Guest essay by Craig Lindberg
Abstract: The change in the relationship between the hemispheric sea ice anomalies appears to have a sinusoidal nature with a wavelength that is a function of North Atlantic and North Pacific sea surface temperature oscillations. There is also a repeating signal observed in both oceans going back at least 100 years. The pattern of this signal appears to be correlated with the sea ice area in both hemispheres and the ENSO.
Background
With only a cursory look at the sea ice anomaly trends in Figure 1, it might be surmised that that the Northern and Southern Hemisphere (“NH” and “SH” respectively) anomalies are negatively correlated; that is as the anomaly in one hemisphere increases, the anomaly tends to decrease in the other.
![Figure1[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure11.png?quality=75)
Figure 1 – Northern and Southern Hemisphere sea ice anomalies over time (Cryosphere Today / Arctic Climate Research at the University of Illinois).
Simply plotting the relationship between the Northern and Southern Hemisphere sea ice anomalies won’t do much to change a perception of a negative correlation. As illustrated in Figure 2, overall it is negative (r^2 = 0.08). Notwithstanding, it appears that an inverse relationship does not accurately characterize the data, and in fact there seems to be a different, and much more interesting, relationship hidden just below the surface as Figures 2 and 3 begin to suggest.
![Figure2[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure21.png?quality=75)
Figure 2 – plot of the NH vs. SH sea ice anomalies and the trend across all data points. Color coding by year suggests that the relationship may have changed significantly over the duration of the satellite record.
![Figure3[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure31.png?quality=75)
Figure 3 – the NH vs. SH sea ice anomalies by calendar year. Black lines are linear best-fit (same color coding as in Figure 2).
The Sea ice Anomaly Oscillation
Figure 3 shows that the relationship between the NH and SH sea ice anomalies has changed meaningfully over time in both sign and magnitude. To study how this relationship varies continuously rather than in arbitrary discrete windows, I calculated the slopes of the best-fit lines (in the least squares sense) beginning with the most recent 356 days of the record (2014.0137 – 2013.0165). I then slid the calculation window backwards across the entire sea ice anomaly record one day at a time, stopping at the final 356 days of the record. This produces a 34 year long daily record of the trailing 365 day relationships between the NH and SH sea ice anomalies (Figure 4).
Any point in the series represents the sign and magnitude of the relationship between the NH and SH sea ice anomalies for the preceding 365 days. I named this index the Sea ice Anomaly Oscillation (the “SAO”).
![Figure4[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure41.png?quality=75)
Figure 4 – the SAO compared to the NH and SH sea ice anomalies. When the SAO is positive, the hemispheric sea ice anomalies generally moved in the same direction (either up or down) over the previous 365 days, and when the index is negative, they generally moved in opposite directions. 49.5% of the series is positive.
The SAO appears to oscillate with an approximately 32 year period that is almost exactly half that of the AMO (Figures 6 and 7). I also compared the SAO to a similar SST index for the Pacific: the mean North Pacific SST anomaly (20N-65N, 100W-100E) with the linear trend removed. I will refer to this index as the Pacific Multidecadal Oscillation (the “PMO”). The roughly 64 year wavelength of the PMO is almost identical to the AMO with the two little more than 3 years out of phase.
![Figure5[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure51.png?quality=75)
Figure 5 – the approximately 32 year SAO oscillation period.
The SAO appears to be directly related to the AMO and PMO. SAO minimums and maximums occur at approximately the intersection of the AMO and PMO and the maximum separation of the AMO and PMO respectively. Zero crossings occur at approximately 1) the intersections of the AMO and inverted PMO, and 2) the maximum separation of the AMO and inverted PMO. A relationship, if any, between the SAO and the PDO is not readily apparent (Figure 6).
![Figure6[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure61.png?quality=75)
Figure 6 – the SAO trend compared to the AMO, PMO (top), inverted PMO (middle), and PDO (bottom) trends.
The SAO and ENSO
When I first plotted the SAO, I noticed it looked similar to any of the standard ENSO indexes such as the Oceanic Nino Index (“ONI”) or the Multivariate ENSO Index (“MEI”). In fact, simply inverting the SAO at its zero crossings matches it up to either of these indexes tantalizingly well (Figure 7).
![Figure7[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure71.png?quality=75)
Figure 7 – the SAO inverted at its inflection points compared to the ONI. (R^2 =0 .13)
Relationship to Atlantic and Pacific SST
While studying the AMO and PMO, I noticed that after removing the main sine components, the residuals (which I will refer to as the “AMO2” and “PMO2” respectively) also had a sinusoidal nature, and that they appeared to be carrying information; the general pattern of the SAO appears to repeat multiple times across both series. To deconvolve the relevant segments into the SAO, I simply inverted them at the fitted SAO zero crossings and then smoothed with a 3-month centered SMA filter.
Deconvolving the AMO2 and PMO2 signals into an ENSO proxy was somewhat of a bigger challenge primarily because the data is fairly noisy (as should probably be expected given the nature of the data). I ended up building a model to deconvolve the signal and then optimized for a frequency solution using the ONI as a reference to minimize variance against. The optimized AMO2 and PMO2 frequencies were 0.1% and 1.0% different from the sine waves fit with R respectively. Deconvolving involved inverting the signal at the AMO2 and PMO2 zero crossings and at the AMO2-PMO2 intersections. The deconvolved signals were smoothed with a 3-month centered SMA filter.
The r^2 of the deconvolved AMO signal segment in Figure 8 compared to the ONI is 0.23 (0.24 MEI and 0.20 vs. NINO3.4). This doesn’t sound too bad when I consider that the AMO is calculated from the average of the entire North Atlantic and that the data used goes back between 74 and 114 years.
I ran several other AMO2 and PMO2 segments through the same algorithm and used the same frequencies, and while they didn’t correlate to the ENSO record nearly as well as the first segment I extracted from the AMO2, visually there were still many similarities. One example of a segment from the PMO2 is given in Figure 9.
![Figure8[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure81.png?quality=75)
Figure 8 – a segment (1900 – 1940.3) taken from the AMO2, shifted forwards in time to the present, and deconvolved into an SAO proxy (middle, r^2 = 0.17) and into an ENSO index proxy (bottom), shown here compared to the ONI (r^2 = 0.23).
![Figure9[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure91.png?quality=75)
Figure 9 – a segment (1945.5-1989.3) taken from the PMO2, shifted forwards in time to the present, and deconvolved into an SAO proxy (middle, r^2 = 0.24) and into an ENSO index proxy (bottom), shown here compared to the ONI (r^2 = 0.02).
Forecast
If these relationship hold, it appears that the next couple decades will see a generally warmer Nino3.4 region. With respect to the sea ice anomalies, I’m not sure how to translate the SAO forecast into km^2 or changes in the gap between the hemispheres – or if it is even possible to do so for that matter. It would appear however that the anomalies will be moving in generally opposite directions for the better part of the next two decades.
![Figure10[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure101.png?quality=75)
Figure 10 – forecast ONI and SAO based on the AMO2 signal post-June 1940.
Discussion
These observations would seem to further call into question the idea that GHGs are the driving force behind the contraction of Arctic sea ice area over the past few decades. If repeating SST patterns can predict the relationship between the hemispheric sea ice anomalies more than 100 years later with the resolution illustrated in Figures 8 and 9 (middle charts), which is the more likely cause: GHGs or natural cycles?
Likewise, perhaps winds do explain much of the recent Antarctic sea ice expansion as several recent journal articles have suggested (http://journals.ametsoc.org/doi/abs/10.1175/JCLI-D-12-00139.1 and http://www.nature.com/ngeo/journal/v5/n12/full/ngeo1627.html), but if so, this would suggest such winds are part of processes set in motion a long time ago – as was whatever mechanism has caused the corresponding contraction in the Arctic.
Notes
Fitting sine cures to the signals in this analysis was performed with R in the y=a*sin(b*t+c)+d form. No adjustments were made to the AMO or PMO fit and only minor adjustments were made to the AMO2 and PMO2 frequency as described above. Constant values are presented in Table 1 below:
Table 1 – Curve fit constants.
![Figure11[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure111.png?quality=75)
Figure 11 – AMO, PMO, and PDO curves as fit. The SAO is shown in Figure 5.
The r^2 of the individual points of the SAO are fairly low. More than half are 0.07 or less. Notwithstanding, over 80% of the results are statistically significant at the 0.05 level and almost 73% at the 0.01 level. Of course, many of the points that are not statistically significant are where the SAO is zero (thus r^2 is also zero), and you would not expect the results to be significant.
![Figure12[1]](http://wattsupwiththat.files.wordpress.com/2014/02/figure121.png?quality=75)
Figure 12 – SAO Index r^2 and Sig. F. Red lines identify the points of the SAO that are not statistically significant at the 0.05 level.
All of the data and methodologies used in this analysis can be found in two Excel files here:
http://lindbergs.us/SAO/SAO1.xlsx
http://lindbergs.us/SAO/SAO2.xlsx
I’m surprised that this situation is so little discussed in the U.S..
http://oi60.tinypic.com/21kfsdc.jpg
“To deconvolve the relevant segments into the SAO, I simply inverted them at the fitted SAO zero crossings and then smoothed with a 3-month centered SMA filter.”
What is this “deconvolution” about ?? Is that a recognised mathematical process ?
This basically folds a negative correlation into a positive correlation . What is the result supposed to tell us about the relationship or climate ???
It looks like arbitrary data juggling, if there is some logic behind it, needs to be clearly explained.
HenryP says:
Sorry, r square less than 0.5 is rubbish.
A comment which shows that you have no understanding correlation coefficients and what consitutes a significant result.
Looking at figure 1 the term “bipolar seesaw” springs to mind.
Does not this entire analysis require the assumption that Antarctic sea ice extents are “equal” in effect to Arctic sea ice extents? (Loss of 1.0 Mkm^2 in the Arctic would have an equal effect to loss of 1.0 Mkm^2 in the Antarctic, or loss of 1.0 Mkm^2 in the Arctic would be “balanced” by the gain of 1.0 Mkm^2 of sea ice in the Antarctic?)
That assumption is wrong: The Arctic Ocean sea ice expands and contracts between 82 North latitude and 70 north latitude. If it were a symmetric “beanie cap” centered on the north pole, you could easily approximate it as circular cover oscillating between 72 north (14.0 Mkm^2) on March 1, and its modern low point of 3.5 Mkm^2 at 81 north latitude in mid-September.
Antarctic sea ice extents also oscillates between a low point of 3.5 Mkm^2 and a recent record-high maximum just under 20.0 Mkm^2, but those similar areas of Antarctic sea ice occur at 70 degrees south latitude at minimum and 59.2 degrees south latitude at maximum.
At lower latitudes many thousand kilometers closer to the equator every day of the year, the Antarctic sea ice is much more effective at reflecting solar radiation, or in its absence, the exposed open ocean water is much more effective at absorbing available solar radiation than the Arctic sea ice.
“Does not this entire analysis require the assumption that Antarctic sea ice extents are “equal” in effect to Arctic sea ice extents? ”
No , it’s a ratio, so if Arctic ice moves 4 times faster it will just scale the graph.
Such a position of the polar vortex will cause flooding in the UK.
http://oi62.tinypic.com/10gwvia.jpg
All oceanic and solar metrics seem to point to 2030 being much cooler than now.
In literature, there is already a term for this: Bipolar seesaw.
The Arctic sea ice has undergone quite a change over the last week. Today,s NSIDC shows that the trend has now moved below the -2 sd line, and from appearances it is about to nosedive. The DMI shows a strong upswing in Arctic temps close to 260K. The temps have risen 10K over the last 3 days. I would imagine that there will be some chatter from the warmists side when they notice this.
Antarctica sea ice has also slumped over the last 3 days, which has brought the trend line back down to the +2 sd line. This is probably due to the approaching minimum. I had thought that the SH sea ice was going to maintain it,s high anomaly level, but it seems that my thoughts were wrong in that regard.
Greg Goodman says
http://wattsupwiththat.com/2014/02/13/a-relationship-between-sea-ice-anomalies-ssts-and-the-enso/#comment-1566717
try finishing first year statistics successfully and we can talk again
if you get r square > 0.99
you are on your way
http://blogs.24.com/henryp/2013/02/21/henrys-pool-tables-on-global-warmingcooling/
The additional data point from 1964, recovered from old satellite data, supports that Arctic/Antarctic sea saw well (Sep 1964, Antarctic 19.7 mill km2 (bit higher than current “record highs”, ), Arctic 6.9 mill km2 (much smaller than thought).
https://nsidc.org/monthlyhighlights/2013/04/glimpses-of-sea-ice-past/
This data point is particularly important, because all the the satellite record is AMO positive and only the last few years PDO negative.
More pre 1979 satellite data should fill that gap and should be available soon:
http://cires.colorado.edu/science/spheres/snow-ice/historic-data.html
And the second main driver of Arctic sea ice melt is also not CO2.
According to Hansen, black carbon on Arctic ice has an “effective” forcing of 3 W/m2,
http://en.wikipedia.org/wiki/Black_carbon
plus further 2 W/m2 atmospheric forcing (1.0 W/m2 globally, but assuming almost all in the northern hemisphere)
http://www.igbp.net/images/18.4910f0f013c20ff8a5f8000200/1376383182972/black-carbon-Fig9.jpg
That sums up to black cabon having about 3 times higher forcing on Arctic ice than CO2.
Fantastic, brilliant paper! True objective data analyses.
Note that HadCrut 4 data has the following, using MACD-determined dates of max, min GSTAs, periods of ~32yrs on average (yes you read that correctly; that’s half of the PMO wave length and equal to that of the SOA…):
• max 1878.1, min 1911.1: 33.0yrs
• min 1911.1, max 1945.6: 34.5yrs
• max 1945.6, min 1976.2: 30.6yrs
• min 1976.2, max 2007.0: 30.6yrs
Average: 32.2yrs
See: http://wattsupwiththat.com/2013/10/01/if-climate-data-were-a-stock-now-would-be-the-time-to-sell/
1911 coincides perfectly with AMO, PMO, and PDO minima
1945 coincides perfectly with a PMO maximum, while AMO and PDO are close to maximum
1976 coincides perfectly with a AMO and PMO minimum,
2007 coincides perfectly with a AMO max, almost PMO mininum and almost PDO minimum
More importantly, there is no need for any “CO2-related warming” to explain any of the temperature trends since 1850: global warming problem solved, move on!
[Equal to the SOA (wave length). PMO and SOA = ??? Mod]
Edit:
relationships
Taking JDNs comment ( the first for thos post) , perhaps establishing an on line journal for such papers might be the way to go. A not for profit public journal backed by a proper peer review process ( i.e. not pal review) with a separate peer review page for any paper that gets published. Some of the commercial journals have utterly disgraced themselves over the past decade or so in this field particularly and simply cannot be trusted. It would not be perfect of course but wtf, why not.
It seems reasonable to suggest that trends in Arctic and Antarctic ice move in and out phase with each other due to the different ocean distributions in each hemisphere.
The underlying driver of change would still, in my view, be solar effects on global cloudiness altering the amount of energy able to enter the global oceans but the Arctic and Antarctic ice responses would be on differing timescales which would indeed move in and out of phase.
So, a single driver could indeed produce the system response which the author suggests.
Curve fitting! It’s not just for breakfast anymore!
Craig: You can get much the same information without doing a curve fit at all.
If you run a Gaussian or similar filter with a 15 year low pass corner the same (or similar) cycle will pop out of the data without any other work being required.
PDO with a Cascaded Triple Running Mean (which has a near Gaussian response curve)
http://i29.photobucket.com/albums/c274/richardlinsleyhood/PDOLowpass_zpsa9b3df25.png
Please also remember that Judith Curry’s Stadium Wave paper has ~60 year cycles all over it.
Role for Eurasian Arctic shelf sea ice in a secularly varying hemispheric climate signal during the 20th century
Wyatt & Curry
http://curryja.files.wordpress.com/2013/10/stadium-wave1.pdf
See Figs 7 though 10.
Temporal Group I: 56 years
Temporal Group II: 59 years
Temporal Group III: 60 years
Temporal Group IV: 60 years
They are all connected through the Meridional Overturning Circulation (MOC). As it speeds up and slows down it drives the other oscillations.
And this from Zhang and Wang 2013 about how badly the models do in all of this.
http://i29.photobucket.com/albums/c274/richardlinsleyhood/MultidecadalNorthAtlanticSeaSurfaceTemperatureandAtlanticMeridionalOverturning-ZhangampWang2013_zps5c350c1b.png
In reply to Mod: Quote “The roughly 64 year wavelength of the PMO is almost identical to the AMO with the two little more than 3 years out of phase. Figure 5 – the approximately 32 year SAO oscillation period.” Hence, my post should read “yes you read that correctly; that’s half of the PMO wave length and that of the SOA…” (I forgot to delete “equal to” when I edited that sentence from period to wave length) sorry about that and thanks for bringing it to our attention!
Craig: Low pass on the AMO says it is there also.
http://i29.photobucket.com/albums/c274/richardlinsleyhood/AMOLowpass_zps1e49c229.png
I still can’t get past Figure 2. When you cross-plot two time series, the slope of the “line” represents the amplitude required to convert one time series into the other. Any correlation (positive or negative) can be seen visually as the narrowness of the graph. A straight line demonstrates high correlation while a “shot-gun” pattern means no correlation. So you have to ask yourself if Figure 2 looks like a “shot-gun” pattern or a straight line.