone boundary so that as the surface pressure changes vary those regions cross from one side to another of those boundaries for variable lengths of time.”
The level of discussion is elevating.
[Next, if we could just get people to stop ignoring seasons…]
Leif Svalgaard said:
“Paul, I think you missing an important element of the lags. Invoking unknown [even variable] lags of several decades are an efficient shield against falsification.”
No, they do however make verification more difficult.
Is it denied that variable lags exist ?
Leif is a proponent of the idea that ALL climate variability is internally generated.
Does he really propose such an all powerful internal system variability as that AND deny the existence of variable lags despite the fluid nature of the oceans with their complex internal structure ?
Lets see what Leif is proposing:
i) Solar effects limited to 0.1C from cycle to cycle and no significant solar effect from changes in the level of solar activity over centuries such as from LIA to date.
ii) No significant variable internal system lags despite deep oceans with a complex and largely unknown internal thermal structure and behaviour.
Effectively Leif is excluding both sun AND oceans as potential climate forcing agents over multidecadal periods of time.
Very helpful to the AGW lobby but not to anyone else.
Leif, if the sun doesn’t do it and there are no multidecadal variable lags generated internally then what would be your next logical step in explaining multidecadal climate variability ?
Haven’t you painted yourself into a corner ?
Leif Svalgaard says:
May 21, 2011 at 9:23 am
What he plots is not what he says he plotted as I just showed.
We can see in Roy’s excellent graphs what he plotted. We don’t need your mischaracterisation of what they show.
Unlike some who have looked at this in detail [not preliminary and not with deficient data analysis] and found it wanting and the evidence unconvincing.
Hah! We’ll see. CLOUD will have more results soon, and the Aahus results are looking very good too.
http://calderup.wordpress.com/2011/05/15/accelerator-results-on-cloud-nucleation/
The days of your pooh-poohing Svensmark are numbered. Enjoy them while you can.
Paul Vaughan says:
May 21, 2011 at 9:35 am
tallbloke wrote (May 21, 2011 at 9:25 am) “the variation is much greater than the higher frequency annual variation.”
This can’t be right.
I mean the variation in ocean heat content (to, say, 700m), not surface temperature.
“[Next, if we could just get people to stop ignoring seasons…]”
I had assumed that everyone knew that I was referring to shifts beyond normal seasonal variation.
Such as :
http://www.msnbc.msn.com/id/24228037/
and more recently:
http://poleshift.ning.com/profiles/blogs/earth-wobble-jet-stream
tallbloke says:
May 21, 2011 at 9:46 am
We can see in Roy’s excellent graphs what he plotted. We don’t need your mischaracterisation of what they show.
But unless you redo what he said he did, you won’t see that what he plotted is not what he said he plotted. Here is an overlay: http://www.leif.org/research/Moscow-2000-2011-compare.png to help you over your denial.
I really wish that there was a link between solar activity and climate. That would make my field all that more relevant [help improve funding too], but, alas, 400 years [almost 150,000 days] of claims have not gotten us any closer. One may hope that the number of days until my field becomes the foundation of climate science is indeed small.
tallbloke, LINEAR cross-correlation UNDERestimates (SEVERELY) the strength of relations among interannual terrestrial oscillations …and it also invites nonsensical MISinterpretations of lags [including interannual & multidecadal ones].
Additionally, basing LINEAR decompositions on ENSO causes related estimation problems ….for one truly simple example, even the interannual component of AMO LINEARLY correlates more strongly with global surface T than does ENSO – should be a nobrainer to climate discussion enthusiasts who understand the role of high-amplitude regional variance in global summaries, but we see clearly in these discussions that it is not.
Upshot: Complex numbers are needed in the study of phase relations.
As regards my post of 9.58 a m I do not share the idea that there is an Earth ‘wobble’ or a pending pole shift. The link is merely to demonstrate the extent of the recent jetstream shifting whilst solar activity was low.
Paul Vaughan says:
May 21, 2011 at 9:39 am
[Next, if we could just get people to stop ignoring seasons…]
The seasonal changes in insolation and the resulting north-south differentials are a vital aspect of the heat pump which drives the mixing of solar energy in the oceans.
tallbloke wrote (May 21, 2011 at 9:56 am) “I mean the variation in ocean heat content (to, say, 700m), not surface temperature.”
Still can’t be right. Let’s just efficiently call it a “misunderstanding” and move on to more productive pursuits than protracted exchanges (that no sensible person bothers to read under normal circumstances).
Leif Svalgaard says:
May 21, 2011 at 10:00 am
Here is an overlay: http://www.leif.org/research/Moscow-2000-2011-compare.png to help you over your denial.
Looks pretty similar to your green curve.
I really wish that there was a link between solar activity and climate. That would make my field all that more relevant [help improve funding too], but, alas, 400 years [almost 150,000 days] of claims have not gotten us any closer.
Dear Leif, I hope you are still around when our theory is fully developed and accepted. Even though your own efforts are aimed at preventing this happening.
One may hope that the number of days until my field becomes the foundation of climate science is indeed small.
Hurrah! 🙂
Stephen Wilde says:
May 21, 2011 at 9:40 am
Leif, if the sun doesn’t do it and there are no multidecadal variable lags generated internally then what would be your next logical step in explaining multidecadal climate variability ?
I don’t know about any internal lags, just fluctuations. I don’t think there are any lags, but none are needed. There are large internal fluctuations [and by internal I include volcanoes – I don’t see the effect of Pinatubo showing up twenty years down the road]. So, you propose that there is some change in the ocean heat content and that as a result the climate changes several decades later.
‘Lags’ are but a convenient rug to shove things under.
tallbloke says:
May 21, 2011 at 10:17 am
Looks pretty similar to your green curve.
Is not the point. In this business there must be an exact match. I take the same data, detrend, smooth the prescribed way 1-2-1, and get a different result. So what is he not telling?
Dear Leif, I hope you are still around when our theory is fully developed and accepted.
It has failed so far for more than 150 years, so perhaps none of us will be around.
Leif Svalgaard says:
May 21, 2011 at 10:18 am
So, you propose that there is some change in the ocean heat content and that as a result the climate changes several decades later.
About one decade later. As you and I discussed on Climate Audit nearly 3 years ago.
“I don’t know about any internal lags, just fluctuations.”
Then we are agreed because to my mind internal system fluctuations must result in a lagged system response to solar input.
The climate doesn’t just ‘change several decades later’. One fluctuation segues into the next in a constant process and the solar and oceanic fluctuations modulate each other.
At the surface and in the short term random chaotic variability does the rest.
tallbloke says:
May 21, 2011 at 10:25 am
About one decade later.
So, the ocean heat content changes [that is: the oceans have already heated up] and then ten years later the atmosphere [the ‘climate’] changes? apart from ‘climate’ being a 30-yr thing [but let that slide].
tallbloke wrote (May 21, 2011 at 10:08 am):
“The seasonal changes in insolation and the resulting north-south differentials are a vital aspect of the heat pump which drives the mixing of solar energy in the oceans.”
Explicit acknowledgement that the oceans don’t produce their own heat. This is progress.
Mention of “insolation” in the same sentence as “oceans”. A welcome development.
(Neither sarcasm nor disrespect intended.)
Stephen Wilde wrote (May 21, 2011 at 9:58 am):
“I had assumed that everyone knew that I was referring to shifts beyond normal seasonal variation.”
This is what I’m getting at – and it’s FUNDAMENTALLY important:
a) Exposition of p. 433 [pdf p.10]:
Sidorenkov, N.S. (2005). Physics of the Earth’s rotation instabilities. Astronomical and Astrophysical Transactions 24(5), 425-439.
http://images.astronet.ru/pubd/2008/09/28/0001230882/425-439.pdf
b) Figures 8, 11, 13, & 15:
Leroux, Marcel (1993). The Mobile Polar High: a new concept explaining present mechanisms of meridional air-mass and energy exchanges and global propagation of palaeoclimatic changes. Global and Planetary Change 7, 69-93.
http://ddata.over-blog.com/xxxyyy/2/32/25/79/Leroux-Global-and-Planetary-Change-1993.pdf
–
Until people take the time to conceptually understand (a) & (b) in concert with north-south continental-maritime asymmetry, they’ll likely not understand the following:
1) http://wattsupwiththat.files.wordpress.com/2010/12/vaughn_lod_fig1a.png
2) http://wattsupwiththat.files.wordpress.com/2010/12/vaughn_lod_fig1b.png
3) http://wattsupwiththat.files.wordpress.com/2010/08/vaughn_lod_amo_sc.png
4) http://wattsupwiththat.files.wordpress.com/2010/09/scl_northpacificsst.png
5) http://wattsupwiththat.files.wordpress.com/2010/09/scl_0-90n.png
…where SCL’ = rate of change of solar cycle length = solar cycle deceleration ….not to be confused with solar cycle length, which has a correlation of almost zero with SCL’ (…which shouldn’t come as a surprise to anyone who understands complex [as in complex numbers, not as in complicated] phase relations).
I tend towards Leif’s view of fluctuations being the rule, rather than the exception. Trade winds have a near immediate affect on sea surface temperature. The sea surface temperature has a near immediate affect on incoming weather systems. Weather pressure systems have a near immediate affect on temperature variations, humidity, and so on.
Overriding these day to day, week to week, month to month, and year to year variations are oscillations one sees in oceanic and atmospheric circulation patterns. I can only guess that the “lags” people talk about are somehow involved in these oscillations as they switch from one mode to the other. It would take a powerful driver to do that, if what you seek is an external driver.
However, it seems to me that instead of “flipping” or being driven from one mode to the other, I see more a petering out of the energy needed to sustain one mode as it fades into the alternate mode.
tallbloke says:
May 21, 2011 at 7:18 am
Leif Svalgaard says:
May 21, 2011 at 10:31 am
tallbloke says:
May 21, 2011 at 10:25 am
About one decade later.
So, the ocean heat content changes [that is: the oceans have already heated up] and then ten years later the atmosphere [the ‘climate’] changes? apart from ‘climate’ being a 30-yr thing [but let that slide].
What happens is when the sun gets active, the oceans go into ‘mixing down’ mode. Ten years later when the solar cycle is just past minimum, the oceans go into ‘heat release’ mode and that’s when big el nino’s occur that cause upward step changes in surface temperature which persist during positive phases of oceanic cycles. Then after the oceanic cycle peaks and the solar cycles are getting smaller the reverse happens. The big la nina we have just been through hasn’t caused a big downshift in surface temperature, because it followed on the heels of a big El nino, but the next one will. 2013 onwards will see things getting chillier. A decade after the sun started getting quiet in 2003.
Wait and see if I’m wrong.
Ignoring all the oscilliations I simply did a linear regression of the temperatures recorded on a mumner of weather stations from all over the world since 1974. Here are my results:
MAXIMA: rising at a speed of 0.04 degrees C per annum
MEANS : increasing at a speed of 0.02 degrees C per annum
MINIMA: no change at 0.00 degrees C per annum
HUMIDITY: decreasing at a rate of -0.02% per annum
PRECIPITATION: decreasing at a rate of -0.11 mm /month /year
This means that, on my pool table, the global warming that is observed on earth is simply coming from outside and is not caused by an increase in greenhouse gases or any human influences.
Not so?
http://www.letterdash.com/HenryP/henrys-pool-table-on-global-warming
tallbloke says:
May 21, 2011 at 10:25 am
About one decade later.
As so clearly seen here: http://www.leif.org/research/Temp-Solar-Lag.png ?
Stephen Wilde asked (May 21, 2011 at 9:40 am):
“Is it denied that variable lags exist ?”
No, it’s just not a concept with practical utility for sensibly assessing phase relations (worse than that, it invites naive nonsensical misinterpretation). Linear methods are patently insufficient. If one switches one’s conceptualization of phase relations to the eminently more equipped complex plane then (a) lags vanish and (b) correlations go up dramatically. Additionally, everything becomes simple instead of complicated.
John Finn says:
May 21, 2011 at 10:45 am
Ok – so I assume, since the late 1700s had high solar activity, the Dalton Minimun period (1790-1820) was warm – or perhaps the Svensmark effect only affects the late 20th century climate?
Your dating of the Dalton minimum is in error.
We know there were some cold winters in Northern Europe after 1804 We don’t know much about the rest of the world at that time. Multidecadal north-south oscillations play a part too. We’ll have to go on periods for which we have sufficiently useful data.
Having said that, Jasper’s comparison of north atlantic surface temps and Be10 deposition in Greenland is pretty convincing. I won’t bother trying to convince you though.