Guest post by Bob Tisdale
This is the 3rd part of a series of posts that present myths and misunderstandings about the tropical Pacific processes that herald themselves during El Niño and La Niña events. In the posts, I’m simply reproducing chapters from my recently published ebook Who Turned on the Heat?
Many of these myths were created by proponents of manmade global warming who have no understanding of the coupled ocean-air processes that result in El Niño and La Niña events. Those persons look at an El Niño-Southern Oscillation (ENSO) index and wrongly assume the index represents all of the processes of ENSO—when, in reality, the index simply shows the impact of El Niño and La Niña events on the variable being measured for that index. ENSO indices (like NINO3.4 region sea surface temperature anomalies presented in the post) do not capture in recharge aspects of La Niña events that are evident in the ocean heat content data for the tropical Pacific and they do not capture the impacts of the discharge and redistribution processes of major El Niño events that are plainly visible in the sea surface temperature anomalies of the Atlantic-Indian-West Pacific Oceans(90S-90N, 80W-180).
For almost 4 years, my presentations about the long-term effects of El Niño and La Niña events indicate the global oceans over the past 30+ years have warmed naturally. The long-term impacts of El Niño and La Niña are blatantly obvious. Proponents of anthropogenic global warming apparently have difficulty comprehending that, so they use misinformation to try to contradict what’s plainly visible. Many of the myths they’ve created are failed attempts to neutralize strong El Niño and La Niña events—to redirect the observable causes of the warming over the past 3 decades from natural factors to manmade greenhouse gases.
The following discussion is from Chapter 7.1 Myth – ENSO Has No Trend and Cannot Contribute to Long-Term Warming. It begins with a reference to Section 5 of Who Turned on the Heat? The chapter titles of that section give a general description of the topics discussed. See the table of contents in the book preview here. Most of those discussions have been presented in numerous posts over the past 4 years at my blog and in cross posts at WattsUpWithThat.
******
We’ve discussed and illustrated in Section 5 of this book how ENSO has been responsible for the warming of global sea surface temperatures over the past 30 years. In fact, the intent of this book was to provide the reader with a strong enough background in ENSO to understand why this myth [ENSO Has No Trend and Cannot Contribute to Long-Term Warming] is wrong. Regardless, let’s examine this myth a little closer and see what else we can learn from it.
The “ENSO has No Trend” part of this myth depends on the dataset. That is, since 1900, some sea surface temperature-based ENSO indices show long-term trends, warming and cooling; another is flat. Let’s look at NINO3.4 sea surface temperature anomalies using a number of different datasets. We’ll start with ERSST.v3b and Kaplan, both from NOAA, and HADISST from the Hadley Centre. Refer to Figure 7-1. NINO3.4 sea surface temperature anomalies for the ERSST.v3b, Kaplan, and HADISST datasets are available through the KNMI Climate Explorer Monthly Climate Indices webpage. The ERSST.v3b version of NINO3.4 sea surface temperatures has a significant warming trend, while the Kaplan version of NINO3.4 data shows significant cooling. The HADISST-based NINO3.4 data since 1900 has a slightly negative trend, but it’s basically flat.
Figure 7-2 presents the average of the ERSST.v3b, HADISST and Kaplan versions of NINO3.4 sea surface temperature anomalies. The linear trend of 0.003 deg C per decade is basically flat.
HADSST2 and HADSST3 are also available at the Climate Explorer, but their data for the NINO3.4 region are so sparse at times that there are large gaps, with many missing months. Fortunately, a recent climate paper presented an ENSO index based on HADSST2 sea surface temperature anomalies. The paper was Thompson et al (2009) Identifying signatures of natural climate variability in time series of global-mean surface temperature: Methodology and Insights. We’ll discuss this paper again in another myth. Thompson et al (2009) were kind enough to provide data along with their paper. The instructions for use and links to the data are here. Thompson et al (2009) used the sea surface temperature anomalies for Cold Tongue Index region instead of the more commonly used NINO3.4 region. There are very slight differences between the two datasets. Thompson et al also scaled the data so that they could subtract it from global surface temperatures. We’ll standardize it so the dataset doesn’t look so odd, Figure 7-3. The trend clearly shows cooling. That’s even steeper than the cooling trend in the Kaplan NINO3.4 data.
In summary, sea surface temperature anomaly-based ENSO indices do have trends. The trend depends on the dataset. Most show a cooling trend over the 20th century and on into current times.
That’s not the primary fault with that myth. What defies logic with that fairytale is the idea that a variable source of heat with a flat long-term linear trend cannot raise or lower temperatures over periods of time.
For example, let’s say a hospital recently built a new multistory wing. The engineering department has received complaints about the temperature in a storeroom. Rarely does anyone enter the storeroom, but when they do, the temperature there can be very cool or very warm, or sometimes it’s just right. The storeroom is in the center of the building. It’s surrounded by occupied spaces and there are occupied floors above and below it. The temperatures in all of the spaces surrounding the storeroom are controlled by thermostats to maintain temperatures at 21 deg C (70 deg F). The lights in the storeroom are controlled by an occupancy sensor and there is no equipment in that space causing a heat load. Basically, the storeroom has no heat gains or losses when it’s unoccupied. To save on construction costs, hospital administrators elected not to install a thermostat in the storeroom with a separate supply of heating and cooling. The heating and air conditioning system does, however, serve the storeroom, providing a minimum amount of conditioned air for ventilation. The air conditioned or heated supply air comes from a duct that’s controlled by a thermostat in an adjacent office space, which is unfortunately an exterior zone, with heat losses and heat gains and varying occupancy. The head of the engineering department sends a new hire to the storeroom with a couple of temperature sensors and digital recorder.
After a period of time, the new hire stops by the boiler room to consult with the crusty old boiler room foreman. The new hire explains his findings to foreman. The temperature of the storeroom does vary, and he provides a graph that shows the temperature there initially warmed, then cooled slightly, and then warmed again. See Figure 7-4.
The new hire is baffled, though. The graph of the temperature of the air being supplied to the space, Figure 7-5, shows lots of variability. If he compares the supply air and space temperature, the new hire can see that the temperature of the air being supplied to the space has a strong short-term effect on space temperature. When there’s a short-term supply of warm air, the space temperature warms and, conversely, when there’s a short-term supply of cool air, the space temperature cools. What baffles the new hire is that space temperatures obviously warmed over the long-term, but the supply air temperature shows no trend. In fact, it shows a slight cooling trend.
The boiler room foreman suggests the new hire determine the average temperatures of the supply air entering the space during the early and late warming periods and determine the average supply air temperature for the relatively flat temperature period between them. The new hire returns with a revised graph that shows the average supply air temperatures were in heating mode during the two warming periods and in cooling mode, just slightly, during the period between them. All of the variability had hidden the obvious from him when he looked at the data for the first time. The new hire states the supply air was an uncontrolled supply of variable heating and cooling, and it was causing the space temperatures to warm and cool. The foreman and the new hire go into a more detailed discussion to clarify the reasons for the warming and cooling before the new hire reports back to the head of engineering.
If you hadn’t noticed, I used scaled and ranged NINO3.4 sea surface temperature anomalies since 1900 to create the supply air temperature data in Figures 7.5 and 7.6, and the space temperature in Figure 7-4 bears a striking resemblance to global surface temperatures since 1900 as well. I’m sure some readers will think it was a poor example and that there are better examples I could have used in the discussion above, but let’s look at the bottom line.
Isn’t that all ENSO is? Isn’t ENSO simply a natural, uncontrolled, variable source of heat to the global oceans and atmosphere? Global Land Plus Sea surface temperatures warmed from 1917 to 1944 and warmed again from 1976 to present, and they cooled slightly from 1944 to 1976. Using period-average NINO3.4 sea surface temperatures, we can see that El Niño events dominated the global warming periods, and La Niña events dominated the period between them when global temperatures cooled.
We’ve discussed this in Chapter 5.8 Scientific Studies of the IPCC’s Climate Models Reveal How Poorly the Models Simulate ENSO Processes. Let’s repeat that discussion.
The strength of ENSO phases, along with how often they happen and how long they persist, determine how much heat is released by the tropical Pacific into the atmosphere and how much warm water is transported by ocean currents from the tropics to the poles. During a multidecadal period when El Niño events dominate (a period when El Niño events are stronger, when they occur more often and when they last longer than La Niña events), more heat than normal is released from the tropical Pacific and more warm water than normal is transported by ocean currents toward the poles—with that warm water releasing heat to the atmosphere along the way. As a result, global sea surface and land surface temperatures warm during multidecadal periods when El Niño events dominate. See Figure 7-7. Similarly, global temperatures cool during multidecadal periods when La Niña events are stronger, last longer and occur more often than El Niño events.
The myth “ENSO Has No Trend and Cannot Contribute to Long-Term Warming” is flawed in a number of ways.
THE REST OF THIS SERIES
The remainder of this series of posts will be taken from the following myths and failed arguments. They’re from Section 7 of my book Who Turned on the Heat? I may select them out of the order they’ve been presented here, and I’ll try to remember to include links to the other posts in these lists as the new posts are published.
ALREADY PUBLISHED
1. El Niño-Southern Oscillation Myth 1: El Niño and La Niña Events are Cyclical. Refer also to the cross post at WattsUpWithThat for comments.
2. El Niño-Southern Oscillation Myth 2: A New Myth – ENSO Balances Out to Zero over the Long Term. And please see the WattsUpWithThat cross post.
UPCOMING
Myth – The Effects of La Niña Events on Global Surface Temperatures Oppose those of El Niño Events
Failed Argument – El Niño Events Don’t Create Heat
Myth – El Niño Events Dominated the Recent Warming Period Because of Greenhouse Gases
Myth – ENSO Only Adds Noise to the Instrument Temperature Record and We Can Determine its Effects through Linear Regression Analysis, Then Remove Those Effects, Leaving the Anthropogenic Global Warming Signal
Myth – The Warm Water Available for El Niño Events Can Only be Explained by Anthropogenic Greenhouse Gas Forcing
Myth – The Frequency and Strength of El Niño and La Niña Events are Dictated by the Pacific Decadal Oscillation
And I’ll include a few of the failed arguments that have been presented in defense of anthropogenic warming of the global oceans.
Failed Argument – The East Indian-West Pacific and East Pacific Sea Surface Temperature Datasets are Inversely Related. That Is, There’s a Seesaw Effect. One Warms, the Other Cools. They Counteract One Another.
INTERESTED IN LEARNING MORE ABOUT EL NIÑO AND LA NIÑA AND THEIR LONG-TERM EFFECTS ON GLOBAL SEA SURFACE TEMPERATURES?
Why should you be interested? Sea surface temperature records indicate El Niño and La Niña events are responsible for the warming of global sea surface temperature anomalies over the past 30 years, not manmade greenhouse gases. I’ve searched sea surface temperature records for more than 4 years, and I can find no evidence of an anthropogenic greenhouse gas signal. That is, the warming of the global oceans has been caused by Mother Nature, not anthropogenic greenhouse gases.
I’ve recently published my e-book (pdf) about the phenomena called El Niño and La Niña. It’s titled Who Turned on the Heat? with the subtitle The Unsuspected Global Warming Culprit, El Niño Southern Oscillation. It is intended for persons (with or without technical backgrounds) interested in learning about El Niño and La Niña events and in understanding the natural causes of the warming of our global oceans for the past 30 years. Because land surface air temperatures simply exaggerate the natural warming of the global oceans over annual and multidecadal time periods, the vast majority of the warming taking place on land is natural as well. The book is the product of years of research of the satellite-era sea surface temperature data that’s available to the public via the internet. It presents how the data accounts for its warming—and there are no indications the warming was caused by manmade greenhouse gases. None at all.
Who Turned on the Heat?was introduced in the blog post Everything You Every Wanted to Know about El Niño and La Niña… …Well Just about Everything. The Updated Free Preview includes the Table of Contents; the Introduction; the beginning of Section 1, with the cartoon-like illustrations; the discussion About the Cover; and the Closing. The book was updated recently to correct a few typos.
Please buy a copy. (Credit/Debit Card through PayPal. You do NOT need to open a PayPal account. Simply scroll down past where they ask you to open one.). It’s only US$8.00.
VIDEOS
For those who’d like a more detailed preview of Who Turned on the Heat? see Part 1 and Part 2 of the video series The Natural Warming of the Global Oceans. Part 1 appeared in the 24-hour WattsUpWithThat TV (WUWT-TV) special in November 2012. You may also be interested in the video Dear President Obama: A Video Memo about Climate Change.
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Bob Tisdale: Please advise how you deduced that.
Which part? Not at every relative maximum, or only at relative maxima? And the corresponding inference about the La Ninas at the relative minima?
The easy part is that the the El Ninos never occur at the relative minima. Next you can see that the El Ninos occur in between relative minima. The relative maxima where the El Ninos occur are broader and less extreme than most of the relative maxima at which the El Ninos do not occur.
Bob Tisdale: Proponents of anthropogenic global warming apparently have difficulty comprehending that, so they use misinformation to try to contradict what’s plainly visible.
Possibly there is disagreement about what Is plainly visible .
Volker Doormann says:
December 24, 2012 at 4:38 am
Your reasons are noted and this still hides the behavior in-between the overall trend. The failure to notice a step up from the 1970’s to the 1980’s also weakens your argument.
When a El Nino event declines to average SST’s can you explain where it moves too and support that it only affects the NINO 3.4 narrow strip?
This is from the same data.
The surface for NINO 4 shows significant warming especially towards the recent warm period.
http://img820.imageshack.us/img820/3429/nino4.png
The surface for NINO 3 shows significant warming again towards the recent warm period.
http://img855.imageshack.us/img855/5819/nino3.png
The surface for NINO 1.2 shows warming towards the recent warm period.
http://img705.imageshack.us/img705/2504/nino12.png
The level has been raised from previous periods and it may not continue to rise, but when has warming or cooling only occurred straight away?
Once the level is reached what ever generally happens, it is always around say 0.5c to 1.0c higher on average. That makes quite a difference to global temperatures from previous decades even if it remains the same.
Matt G says:
December 24, 2012 at 1:57 pm
Volker Doormann says:
December 24, 2012 at 4:38 am
Your reasons are noted and this still hides the behavior in-between the overall trend.
No. That impedance cannot create heat because it is a passive element in a heat current hides nothing; it’s a physical law. Regarding ‘behavior in-between the overall trend’ the question is what you talk about and/or what your argument is.
When a El Nino event declines to average SST’s can you explain where it moves too and support that it only affects the NINO 3.4 narrow strip?
The surface for NINO 4 shows significant warming especially towards the recent warm period.
The surface for NINO 3 shows significant warming again towards the recent warm period.
The surface for NINO 1.2 shows warming towards the recent warm period.
The level has been raised from previous periods and it may not continue to rise, but when has warming or cooling only occurred straight away?
We can talk about A.) the measured global temperature function. We can talk about B.) a defined Index called ENSO or MEI or ONI or NINO xyz.
If we talk about A.) we talk about physics of heat, heat current, heat convection, heat radiation. If we talk about B.) we talk about social defined landmark christmas indices for fisherman, and we talk about an ocean oscillator and its geometric and complex elements.
If one would like to analyse global warming he do argue on A.) because (global) warming is invariant to earth locations.
You do argue on B.) claiming that ‘shows significant warming’, but the point is that because B.) is a relative value it is nonsense to speak on ‘significant warming’.
You can crosscheck all NINO data tables for its mean values. Because the values are differences of an terrestrial oscillator, but not absolute temperature values, the mean value should be zero after many ENSO cycles of 3.55 years and 4.73 years (subharmonics of the Chandler wobble period of 1.182783 years), or near zero after about 60 years. This is fulfilled with values between -0.15 °C. and -0.27 °C. for all four indices for standard deviations of 0.625 to 1.072 ° C.
http://www.volker-doormann.org/images/nino_4.gif
A 3rd order polynomial on the data of NINO 3.4 with a maximum in the 1990s confirmed with that global temperature like function, that the definition of this NINO 3.4 is not free from the global temperature function using this time span of 60 years. But it is nonsense to argue B.) using A.)
The data I have used in my prior graph are taken from the web site http://www.esrl.noaa.gov/psd/data/correlation/oni.data
Bob gave this URL;
http://www.cpc.ncep.noaa.gov/products/analysis_monitoring/ensostuff/ensoyears.shtml
The mean value ofboth 754 data points is +0.0101 Centigrade, have minimum of -2 Centigrade, a maximum of 2.4 Centigrade.
I do not know, what the reason of the difference in definition is, but this mean value confirms that ENSO is free from the global warming function.
V.
Volker Doormann says:
December 25, 2012 at 6:29 am
The ENSO was only made free from the global warming function by removing the warming from the data shown in my previous post. The bottom half in quotation marks is the description what was done and why. Hence, the reason why the data you use shows a mean +0.0101 Centigrade. This is the reason why I was saying this was hiding the behavior in the overall trend because it has already had warming removed. What will conclude this disagreement in future if a period of mainly La Ninas occur and global temperatures fall, it will back my point of view from observed science data.
It is fair to describe the ENSO as an indices that doesn’t describe on it’s own how much it really affects global temperatures. Bob’s mentioned about the process before, what this involves and the ENSO indices looks only a little part of it. The warm ocean pool from NINO 3.4 can be seen moving towards the western Pacific ocean and then moving slowly NE until it reaches the NW part of the Pacific ocean.
With your A & B description despite B only being a part of the process it still affects A very significantly while it is pooling in the NINO 3 and 4 regions. I agree after 60 years this seems to cover both the peak and trough, but saying it doesn’t affect global temperatures in the long run during it’s peak or trough is wrong.
“Due to a significant warming trend in the Niño-3.4 region since 1950, El Niño and La Niña episodes that are defined by a single fixed 30-year base period (e.g. 1971-2000) are increasingly incorporating longer-term trends that do not reflect interannual ENSO variability. In order to remove this warming trend, CPC is adopting a new strategy to update the base period.
There will be multiple centered 30-year base periods that will be used to define the Oceanic Niño index (as a departure from average or “anomaly”). These 30-year base periods will be used to calculate the anomalies for successive 5-year periods in the historical record: ”
I have failed to see scientific evidence that this warming trend does not reflect interannual ENSO variability. Any assumption in science is usually the dangerous route to take. What would happen if we took these 5 year periods on 30 year bases and applied that to global temperatures?
Matt G says:
December 26, 2012 at 1:48 pm
Volker Doormann says:
December 25, 2012 at 6:29 am
[….]
EOD.
V.
Volker Doormann says:
December 25, 2012 at 6:29 am
The entire process of ENSO shows a mechanism involving energy from the sun.
Without taking into account changing TSI reaching the surface of the ocean this will be greatly incomplete and missing the main input of solar energy over the period. A 4 percent increase in global low cloud levels will put the Earth back to global temperatures of the 1970′s. Dismissing solar warming without even considering this important observation of the period is complete ignorance.
Notice El Nino’s roughly got stronger during the period while global low cloud albedo was declining. Since 2006 low global cloud has stopped declining therefore based on the ENSO knowledge so far future El Nino’s will not be stronger than the 1997/98 one unless a further decrease in global low cloud albedo occurs in future. Therefore based on what’s been happening recently El Nino’s should become stable/ weaker and any increases in global low cloud albedo in future will further weaker them. The process of ENSO moving warm surface water around the globe towards the pole will be reduced and therefore rises in global temperatures also reduced. This will then lead to peaks and troughs in the ENSO swings at lower levels than compared over the recent warm period.
This below mainly describes the energy mechanism involving the process of ENSO and therefore the indices can only reflect the energy available to it, just on the surface of the ocean in these NINO regions. This is combined with the other observation regarding the solar/ocean mechanism and why a TSI stable period doesn’t show up soon as the sun cycle does.
This is because when the solar activity reached an increased level during the 1950′s the trade winds were generally strong over this period right through to mid 1970′s. These resulted in plenty of up welling ocean water and warming ocean water from the sun was piled towards the western side of the Pacific Ocean circling to greater depths. This resulted in energy not calculated in surface temperatures because it was below the surface and not allowed to spread East over the ENSO surface region. Data during this period in the ocean depths were very limited so missed this increased energy around the western areas of the Pacific Ocean.
Post 1970′s the trade winds declined for longer periods especially beginning with the Pacific shift and moderate/strong El Nino in the early 1980′s . (What you should note is that this Pacific shift warmed the ENSO region up after this event and therefore the new changes to the ENSO indices are based on removal of the Pacific shift. This resulted in the warmed sub-ocean water that had not been calculated over the recent decades surface temperatures, (1950/1960′s etc) surfacing across the central and eastern Pacific and warming global temperatures in it’s wake. This process delayed the warming from the increased solar cycle until the trade winds become weak and allowed warmer water to form much more over the surface and be eventually lost by the atmosphere. Suddenly this warmed the planet from the tropics to the poles via the process of ENSO.
Matthew R Marler says: “The easy part is that the the El Ninos never occur at the relative minima. Next you can see that the El Ninos occur in between relative minima. The relative maxima where the El Ninos occur are broader and less extreme than most of the relative maxima at which the El Ninos do not occur.”
I’m still puzzled by your claims about the maxima and minima of an ENSO index. The data in the graph you referenced…
http://bobtisdale.files.wordpress.com/2012/12/figure-1.png
…is a graph of a commonly used ENSO index—the sea surface temperature anomalies of the NINO3.4 region. When sea surface temperatures there rise above a threshold (not the fact that they have reached a maximum), an El Nino is taking place. Conversely, when the sea surface temperatures in the NINO3.4 region drop below a threshold (not the fact that they have reached a minimum), a La Nina is said to be taking place.
Volker Doormann says: “This result tells me that the two data tables are identical. Moreover the mean value of +0.0101 Centigrade @ur momisugly a standard deviation of 0.809 tells me that there is no significant offset in the 754 data points, which means to me that ENSO has no (significant) trend and cannot contribute to long-term warming.”
You obviously overlooked portions of my reply to you. I’ll repeat the appropriate portion:
Volker Doormann says: “The linear trend of the NINO 3.4 region is – 0.11 Centigrade for the last 50 years.
http://www.volker-doormann.org/images/down_10.gif”
The ONI data you’ve plotted is NOT a “Three month running mean of NOAA ERSST.v2 SST anomalies in the NINO3.4 region (5S-5N, 120-170W) based on the 1971-2000 base years” as you note on your graph. You provided this link to the data:
http://www.esrl.noaa.gov/psd/data/correlation/oni.data
Problem 1: NOAA stopped using ERSST.v2 for its ONI index a few years ago. They now use ERSST.v3b.
Problem 2: NOAA stopped using 1971-2000 as the base years for anomalies earlier this year. They use (freakish) shifting base years now, described here:
http://www.cpc.ncep.noaa.gov/products/analysis_monitoring/ensostuff/ensoyears.shtml
And further described here:
http://www.cpc.ncep.noaa.gov/products/analysis_monitoring/ensostuff/ONI_change.shtml
And I critiqued their changes to ONI here:
http://bobtisdale.wordpress.com/2012/06/05/comments-on-noaas-recent-changes-to-the-oceanic-nino-index-oni/
HHHHHHHHHHHHH
In summary, Volker Doormann, the ONI data you plotted and continue to misunderstand does not represent sea surface temperature anomalies against a 30-year base period.
Additionally, a variable source of heat does not need to have a trend in order to contribute to a long-term warming. That was the subject of this post, which you have also failed to grasp.
Good-bye, Volker Doormann. You appear to have purposely overlooked portions of my earlier reply to you. I’m finished with my efforts to explain this.
„El Niño-Southern Oscillation Myth 3: ENSO Has No Trend and Cannot Contribute to Long-Term Warming
Let’s look at NINO3.4 sea surface temperature anomalies using a number of different datasets. The ERSST.v3b version of NINO3.4 sea surface temperatures has a significant warming trend, while the Kaplan version of NINO3.4 data shows significant cooling. The HADISST-based NINO3.4 data since 1900 has a slightly negative trend, but it’s basically flat. Figure 7-2 presents the average of the ERSST.v3b, HADISST and Kaplan versions of NINO3.4 sea surface temperature anomalies. The linear trend of 0.003 deg C per decade is basically flat.
In summary, sea surface temperature anomaly-based ENSO indices do have trends. The trend depends on the dataset. Most show a cooling trend over the 20th century and on into current times. What defies logic with that fairytale is the idea that a variable source of heat with a flat long-term linear trend cannot raise or lower temperatures over periods of time.
Isn’t ENSO simply a natural, uncontrolled, variable source of heat to the global oceans and atmosphere?
The strength of ENSO phases, along with how often they happen and how long they persist, determine how much heat is released by the tropical Pacific into the atmosphere and how much warm water is transported by ocean currents from the tropics to the poles.
During a multidecadal period when El Niño events dominate (a period when El Niño events are stronger, when they occur more often and when they last longer than La Niña events), more heat than normal is released from the tropical Pacific and more warm water than normal is transported by ocean currents toward the poles—with that warm water releasing heat to the atmosphere along the way.
As a result, global sea surface and land surface temperatures warm during multidecadal periods when El Niño events dominate.
Similarly, global temperatures cool during multidecadal periods when La Niña events are stronger, last longer and occur more often than El Niño events.”
The ONI function over time contains a lot of harmonic modes.
Using some of this modes the ONI spectrum can be reconstruct also for the future.
The global temperature spectra like hadcrut4 shows anomalies from these harmonic modes especially if there are amplitudes of different modes have their extremes at the same time like 1998 to 2000.
Despite a phase shift between the ONI spectrum and the global temperature a subtraction shows that the remaining function is freed from the ONI modes.
http://www.volker-doormann.org/images/oni_modes.gif
The remaining temperature function, containing mostly periods under a calendar year cannot explained with terrestrial geometric functions, and not by an damped oscillator like ONI, but can explained with solar tide functions of the inner planets of the Sun.
http://www.volker-doormann.org/images/oni_etc.gif
This is shown by the high resolution functions of global temperatures and solar functions
http://www.volker-doormann.org/images/uah_rss_ghi11_r_nov_2012.gif
All these investigations show that as well the ONI is based on a very geometrical function but also the high frequency temperature anomalies of ~6.30 periods per year connected time coherent to the global sea level oscillations.
Thank You all.
V.
Bob Tisdale: “We’ve discussed and illustrated in Section 5 of this book how ENSO has been responsible for the warming of global sea surface temperatures over the past 30 years. In fact, the intent of this book was to provide the reader with a strong enough background in ENSO to understand why this myth [ENSO Has No Trend and Cannot Contribute to Long-Term Warming] is wrong.“
Volker Doormann says:
December 20, 2012 at 2:06 pm
There are two different simple geometry oscillations to discriminate. Earth and Sun.
Suns oscillations from solar tides are clear visible, if one detracts the ONI/MEI/ENSO oscillations from the global temperature.
This is also confirmed if the (scaled) ONI function is taken and shifted by a phase step of 0.45 years to match the low frequency pattern of the RSS global land/ocean data, and is subtracted from the monthly RSS global land/ocean temperature data.
http://www.volker-doormann.org/images/oni_cleaned_rrs_temps.gif
The remaining RSS temperature curve (Red thick) shows a remarkable correlation with the solar tide function (Blue thick) for this time span or any other time span.
That means simple that the ENSO cleaned RSS global temperatures do show only temperature anomalies which are coherent in phase with solar tide functions.
The conclusion that because the global warming pattern cannot explained or created by a greenhouse effect and must therefore be created by the ENSO resonances, is a fallacy known as ‘Bifurcation, also referred to as the “black and white” fallacy and “false dichotomy,” bifurcation occurs if someone presents a situation as having only two alternatives, where in fact other alternatives exist or can exist.’
One other known alternative exist to explain the global warming pattern as a superimposition of solar tide functions corresponding to a solar heat power processand the terrestrial ocean stream resonances known as ONI or ENSO, which cannot create more heat as the heat input it gets from the Sun, as everybody knows.
V.