UPDATE: Chris de Freitas responds to comments with an addendum below – Anthony
Readers may recall the recent paper that blamed “the pause” in global temperature on ENSO changes in the Pacific Ocean.
Recent global-warming hiatus tied to equatorial Pacific surface cooling
Yu Kosaka & Shang-Ping Xie Nature (2013) doi:10.1038/nature12534
Dr. Judith Curry called the paper “mind blowing”
Now there’s another paper that reaches a similar conclusion:
Update of the Chronology of Natural Signals in the Near-Surface Mean Global Temperature Record and the Southern Oscillation Index
de Freitas and McLean, 2013, p. 237 (Int J Geosciences – open access):
“All other things being equal, a period dominated by a high frequency of El Niño-like conditions will result in global warming, whereas a period dominated by a high frequency of La Niña-like conditions will result in global cooling. Overall, the results imply that natural climate forcing associated with ENSO is a major contributor to temperature variability and perhaps a major control knob governing Earth’s temperature.”
ABSTRACT
Time series for the Southern Oscillation Index and mean global near surface temperature anomalies are compared for the 1950 to 2012 period using recently released HadCRU4 data. The method avoids a focused statistical analysis of the data, in part because the study deals with smoothed data, which means there is the danger of spurious correlations, and in part because the El Niño Southern Oscillation is a cyclical phenomenon of irregular period. In these situations the results of regression analysis or similar statistical evaluation can be misleading.
With the potential controversy arising over a particular statistical analysis removed, the findings indicate that El Nino-Southern Oscillation exercises a major influence on mean global temperature. The results show the potential of natural forcing mechanisms to account for mean global temperature variation, although the extent of the influence is difficult to quantify from among the variability of short-term influences.
Since the paper is open access, and available here: http://www.scirp.org/journal/PaperInformation.aspx?PaperID=27382
Here is the link to the PDF:
deFreitas_&_McLean_IJG_2013_SOI_&_Mean_Global_Temp
This figure is interesting:
Figure 1. Four-month shifted SOI anomalies with monthly MGT anomalies shown for periods 1950 to1970 (a), 1970 to 1990 (b) and 1990 to June 2012 (c), where the Y-axis scale is identical in each case. The dark line indicates SOI and light line indicates MGT. Periods of volcanic activity are indi-cated (see text).
Discussion and Conclusions
The results show that, by and large, the Southern Oscilla- tion has a consistent influence on mean global tempera- ture. Changes in temperature are consistent with changes in the SOI that occur about four months earlier. The rela- tionship weakens or breaks down at times of major volcanic eruptions. Since the mid-1990s, little volcanic activity has been observed in the tropics and global average temperatures have risen and fallen in close accord with the SOI of four months earlier; although with the unexplained divergence of NH and SH average temperature anomalies modifying the earlier relationship.
The strength of the SOI-MGT relationship may be indicative of the increased vigor in the meridional dispersal of heat during El Niño conditions and the delay in the temperature response is consistent with the transfer of tropical heat polewards. The mechanism of heat transfer is likely the more vigorous Hadley Cell Circulation on both sides of the Intertropical Convergence Zone distributing warm air from the tropical regions to higher lati- tudes. The process of meridional heat dispersal weakens during La Niña conditions and is accompanied by a lower than normal MGT. Hadley Cell Circulation is weakened when the Southern Oscillation is in a state associated with La Niña conditions (i.e. positive Troup SOI values), but strengthens as the Southern Oscillation moves to a condition consistent with El Niño conditions (that is negative SOI values) [6,7].
The precision of the 4-month lag period is uncertain, but the credibility of a lag of some length is not in dispute. Researchers [31] found that mean tropical temperatures for a 13-year record lagged outgoing longwave anomalies by about three months, while [32] found warming events peak three months after sea surface temperature (SST) in the Niño-3.4 region. On the same theme, [33] found lags between 1 – 3 months with SST in the Niño-3.4 region for the period 1950-1999. Along the same lines [14] determined that the correlation between SST in the Niño-3 region and the MGT anomaly was optimum with a time lag of 3-6 months. The sequence of the lagged relationship indicates that ENSO is driving temperature rather than the reverse. Reliable ENSO prediction is possible only to about 12 months [34], which implies that improved temperature forecasting beyond that period is dependent on advancements in ENSO prediction.
The reason for the post-1995 period shift in the SOI- MGT relationship illustrated in Figure 1(c) is puzzling. An explanation may lie in changes in global albedo due to changes in lower-level cloud cover. In an analysis of Australian data, [34] found positive values of SOI anomalies to be associated with increased cloudiness and decreased incoming solar radiation. Data from the International Satellite Cloud Climatology Project (ISCCP) indicate that, from 1984 to 2005, mid-level cloud cover in the tropics was relatively constant but both lower and upper level cloud cover declined slightly. In the exotropics (latitude > 20 degrees, low-level cloud progressively decreased from 1998 onwards. It is not clear whether the change is a cause or an effect of a parallel temperature change [35]. The post-1995 shift appears unrelated to carbon dioxide increase because it occurred long after atmospheric CO2 was known to be rising. It is important to see the shift as more of discrete (i.e. step) change rather than a divergence, with the relationship reestablished after 2 – 3 years. Another possibility is that there are problems with the HadCRUT4 1.1.0 data. For example, we note that the published monthly average global temperature anomalies are not equal to the mean of the two published corresponding hemispheric values.
The approach used here avoids a focused statistical analysis of the data, in part because the study deals with smoothed data, which means there is the danger of spu- rious correlations, and in part because the ENSO is a cyclical phenomenon of irregular period. In these situations, the results of regression analysis or similar statisti- cal evaluation can be misleading. With the potential con- troversy arising over a particular statistical analysis re- moved, the findings reported here indicate that atmos- pheric processes that are part of the ENSO cycle are col- lectively a major driver of temperature anomalies on a global scale. All other things being equal, a period dominated by a high frequency of El Niño-like condi- tions will result in global warming, whereas a period dominated by a high frequency of La Niña-like condi- tions will result in global cooling. Overall, the results imply that natural climate forcing associated with ENSO is a major contributor to temperature variability and per- haps a major control knob governing Earth’s temperature.
================================================================
UPDATE: 9/5/13 4:15PM PDT Chris de Freitas asked for this addendum to be posted in response to comments/discussion – Anthony
I understand concerns of the global warming alarmists. I too have been looking high and low for evidence that human-caused carbon dioxide increase is a major driver of mean global temperature. Our current is not part of that quest.
The intention of the work reported in the paper (de Freitas and McLean, 2013) was to stay as far away as possible from statistical massaging of the data. The reason is that, in our earlier 2009 work (McLean, de Freitas and Carter – references below), we were roundly criticised for the statistical methods we used. It detracted from the main finding of the work (i.e. Fig 7), which was free from statistical massaging; namely, that ENSO accounted for a great deal of the variability in mean global temperature; similar to that reported in the more recent paper in Nature (Kosaka and Xie, 2013).
In de Freitas and McLean (2013) we also stayed away from looking for trends. Determining trends and implementing detrending procedures can be important steps in data analysis. However, there is no precise definition of ‘trend’ or any ‘correct’ algorithm for extracting it. Consequently, identification of trend in a time series is subjective because a trend cannot be unequivocally distinguished from low frequency fluctuations. For this reason, a variety of ad hoc methods have been used to determine trends and to facilitate detrending methods (which are also subjective). As regards the correlation routine (Table 2 of our IJG 2013 paper), the idea there was to look for guidance in aligning the X-axis of Figures 1 and 3. It could have (even) been done by eye.
The overriding message is this. Climate is never constant; it is always cooling or warming. Various things cause these trends. Ever since I began studying climate 40 years ago I have been looking for patterns along with possible mechanisms and explanations. I have not had great success; if fact nobody has, and we have all been wrong once or twice. Notwithstanding that, our IJG (2013) paper shows that ENSO correlates well with global temperature. A possible reason (as described) is enhanced (or reduced) Hadley circulation, which increases (or decreases) the effectiveness of meridional heat transfer from the vast tropical zone of surplus towards the poles. It could be that the same process causes vast amounts of stored ocean heat to be fed into the atmosphere over extended periods (or moved back into the ocean over lengthy periods) The result is planet-wide warming (or cooling). If this persists, we get decadal scale global warming (or cooling) trends.
Like the work of Kosaka and Xie (2013), our IJG (2013) and earlier work (2009) shows that the current (or past hiatus), or multi-decadal-scale cooling or warming (‘climate change’), are possibly a reflection of natural climate variability tied specifically to ENSO decadal-scale processes. I assume these are superimposed upon what seems for the moment to be the less potent CO2-caused warming, and likely other less potent mechanisms as well.
Whether the ENSO-caused multi-decadal trends are internal or forced is unknown. My guess is that cooling and warming trends we see, or hiatus, are probably due to natural internal variability rather than a forced response. But we don’t know.
Chris de Freitas
de Freitas, C.R. and McLean, J.D., 2013. Update of the chronology of natural signals in the near-surface mean global temperature record and the Southern Oscillation Index. International Journal of Geosciences, 4(1), 234-239.
Open access at:
http://www.scirp.org/journal/PaperInformation.aspx?paperID=27382&
McLean, J. D., C. R. de Freitas, and R. M. Carter, 2009b. Correction to ”Influence of the Southern Oscillation on tropospheric temperature”, Journal of Geophysical Research, 114, D20101, doi:10.1029/2009JD013006. ISSN 0148-0227
McLean, J. D., C. R. de Freitas, and R. M. Carter, 2009a. Influence of the Southern Oscillation on tropospheric temperature, Journal of Geophysical Research, 114, D14104, doi:10.1029/2008JD011637. ISSN 0148-0227
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Now that climate scientists are focusing on ENSO variability, maybe the next focus should be on these Nada periods. The mechanism for significant recharge is clear sky La Nina’s. But what if the recharge is limited by a La Nada? The next El Nino won’t be as hot? What if the next La Nina is again a La Nada? The next El Nino won’t be as hot? If this pattern continues, we should see a gradual cooling and possibly serious cooling because El Nino’s won’t produce enough land heat to keep us (and our plants) temperately comfortable. Does the length or frequency of La Nada’s (poor rechargers) forecast coming serious cooling?
Ulric Lyons:
In attempt to stop you derailing this thread as you did the previous ENSO thread, I said to you
And at September 4, 2013 at 7:11 am you have replied
NO!
A rational person does not call this “concise and cogent”
You wrote it on WUWT yesterday in the previous ENSO thread. It is at
http://wattsupwiththat.com/2013/08/28/another-paper-blames-enso-for-the-warming-hiatus/#comment-1407289
And it is a statement that you don’t want to discuss science rationally.
Richard
Let’s consider La Nadas as Pamela Gray suggests.
The only way energy gets into the oceans without being offset by increased evaporation is via solar shortwave which is energetic enough to get past the evaporative layer.
We can’t ignore solar influences because that is the only source of energy available. Note that energy is being released all the time during El Ninos, La Ninas and La Nadas.
All that changes is the rate of that release.
So some of the time the oceans are holding on to solar energy a little longer (La Ninas) and the air above cools because energy to space is greater than energy from the oceans.
Sometimes the oceans release their energy a little sooner (El Ninos) and the air above warms because energy to space is less than energy from the oceans.
La Nada suggests the rates of energy loss and gain for the air are about in balance so a pause rather than warming or cooling.
But there is another factor.
If there is more global cloud cover the rate of recharge will be reduced from what would otherwise it would have been during any given La Nina.
If there is less global cloud cover the rate of recharge will be similarly increased.
That can skew the balance between El Nino and La Nina.
So we really do need another forcing element to account for the cloudiness changes and that has to be the top down solar effect.
If the oceans were controlling the cloud cover the ocean cycles would simply fade away to a bare minimum once the recharge / discharge process achieved equilibrium at a given level of cloud cover but that never happens.
The current observations implicitly reveal that some other factor altering cloudiness is destabilising the oceans’ attempts to achieve equilibrium with the air above.
The longer term (beyond the 60 year PMO) cycles we see are therefore the negative system response from the oceans serving to offset the destabilising influence of that separate solar forcing effect on global cloudiness.
Our CO2 emissions, in so far as they have an effect, would be indiscernible in comparison.
richardscourtney says:
“And it is a statement that you don’t want to discuss science rationally.”
It essentially states that I have no need to discuss pseudo-science when presenting my findings. If you regard any existing papers on planetary-solar phenomena as science, you must have your bar set much too low.
One item not to over look is visible solar light penetrates the ocean surface to a depth of 100 meters and it is this intensity of visible solar light which plays a significant role in the amounts of ocean heat content..
Pamla Gray, I can’t get what you are trying to convey, other then the sun has nothing to do with anything.
Ulric Lyons:
In the unlikely event that anybody is interested in your words and their context, I copy the link for them here.
http://wattsupwiththat.com/2013/08/28/another-paper-blames-enso-for-the-warming-hiatus/#comment-1407289
Richard
Pamela, most climate scientist if not all of them that do not have a vested interest in the global man made warming agenda are of the opinion that solar rules the climate.
That is how it is, and today a new study came out which further confirms the solar/cosmic ray/cloud lower temperature connection.
Pamela , you believe in what you want to and I suggest you should ignore all post that talk about a solar /climate connection, since it bothers you so much.
“As for patterns of frequent El Ninos and patterns of frequent La Ninas, this has always been a focus of data. But I am wondering if a pattern of El/La Nadas holds the key for coming coolness.”
Pam,
I have always wondered what ENSO looked like during the MWP (800-1300AD) and the LIA (1300-1850)? Is our global climate always determined by ENSO? Could the LIA been brought on by some anomaly that works against Nature’s Thermostat?
Richard Courtney, if various posters bother you why do you respond? It is just a waste of all of our time.
Ulric Lyons, I appreciate you efforts, keep posting your thoughts going forward.
Once very quiet solar conditions prevail(in the not to distant future once again) I expect the trend toward a more meridional atmospheric circulation pattern will start to exert itself, which is and will be a mjor climate changer.
A more SUSTAINED meridional atmospheric circulation will promote more clouds, more precip.,and more snow cover for the N.H. which will prove to be a climate changer if sustained over a period of time.
Salvatore Del Prete:
At September 4, 2013 at 10:20 am you write
So, one thread hijacker supports another thread hijacker and neither says anything pertinent to the subject of the thread, but they whinge at complaints at their thread hijacking.
No surprise there.
Richard
It is not important. What is important is finding out why, I think all of thecontributions are of value even ones I disagree with 100%.
Pamela Gray says:
September 4, 2013 at 8:22 am
The null hypothesis is internal variation, of which this thread is focused on.
…With neutral ENSO, the oceans are not getting recharged to the degree they should…”
////////////////////////////
Pamela
What recharges the oceans?
Is this by any chance the sun and the solar energy that it radiates? If not this, what is it?
If “the oceans are not getting recharged to the degree they should”, is this because total solar energy (which is not necessarily TSI) is less, or is it because less solar gets through to the ocean surface due to changes in the atmosphere, notably changes in cloudiness?
If the latter, ie., changes in cloudiness, are the changes to cloudiness simply the result of energy changes going into the atmosphere (including differing amounts of water vapour) driven directly by the various ENSO states theemselves, or is due to some change brought about by an atmospheric reaction to changes within the sun (eg., perhaps something along the line that Svenmark postulates upon), and/or perhaps the earth’s own magnetic field?
Clarification of your views on internal variation would be appreciated.
PS. I do not disagree that there is a potentially a third state to consider that you call La Nada.
Pamela Gray says:
“The null hypothesis is internal variation, of which this thread is focused on.”
That’s a Nil Hypothesis. Declaring it random provides no reasons for why the trade winds alter.
But I thought the sea was becoming warmer?
Here we go again. It seems necessary to remind ourselves that ENSO is an oceanic phenomenon, not an atmospheric or
astrologicalastrophysical one. Few seconds on Google scholar (near the bottom of the list of the “more” options at google) reveal dozens of published papers over the last 3 decades demonstrating the nonlinear oscillatory dynamics of ENSO, and assessing among other thing forcing by astrophysical factors and other climate oscillations. Here are a few examples:http://cpb.iphy.ac.cn/EN/article/downloadArticleFile.do?attachType=PDF&id=22907
http://grims-model.org/front/bbs/paper/gcm-1/CLM-GCM_1997-4_Nartin_P._Hoerling_et_al.pdf
http://web.yonsei.ac.kr/climate/board/4/20090612072138217_2009-2_TAC_An.pdf
http://lumahai.soest.hawaii.edu/MET/Faculty/jff/2004_02%20Nonlinearity%20and%20Asymmetry%20of%20ENSO.pdf
http://www.lasg.ac.cn/UpLoadFiles/File/papers/2006/2006-dws.pdf
http://o3d.org/web_db_data/articles/1995/Penland-1995.pdf
http://www.ldeo.columbia.edu/res/div/ocp/pub/cane/MunnichEtAl1990.pdf
The Bjerknes positive feedback between Peruvian upwelling and trade winds is the motor at the heart of the ENSO. ENSO is not however a continuous nonlinear oscillation like the heart beat, it is intermittent with probably neutral periods during which nonlinear oscillation is not taking place.
The fact that el Nino peaks usually around Christmas shows that ENSO is under entrainment (this is a more accurate term than “forcing”) from the annual cycle at least. (I will at least concede to the solar brigade that winter and summer are real phenomena.)
The major problem with all natural oscillations being forced like clockwork from astrophysical forcings is that they are not regular in the long term: the PDO is only 60 years periodic in the last century, looking further back there is wide variation in its time period. ENSO is also irregular, there is no monotonic periodicity that would be required if astrophysical forcing were dominant. A paradigm of a weakly forced nonlinear oscillator is much more compelling.
The main motor of ENSO variation is internal, the Bjerknes feedback. There is a possible role for astrophysical cycles in weak forcing or entrainment.
Weather is from the atmosphere. Climate is from the ocean. Live with it.
The variation of cloudlessness during a La Nina/La Nada event could be related to a teleconnection with the many large pressure systems set up via the Coriolis affect. These systems may themselves have a variety of swings and shifts that affect how much equatorial clear sky is or is not present during re-charge events. Certainly, by far, the greater variation in SWIR at Earth’s sea surface is the degree of cloudiness that SWIR has to penetrate, not some tiny solar difference emanating from the Sun.
I find this description of equatorial clouds, and clouds in general, fascinating and speaks to the role and variance of clouds in this debate.
http://isccp.giss.nasa.gov/role.html#TOP
What’s “mind-blowing” to JC, and me, is that the paper acknowledged a major role for oceanic cycles. I’m waiting for the next shoe to drop, attribution of ENSO to CO2.
Preview and more, like the blockquote above, available with the Greasemonkey add-on running the CA Assistant script (See the Climate Audit front page).
Fonts, and links, and more.
phlogiston says:
“The main motor of ENSO variation is internal, the Bjerknes feedback.”
It does not explain the switch, the current idea is that slosh does that:
http://eesc.columbia.edu/courses/ees/climate/lectures/enso.html
And solar forcing is not in the slightest bit like clockwork.
Phlogiston said:
The main motor of ENSO variation is internal, the Bjerknes feedback. There is a possible role for
astrophysical cycles in weak forcing or entrainment.
My response:
So that would explain why there is a much greater than chance probability of finding an extreme perigean spring-tide (i.e. one that occurs close to perihelion) in the year prior to or the first year of an El Nino event?
You are obviously not aware of the work of Claire Perigaud:
http://www.aviso.oceanobs.com/fileadmin/documents/OSTST/2009/poster/Perigaud.pdf
http://www.aviso.oceanobs.com/fileadmin/documents/OSTST/2009/poster/Perigaudabstract.pdf
Irrespective of what drives the PDO, ENSO, AMO, etc, if the downward leg of changes in the balance between nino and nina conditions is to be blamed for the stagnation in temperatures, the upward leg must have contributed commensurately to the most recent warming phase as well.
That further constrains the estimates of climate sensitivity to CO2, since half of the warming previously assumed to be due to CO2 would actually have been due to natural factors.