Guest Post by Willis Eschenbach
In investigations of the past history of cosmic rays, the deposition rates (flux rates) of the beryllium isotope 10Be are often used as a proxy for the amount of cosmic rays. This is because 10Be is produced, inter alia, by cosmic rays in the atmosphere. Being a congenitally inquisitive type of fellow, I thought I’d look to see just how good a proxy 10Be might be for solar activity. Now most folks would likely do a search of the literature first, to find out what is currently known about the subject.
I don’t like doing that. Oh, the literature search is important, don’t get me wrong … but I postpone it as long as I possibly can. You see, I don’t want to be mesmerized by what is claimed to be already known. I want to look whatever it is with a fresh eye, what the Buddhists call “Beginner’s Mind”, unencumbered by decades of claims and counter-claims. In short, what I do when faced with a new field is to go find some data and analyze it. After I’ve found out what I can from the dataset, and only then, do I search the literature to find out what other folks might believe. Yes, it costs me sometimes … but usually it allows me to find things that other folks have overlooked.
In this case, I found a gem of a dataset. Here is the author’s summary:
Annually-resolved polar ice core 10Be records spanning the Neutron Monitor era
Abstract: Annually-resolved 10Be concentrations, stable water isotope ratios and accumulation rate data from the DSS site on Law Dome, East Antarctica (spanning 1936-2009) and the Das2 site, south-east Greenland (1936-2002).
The only thing better than data is recent data, because it is more likely to be accurate, and here we have seven decades of recent 10Be deposition rates (fluxes). So, without fanfare, here’s the data in question
Figure 1. 10Be flux rates from Law Dome in Antarctica and from Southeast Greenland. Bottom panel shows the annual average sunspot count.
So … what’s not to like about these records? Well … lots of things.
The first unlikable item is that the correlation between these two 10Be datasets is pathetic, only 0.07. Seems to me like this would be enough in itself to put the whole 10Be—cosmic rays connection into doubt. I mean, if the two best recent dataset don’t agree with each other, then what are we supposed to believe?
The next problem is even larger. It is the lack of any clear 11-year signal from the variations in cosmic rays. It is well-known that cosmic rays are deflected from the solar system by the magnetic field of the sun, which varies in general sync with the sunspots. As a result, the numbers of cosmic rays, and presumably the 10Be flux rates, vary in an 11-year cycle inversely to the sunspot cycle. Here’s what the relationship looks like:
Figure 2. Sunspots and cosmic rays (as indicated by the neutron count). SOURCE
So the relation between cosmic rays and sunspots is quite solid, as you can see above. However, the problem with the 10Be records in this regard is … they have no power in the 11-year cycle range. Sunspot data has power in that range, as does the neutron count data representing cosmic rays … but the 10Be data shows nothing in that range. Here’s the periodicity analysis (see here et seq. for details of periodicity analyses):
Figure 3. Periodicity analysis of the two datasets shown in Figure 1, 10Be flux from Greenland and Antarctica
As you can see, we have no power in either the 11-year or 22-year bands … and if you look at Figure 1, you can see that their correlation with the sunspots is … well … pathetic. The correlation between Greenland 10Be and sunspots is -0.10, and between Antarctica 10Be and sunspots is even worse, -0.03 … like I said, pathetic. A cross-correlation analysis shows slightly greater correlations with a 2 year lag, but not much. However, the lack of the 11-year peaks periodicity analysis (or visible 11-year peaks in the 10Be data) suggests that the lag is spurious.
The problem is, both the sunspots and the cosmic ray counts have a huge peak in periodicity at 10-11 years … but the 10Be records show nothing of the sort.
So, at this point I’m in as much mystery as when I started. We have two beryllium-10 records. They don’t agree with each other. And according to both periodicity and correlation analysis, they don’t show any sign of being connected to anything related to the sunspots, whether by way of cosmic rays, TSI, or anything else …
Now that I’ve finished the analysis, I find that the notes to the dataset say:
Cosmogenic 10Be in polar ice cores is a primary proxy for past solar activity. However, interpretation of the 10Be record is hindered by limited understanding of the physical processes governing its atmospheric transport and deposition to the ice sheets. This issue is addressed by evaluating two accurately dated, annually resolved ice core 10Be records against modern solar activity observations and instrumental and reanalysis climate data. The cores are sampled from the DSS site on Law Dome, East Antarctica (spanning 1936–2009) and the Das2 site, south-east Greenland (1936–2002), permitting inter-hemispheric comparisons.
Concentrations at both DSS and Das2 are significantly correlated to the 11-yr solar cycle modulation of cosmic ray intensity, r = 0.54 with 95% CI [0.31; 0.70], and r = 0.45 with 95% CI [0.22; 0.62], respectively. For both sites, if fluxes are used instead of concentrations then correlations with solar activity decrease.
If you use flux rates the “Correlations with solar activity decrease”??? Yeah, they do … they decrease to insignificance. And this is a big problem. It’s a good thing I didn’t read the notes first …
Now, my understanding is that using 10Be concentrations in ice cores doesn’t give valid results. This is because the 10Be is coming down from the sky … but so is the snow. As a result, the concentration is a factor of both the 10Be flux and the snow accumulation rate. So if we want to understand the production and subsequent deposition rate of 10Be, it is necessary to correct the 10Be concentrations by using the corresponding snow accumulation rate to give us the actual flux rate. So 10Be flux rates should show a better correlation with sunspots than concentrations, because they’re free of the confounding variable of snow accumulation rate.
As a result, I’ve used the flux rates and not the concentrations … and found nothing of interest. No correlation between the datasets, no 11-year periodicity, no relationship to the solar cycle.
What am I missing here? What am I doing wrong? How can they use the concentration of 10Be rather than the flux? Are we getting accurate results from the ice cores? If not, why not?
These questions and more … please note that I make no overarching claims about the utility of 10Be as a proxy for sunspots or cosmic rays. I’m just saying that this particular 10Be data would make a p-poor proxy for anything … and once again I’m raising what to me is an important question:
If the 10Be deposition rate is claimed to be a proxy for the long-term small changes in overall levels of cosmic rays … why is there no sign in these datasets of it responding to the much larger 11-year change in cosmic rays?
I have the same question about cosmic rays and temperature. There is no sign of an 11-year cycle in the temperature, meaning any influence of cosmic rays is tiny enough to be lost in the noise. So since temperature doesn’t respond to large 11-year fluctuations in cosmic rays, why would we expect temperature to track much smaller long-term changes in the cosmic ray levels?
Always more questions than answers, may it ever be so.
My regards to everyone, guest authors, commenters, and lurkers … and of course, Anthony and the tireless mods, without whom this whole circus wouldn’t work at all.
w.
COMMENTS: Please quote the exact words that you are referring to in your comment. I’m tired of trying to guess what folks are talking about. Quote’m or you won’t get traction from me. Even if the reference is blatantly obvious to you, it may not be to others. So please, quote the exact words.
DATA: 10Be original data, Excel spreadsheet
CODE: Just for fun, I’ll put it here to show how tough this particular analysis was:
source("~/periodicity functions.R")
par(mgp=c(2,1,0),cex.axis=1)
spotsraw=ts(read.csv("monthly ssn.csv")[,2],start=c(1749,1),frequency=12)
Annual.Sunspots=window(aggregate(spotsraw,frequency=1,FUN=mean),start=1937,end=2009)
plot(Annual.Sunspots)
theflux=ts(read.csv("Polar 10Be Flux.csv")[,2:3],start=1937,frequency=1)
theoxy=ts(read.csv("Polar 10Be Flux.csv")[,4:5],start=1937,frequency=1)
plot(cbind(theflux,theoxy))
fulldata=cbind(theflux[,1],theflux[,2],Annual.Sunspots)
colnames(fulldata) = c("Greenland 10Be Flux","Antarctica 10Be Flux","Sunspots")
plot(fulldata,main="",yax.flip=TRUE)
title(main="10Be Flux Rates in Greenland and Antarctica\n(atoms / square metre / second)",
line=1,cex.main=1.1)
cor(ts.intersect(fulldata),use="pairwise.complete.obs")
periodsd(theflux[,1],doplot=TRUE,timeinterval=1,add=FALSE,col="blue3",
maintitle="Periodicity Analysis, Ice Core 10Be Flux\nGreenland (blue) and Antarctica (red)")
periodsd(theflux[,2],doplot=TRUE,timeinterval=1,add=TRUE,col="green3")
You’ll need the code for the periodicity functions, it’s here.
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What do the non polar data sets show? do they show 10B3 correlation with the suns magnetic cycles? If so then the explanation may be the the earth’s magnetic field and its effect on cosmic rays.
ferd berple says:
April 13, 2014 at 11:17 pm
What do the non polar data sets show? do they show 10B3 correlation with the suns magnetic cycles?
I haven’t seen any based on ice cores, so can’t tell. The time resolution for the rock exposure data is not good enough for this.
William Astley says:
April 13, 2014 at 8:26 pm
William, that’s a lovely hypothesis … but I’m a practical guy. IF there is an effect on the cloud cover from the changes in cosmic rays / heliomagnetism / sunspots, it would perforce have to operate on an 11-year cycle. So unlike you, always propounding your theories, I go out looking for EVIDENCE. And the problem is, I can find no evidence of such 11-year effects.
Dunno if you saw it in my other post, but in the comments I mentioned that I ran a periodicity analysis on the data from the Armagh Observatory, one of the longest. In this comment, I discuss the results. What I did was to look at the monthly temperature range (MTR). The MTR is the difference between the max and min temperatures for the month. Since in general clouds warm the nights and cool the days, months with lots of clouds should show a smaller MTR than the same month with less cloud.
However, again I found no cycles in the 10-11 year range, in fact, I found no significant cycles at all except for the curious 44-month cycle that I’ve seen in a few datasets without explanation. If GCRs are regulating cloud cover, someone forgot to send Armagh the memo …
So … your hypothesis might indeed be shown to be correct someday. In the meantime, I can’t find any evidence to support it. And you restating your hypothesis over and over does nothing. If you think the GCRs affect the temperature, then find me the temperature dataset with a strong 11-year cycle in it. So far, all of the evidence supports my side of the discussion. I’ve looked at lots of temperature datasets and found nothing. But heck, I’m always happy to be surprised … but it’s gonna take observations to do it.
w.
As my 10:20pm held for moderation post still isn’t showing up, let’s try again:
Konrad says:
April 13, 2014 at 7:14 pm
“Are there any mid-latitude 10Be records that show an 11 year cycle?”
While Greenland latitude, there is figure 6 in this paper, on page 6 of it:
http://arxiv.org/pdf/0804.1938v1.pdf
As my 10:20pm held for mo… post still isn’t showing up, let’s try again:
K[…] says:
April 13, 2014 at 7:14 pm
“Are there any mid-latitude 10Be records that show an 11 year cycle?”
While of Greenland latitude, there is figure 6 in this paper, which is on page 6 of it:
http://tinyurl.com/pfezmp5
ckb says:
April 13, 2014 at 9:14 pm
I have no confidence in the GCR levels over geologic time. Even over a millennium the proxies are in large disagreement. There’s an example of one such study here.
Note the bottom panel in the graphic, which shows Greenland and Antarctic ice core 10Be … and note how little agreement there is between them.
However, we have good data back to about 1960. This allows us to correlate the variations in GCRs with sunspot levels, and that lets us use the sunspot levels as a proxy for GCRs back a couple hundred years. I have medium confidence in that kind of reconstruction. However, I haven’t disassembled one of those reconstructions myself, so I can’t really point you to a good one.
Leif is the real authority in this area, I was born yesterday, so perhaps he’ll answer the question.
w.
Perhaps referencing Konrad was what caused it. Hmmm…
Let’s put this in a form that non-statisticians and non-physicists can relate to.
“If the 10Be concentration, but not the flux, is correlated with sunspot activity (r = 0.54 and r = 0.45 for concentration vs r = -0.10 and r = -0.03 for flux)”
The correlation coefficients (R) indicate R-squared of 0.30 and 0.20 which means the 10Be explains only 20% to 30% of the variance in cosmic ray flux.
Someone asked about the source of 10Be.
When an energetic particle (proton in the form of a cosmic ray) collides with a molecule of oxygen, or more likely in the outer atmosphere, an atom of ionized oxygen, then 10Be is produced by spallation, which is a naturally occurring form of fission, splitting of the oxygen atom. Other products can be formed by striking other kinds of matter, but 10Be is useful for dating because its half-life of over 1.3 million years as 10Be breaks down to produce boron-10.
Sorry: The correlation coefficients (R) indicate R-squared of 0.30 and 0.20 which means the 10Be explains only 20% to 30% of the variance in sunspot activity and vice versa.
Willis
Perhaps the primary data is the concentration and the flux is derived from that. I am having trouble imagining the apparatus that would count 150 atoms per square metre per second, especially in the ’50s. There would be all kinds of variables in such a calculation.
@ur momisugly Leif Svalgaard
Thanks for that presentation in pdf! Very interesting.
And I have some questions about it, from p16:
“When hitting the atmosphere Cosmic Rays produce radioactive Carbon14 and Beryllium10 isotopes”
and
“14C: Global 8 kg/yr; 10Be: Global 55 g/yr”
1. Do I understand it correct that only 55g/yr is produced of 10Be?
2. If so, wouldn’t that make 10Be a very difficult proxy, because both its presence and chance of being found somewhere are so small?
3. Wouldn’t 14C make a better proxy? (slightly better; 8 kg if true isn’t much either)
4. And is 10Be used because it’s in the ice-cores instead of in treerings? Or is 14C also present in CO2 that is captured in icecore bubbles?
And a final qustion:
5. Svensmarks theory is about clouds and cosmic rays. What would, in your opinion, be a good proxy for the nuclei that are said to be produced by cosmic rays?
I hope you can find time for this. Thanks in advance!
Henry Clark says:
April 13, 2014 at 10:08 pm
Well, let’s test that, shall we … here are the periodicity analyses of sunspots and cosmic rays, both of which are used as proxies in climatology. In particular, sunspots are used as a proxy for cosmic rays.
I do love folks like you that pontificate on subjects about which you know little, and speak confidently of things you’ve never tested … have you ever done a periodicity analysis, Henry? And if not, as I suspect is the case … why are you prating about them?
w.
Great investigation Willis. I like the beginner’s mind approach. What you are seeing here is what is so common in climatology is that researchers find a paper , take it at face value without checking whether it makes sense. Then bias confirmation rears it’s ugly head, and if the result of the paper fits what they think , they use it cite it and publish another layer of unfounded science.
I went through this John Kennedy in our discussion about “validation” of hadSST “bias corrections” . The validation process cited a japanese paper that did some blatant selection bias and was from a very small geographical area. When I raised the point that the study was not itself valid and in terms of the global adjustments was nothing more than a geographic anecdote, John told me I should take it up with the authors , rather than saying why he though he disagreed and had accepted the results as “validation” of their work.
For some reason the logic that seems to be applied is that once something is published and no one takes the trouble to rebut it. You don’t need to think for yourself whether the paper makes sense or is well executed before using its results. If it’s part of the litchurchur you just reuse it and propagate any errors.
With the massive volume or work being published now, a lot of it frankly bunk, this leads to a very strong possibility of exponential growth of errors since the negative feedback of supposedly intelligent and competent persons checking the workings of a paper before using its results seems to have disappeared. The main criterium seems to be bias confirmation.
lsvalgaard says:
April 13, 2014 at 3:30 pm
…….the modulation parameter (φ) was not zero during the MM (Maunder minimum). In fact, solar modulation of cosmic rays was as strong back then as now.
…….
Dr. S
Thanks, I read all your comments.
I appreciate the author showing “code” used in performing the analysis. I do wish that all authors would be more specific, state language, compiler version and hardware. A reproduction of the compiler report would be “comforting” and appreciated. Any “warnings” ? Particularly when library functions or procedures are called. Thanks.
I’ve just done a quick chirp-z spectral analysis of the Greenland data and it looks like the major peak is close to 19 years. Also a lot of the minor peaks resemble those I usually find SST data.
I think Be tells us more about climate than neutron count.
However, the Law Dome data in particular is far from stationary and will need something like a diff before spectral analysis.
That should say , I think Be FLUX tells us more about climate than neutron count.
I have not looked at concentration and don’t have time today to go into this more thoroughly.
I cannot help but feeling that a better correlation might be obtained from glaciers nearer the equator if that was possible.
At the near polar sites you used, the sun is not seen for 4-5 months of the year and in the rest of the year, the cosmic rays would have to pass much greater thicknesses of atmosphere and presumably the. charged particles would be more absorbed than at near equatorial sites.
I seem to remember being convinced by this –
http://climateaudit.org/2007/01/14/solar-proxies/
http://cc.oulu.fi/~usoskin/personal/2004ja010964.pdf
funny comments though.. hehe
Willis Eschenbach says:
April 14, 2014 at 12:24 am
“Well, let’s test that, shall we … here are the periodicity analyses of sunspots and cosmic rays, both of which are used as proxies in climatology. In particular, sunspots are used as a proxy for cosmic rays.
I do love folks like you that pontificate on subjects about which you know little, and speak confidently of things you’ve never tested … have you ever done a periodicity analysis, Henry?“”
An “exact match” would have those two lines on top of each other and indistinguishable throughout the entire graph, but, for sunspots versus cosmic ray flux, the specific calculation I have done is of correlation:
Linear correlation between monthly data on sunspot counts and cosmic ray flux (neutron monitor count) is a r^2 of 0.648 over a half century period of data from 1964 to 2013, while having an r^2 of 0.113 over a period from 1980 to 1985. (Overall the larger period is more relevant, although the smaller one highlights how the time period can matter). Neither is a r^2 of 1 or near 1. The point is not that CRF is unrelated to sunspots (for they are related) but to highlight how a r^2 value near 1 should not be expected even with solar activity being a major influence on CRF.
(Data and calculation file: http://www29.zippyshare.com/v/60962429/file.html )
I challenge you to either (a) demonstrate a r^2 value of correlation between sunspots and CRF of about 1, uploading all data and calculations, without resorting to something you wouldn’t otherwise like very long scale averaging, or (b) admit that two quantities can be much related without r^2 linear correlation being near 1.
(Note to readers: Look closely to see which sentences above get snipped and not quoted in the subsequent reply; some things can be excused by lack of time, but that isn’t the prime factor here).
Regarding mid latitudes:
Balloon measurements of cosmic ray flux with modern detectors can get very different results depending on location (GeV cutoff, degree of shielding overhead), and that can be seen by figure 7 in the http://arxiv.org/pdf/0804.1938v1.pdf paper. Particularly over the period prior to 1980, compare the plotted green Alma-Ata (Kazakhstan) cosmic ray intensity with others like the readings above Moscow (red).
Such isn’t a matter of comparing Greenland and Antarctica in two different Be-10 datasets but more direct measurements of cosmic ray intensity, where weather isn’t even an impacting variable any more (when pressure-corrected).
If I was into bad usage of correlation stats, I would feed that plot’s data into a digitalizer, get a r^2 closer to 0 than 1, and thus “prove” that cosmic ray flux above the mid-latitude location had nothing to do with it above the higher latitude locations. That would not be a correct conclusion.
Interesting stuff–very convincing. But looking at the issue on a longer time scale is enough to give you a headache. I’m looking at a plot of 10Be from 1400 AD to the present and I can easily pick out the Wolf, Sporer, Maunder, Dalton, and 1880-1915 Solar Minimums from just the 10Be curve. And plotting δ18O from the GISP2 Greenland ice core data and overlaying it on the 10Be curve gives a good correlation with paleotemperature. Overlaying it on the CET temperature curve also gives a reasonably good fit—not perfect, but discernable. But how can that be, given the convincing data that Willis and Leif have shown? How can both be correct? Seems like a bit of a stretch to conclude that these longer term correlations are just coincidence, or that the data isn’t very good and just happens to match up, or something unrelated to solar variation is responsible. As I said, ‘nuff to give you a headache!
Hi Don
Here is my reconstruction of CET from 1659 to 1538. It is evident that the period around `1500 to the start of the reconstruction will turn out to be rather warm. The 50 years from 1450 look as if they were rather cold.
http://curryja.files.wordpress.com/2011/12/11.jpg
If you overlay your plot against this extended record how does it look?
tonyb
lol. as you point out the claim “Cosmogenic 10Be in polar ice cores is a primary proxy for past solar activity” isn’t supported by the data presented here.
Is there a secret big book of climate science that only the initiated ones have access to that has the demonstrations to all the axioms ?
Come on!
10Be in polar ice cores is a totally reliable way of measuring solar activity.
After all we know just how accurate paleo-proxy methods are in calculating temperatures, rainfall etc etc.
We know the Global Temperature in the Southern hemisphere in the 1880s to .1 degree C even though there were probably not more than a score of thermometers in the southern hemisphere at the time…the lady who counted the isotopes in the little shells and the bloke who measured the moss on the tundra couldn’t possibly be wrong…could they?