The 2014 15 El Niño – Part 16 – September 2014 Update – Still Seeing Mixed Signals

(Oops.  Fixed a typo in the title.  This is Part 16.)

This post provides an update on the progress of the evolution of the 2014/15 El Niño (assuming there will be one) with data through the end of August 2014. The post is similar in layout to the past updates:  May, June, July and August.  The post includes 3 large gif animations and 15 illustrations so the post might take a few moments to load on your browser.  Please click on the illustrations and animations to enlarge them.

Included are updates of the weekly sea surface temperature anomalies for the four most-often-used NINO regions. Also included are updates of the GODAS map-based animations of sea surface height anomalies, T300 anomalies (depth-averaged temperature anomalies to 300 meters), sea surface temperature anomalies, and the cross sections of temperature anomalies at depth along the equator. These animations start in January 2014 for the full progress of this year’s events. Also included are a couple of graphs of the BOM and the NOAA Equatorial Southern-Oscillation Indices (SOI and ESOI).

There’s a new the downwelling (warm) Kelvin wave making its way east along the equator in the Pacific, so we’ll continue to show the warm water volume anomalies and depth-averaged temperature anomalies from the NOAA TOA project website.

Then, we’ll take a look at a number of Hovmoller diagrams, comparing the progress so far this year to what happened in 1982.  We had been using 1997 as a reference, but we’re well past this year’s event coming anywhere close to the one in 1997/98, so I’ve switched to 1982, which was a late bloomer.


In earlier updates, with time-series graphs, we compared the evolution of the 2014/15 El Niño to the 1982/83 and 1997/98 El Niños. There’s no reason to continue to use the 1997/98 El Niño as a reference, so I’ve included the most recent strong El Niño (2009/10) along with the 1982/83 El Niño.   No, I’m not saying this year’s El Niño, if one forms, will be as strong as the one in 2009/10.  I’m simply using the 2009/10 El Niño as a reference.


Figure 1 includes the weekly sea surface temperature anomalies of the 4 most-often-used NINO regions of the equatorial Pacific. From west to east they include:

  • NINO4 (5S-5N, 160E-150W)
  • NINO3.4 (5S-5N, 170W-120W)
  • NINO3 (5S-5N, 150W-90W)
  • NINO1+2 (10S-0, 90W-80W)

Of the four listed, the NINO3.4 region is the most commonly used sea surface temperature-based ENSO index. See the illustration here for the location of the NINO3.4 region.  The NOAA Oceanic NINO Index is based on the sea surface temperatures of the NINO3.4 region.

As of the week centered on Wednesday August 27th, the sea surface temperature anomalies in the NINO4 and NINO1+2 regions were still elevated, while the NINO3 and NINO3.4 regions are warming (rebounding) but not yet at the threshold of El Niño conditions, where El Niño conditions are defined as sea surface temperature anomalies equal to or greater than +0.5 deg C.

01 ENSO Indices

Figure 1


Using weekly sea surface temperature anomalies for two NINO regions, Figure 2 updates the comparisons of the evolutions of this El Niño with the 1982/83 and 2009/10 events.  The NINO3.4 and NINO1+2 comparisons were originally provided in the post Part 3 – Early Evolution – Comparison with 1982/83 & 1997/98 El Niño Events.

02 ENSO Indices Evolution

Figure 2

The weekly Reynolds OI.v2 data for Figures 1 and 2 are available through the NOAA NOMADS webpage here.


In the first post in this series, we discussed a number of animations of maps and animations of equatorial cross sections available from the NOAA Global Ocean Data Assimilation System (GODAS) website.  Each cell of the animation is a 5-day (pentadal) average. Those animations ran from January 3rd to March 29th. The following are updates, again starting in January 3rd.  GODAS only maintains their animations for 3 months.  I’ve stored the maps since the first of the year and will continue to add maps as time progresses.  That way we can watch the El Niño unfold from the beginning and then try to keep track of the warm water when El Niño is over.

Animation 1 provides the sea surface height anomalies and the depth-averaged temperature anomalies for the top 300 meters (T300) side by side.

Animation 1 SSH v T300

Animation 1

Animation 2 is a similar side-by-side comparison, but on the left are maps of sea surface temperature anomalies and on the right are the T300 maps. The sea surface temperature maps trail the others by a pentad or two, which is why they do not run through July 2.  (My apologies for the shift in the color scaling for the range of +0.5 to +1.0 deg C in the sea surface temperature anomaly maps.  That appears to be a quirk of my computer, not the GODAS website.)

Animation 2 SST v T300

Animation 2

Animation 3 is an update of the cross sections of temperature anomalies at depth along the equator.

Animation 3 Cross Section

Animation 3

The following are links to the animations of the maps individually.  There’s no color shift:

The new warm anomaly in the western equatorial Pacific is shown in Figure 3. It has worked its way eastward with the Equatorial Undercurrent in the Pacific (the Cromwell current).  The anomaly has also increased in strength as it worked its way to the east, because the subsurface waters in the east are normally cooler than they are in the west.

03 Cross Section for 2014-08-31

Figure 3

Curiously, the new Kelvin wave does not make its presence known along the equatorial Pacific in the GODAS sea surface height anomalies map (top cell of Figure 4), but it is visible in the depth-averaged temperature anomalies for the top 300 meters (bottom cell).

04 SSH and T300 8-31-14 Pentad

Figure 4


The NOAA Tropical Atmosphere-Ocean (TAO) Project website includes data for two temperature-related datasets for the equatorial Pacific.  See their Upper Ocean Heat Content and ENSO webpage for descriptions of the datasets.   The two datasets are Warm Water Volume (above the 20 deg C isotherm) and the Depth-Averaged Temperatures for the top 300 meters (aka T300).  Both are available for the:

  • Western Equatorial Pacific (5S-5N, 120E-155W)
  • Eastern Equatorial Pacific (5S-5N, 155W-80W)
  • Equatorial Pacific (5S-5N, 120E-80W)

Keep in mind that the longitudes of 120E-80W stretch 160 deg, almost halfway around the globe. For a reminder of width of the equatorial Pacific, see the protractor-based illustration here.

In the following three graphs, we’re comparing data for the evolution of the 2014/15 El Niño so far (through August 2014) with the data for the evolutions of the 1982/83 and 2009/10 El Niños. The Warm Water Volume data are the top graphs and the depth-averaged temperature data are the bottom graphs.  As you’ll see, the curves of two datasets are similar.

Let’s start with the Western Equatorial Pacific (5S-5N, 120E-155W), Figure 5. The warm water volume and depth-averaged temperature data show the Western Equatorial Pacific presently have more warm water available in the western equatorial Pacific for an El Niño than during the evolutions of the 1982/83 and 2009/10 El Niños.

05TAO WWV and T300 Evolution West

Figure 5

The warm water volume and depth-averaged temperature data for the eastern equatorial Pacific (Figure 6) show lower values in 2014 than in 1982 and 2009, indicating that the eastern subsurface equatorial Pacific is cooler now than it had been in those prior years.  This year, the eastern equatorial data both rose, a result of the Kelvin wave carrying warm water from the West Pacific Warm Pool to the east.  Most of that warm water in the east has now been consumed, either released to the atmosphere through evaporation or distributed away from the equator.

06 TAO WWV and T300 Evolution East

Figure 6

As a result, across the entire equatorial Pacific, Figure 7, warm water volume (top cell) is lower in 2014 than it was in 1982 and 2009.  Looking at the depth-average temperature anomalies, they’re higher than they were in 1982 but lower than the 2009 August value. For this year, the warm water initially increased across the entire equatorial Pacific, as warm water from off the equator circulated to the equator. Then the warm water decreased as it evaporated or was redistributed from the equator.

07 TAO WWV and T300 Evolution Total

Figure 7

The NODC has updated their Ocean Heat Content data for April to June 2014, but we’re still waiting for update at the KNMI Climate Explorer.  It will be interesting to see what effect this off-season El Niño has had on the ocean heat content of the tropical Pacific.


The reasons an El Niño did not continue to form this year in response to the Kelvin wave are well established. First, the atmospheric component of ENSO, the “SO” part, refused to cooperate.  That is, the trade winds in the western equatorial Pacific did not weaken as expected to help reinforce the El Niño development. (The other reason, of course, was the upwelling (cool) Kelvin that formed in the wake of the downwelling (warm) Kelvin wave. That trailing cool Kelvin wave had counteracted the earlier warm Kelvin wave, the latter of which had everyone so excited earlier this year…me included.)

The Southern Oscillation Index (SOI) from Australia’s Bureau of Meteorology is another widely used reference for the strength, frequency and duration of El Niño and La Niña events.  We discussed the Southern Oscillation Index in Part 8 of this series. It is derived from the sea level pressures of Tahiti and Darwin, Australia, and as such it reflects the wind patterns off the equator in the southern tropical Pacific.  With the Southern Oscillation Index, El Niño events are strong negative values and La Niñas are strong positive values, which is the reverse of what we see with sea surface temperature based indices.  The August 2014 Southern Oscillation Index value is -11.5, which is within El Niño conditions. The BOM threshold for El Niño conditions is an SOI value of -8.0, so we’re there, the atmosphere is cooperating, according to the BOM SOI.  Figure 8 presents a time-series graph of the SOI data.


Figure 8

The top graph in Figure 9 compares the evolution of the SOI values this year to those in 1982 and 2009, the development years of the strong 1982/83 and 2009/10 El Niños.  The Southern Oscillation Index this year is lagging well behind the values in 1982, but it’s ahead of the game compared to 2009.  Because the SOI data is so volatile, I’ve smoothed them with a 3-month filter in the bottom graph.

09 BOM SOI Evolution

Figure 9

For those of you interested in keeping a closer eye on the BOM Southern Oscillation Index, see the BOM Recent (preliminary) Southern Oscillation Index (SOI) values webpage. For the past month, the 30-day running-average of the SOI has been cycling near to or within El Niño conditions.

BUT…Big but.

We’re getting a totally different indication from the NOAA Equatorial Southern Oscillation Index.  As discussed in Part 8 of this series, the BOM SOI is based on sea level pressures off of the equator (where El Niños and La Niñas take place), and, as a result, the BOM SOI can be impacted by weather events that aren’t related to El Niño and La Niña events.  The NOAA Equatorial Southern Oscillation Index is based on sea level pressures along the equator. (Data are here.)  As shown in Figure 10, the Equatorial Southern Oscillation Index value for August 2014 is slightly positive, well with ENSO-neutral conditions, and leaning ever so slightly toward La Niña conditions.

10 Equatorial SOI

Figure 10

But that does not mean an El Niño can’t form.  The August 2014 Equatorial Southern Oscillation Index reading is comparable to the value in 2009, as is the most recent 3-month average.  See Figure 11. But it’s far behind the development of the 1982/83 El Niño.

11 Equatorial SOI Evolution

Figure 11


In past updates, in the following Hovmoller diagrams, I’ve used the development of the 1997/98 El Niño as a reference for this year’s El Niño. That now seems to be overkill, because the feedbacks never kicked in this year…where all of the feedbacks freakishly aligned for the 1997/98 El Niño.  The 1982/83 El Niño was a late bloomer; that is, it didn’t really start to take off until later in the year, and it was a very strong El Niño too. So I’ve switched reference years for this post.  Next month, I may switch over to the 2009/10 El Niño.

Hovmoller diagrams are a great way to display data.  If they’re new to you, there’s no reason to be intimidated by them. Let’s take a look at Figure 12.  It presents the Hovmoller diagrams of thermocline depth anomalies (the depth of the isotherm at 20 deg C) with 2014 on the left and 1982 on the right. GODAS, unfortunately, furnishes the illustrations (not the data) in different dimensions for the two years.  The vertical (y) axis in both is time with the Januarys for both years at the top and Decembers at the bottom.  The horizontal (x) axis is longitude, so, moving from left to right, we’re going from west to east…with the Indian Ocean in the left-hand portion, the Pacific in the center and the Atlantic in the right-hand portion.  We’re interested in the Pacific. The data are color-coded according to the scales below the Hovmollers.

12 GODAS Thermocline Depth Anomalies 2014 v 1982

Figure 12

Figure 12 is presenting the depth of the 20 deg C isotherm along a band from 2S to 2N. The positive anomalies, working their way eastward since the beginning of 2014, were caused by the downwelling Kelvin wave, which pushes down on the thermocline (the 20 deg C isotherm).  You’ll note how the anomalies grew in strength as the Kelvin wave migrated east. That does not mean the Kelvin wave is getting stronger as it traveled east; that simply indicates that the thermocline is normally closer to the surface in the eastern equatorial Pacific than it is in the western portion.

Figure 13 presents the 2014-to-date and 1982 Hovmollers for wind stress (not anomalies) along the equator.   The simplest way to explain them is that they’re presenting the impacts of the strengths and directions of the trade winds on the surfaces of the equatorial oceans. In this presentation, the effects of the east to west trade winds at various strengths are shown in blues, and the reversals of the trade winds into westerlies are shown in yellows, oranges and reds.

13 GODAS Zonal Wind Stress 2014 v 1982

Figure 13

The two westerly wind bursts shown in red in the western equatorial Pacific in 2014 are associated with the downwelling Kelvin wave, and the westerly bursts in March and May 1982 are associated with the Kelvin wave that year. (See the post ENSO Basics: Westerly Wind Bursts Initiate an El Niño.)  Note how in 1982, as the June progressed through December, the negative wind stresses decreased (associated with a weakening of the trade winds), with the neutral whites expanding eastward. Also note the repeated westerly wind bursts in the western equatorial Pacific from June through November, with the big one in November 1982.  Those westerly wind bursts throughout 1982 continued to help push warm water from the western equatorial Pacific into the east, strengthening the 1982/83 El Niño.

We’re, obviously, still waiting for some westerly wind bursts to help reinforce an El Niño in 2014.  In fact, without westerly wind bursts, that downwelling (warm) Kelvin wave, the new one that’s presently working its way east, will probably not be strong enough to create an El Niño.  For an El Niño to form, it needs atmospheric feedback in the form of extra westerly bursts to push additional warm water to the east.

Figure 14 presents the Hovmollers of wind stress anomalies…just a different perspective.  Note how there were more positive wind stress anomalies in the western equatorial Pacific in 1982 than there have been so far this year.

14 GODAS Zonal Wind Stress Anomaly 2014 v 1982

Figure 14

And Figure 15 presents the Hovmollers of sea surface temperature anomalies. Unfortunately, the Hovmoller of sea surface temperature anomalies is delayed a few weeks.  But as we’ve seen in the comparison graphs in Figure 2, the sea surface temperature anomalies of the NINO3.4 region in 2014 are well behind those of 1982, and the sea surface temperature anomalies this year in the NINO1+2 region are in line with those in 1982.  As you’ll note in the Hovmoller for this year, it didn’t take long for the La Niña conditions in the eastern equatorial Pacific to disappear.  The El Niño conditions also disappeared as quickly.

15 GODAS SST Anomaly 2014 v 1982

Figure 15


We discussed what appears to have been a climate shift in the Pacific in a recent post.  See On The Recent Record-High Global Sea Surface Temperatures – The Wheres and Whys.


And for additional introductory discussions of El Niño processes see:


My ebook Who Turned on the Heat? goes into a tremendous amount of detail to explain El Niño and La Niña processes and the long-term aftereffects of strong El Niño events.  Who Turned on the Heat? weighs in at a whopping 550+ pages, about 110,000+ words. It contains somewhere in the neighborhood of 380 color illustrations. In pdf form, it’s about 23MB. It includes links to more than a dozen animations, which allow the reader to view ENSO processes and the interactions between variables.

I’ve lowered the price of Who Turned on the Heat? from U.S.$8.00 to U.S.$5.00.  A free preview in pdf format is here.  The preview includes the Table of Contents, the Introduction, the first half of section 1 (which was provided complete in the post here), a discussion of the cover, and the Closing. Take a run through the Table of Contents.  It is a very-detailed and well-illustrated book—using data from the real world, not models of a virtual world. Who Turned on the Heat? is only available in pdf format…and will only be available in that format.  Click here to purchase a copy.  Thanks. (I also am very happy to receive tips or donations.)

About Bob Tisdale

Research interest: the long-term aftereffects of El Niño and La Nina events on global sea surface temperature and ocean heat content. Author of the ebook Who Turned on the Heat? and regular contributor at WattsUpWithThat.
This entry was posted in 2014-15 El Nino Series, El Nino-La Nina Processes, ENSO Update. Bookmark the permalink.

17 Responses to The 2014 15 El Niño – Part 16 – September 2014 Update – Still Seeing Mixed Signals

  1. craigm350 says:

    Reblogged this on CraigM350 and commented:
    Excellent info as always Bob. Thanks.

  2. Thanks, Bob. Very good information!
    “Curiously, the new Kelvin wave does not make its presence known along the equatorial Pacific in the GODAS sea surface height anomalies map (top cell of Figure 4), but it is visible in the depth-averaged temperature anomalies for the top 300 meters (bottom cell).”
    Is this a stealth El Niño? The MEI also shows it as very slight right now.

  3. BTW, I just added an Index of Graphics to my Climate Change pages, and you are in it with your “Long-Term Effects of Strong El Niño Events on Global Surface Temperatures”.

  4. Bob Tisdale says:

    Thanks, Andres.


  5. Keitho says:

    Hi Bob this is a bit off topic so I apologise in advance but I don’t know where else to ask this.

    I keep on seeing references to the effect that El Nino causes an acceleration of sea level rise due to the warming of the Pacific. My understanding is that the heat isn’t new it has just changed position, coming to the surface from somewhere deeper. If there is no new heat how can that affect sea surface level? Indeed, I presume that as the ocean is now giving up heat to the atmosphere the overall temperature of the ocean must be falling even if it is only in a notional way.

    Why is the link between El Nino and accelerating sea level made? Is it to do with something other than thermal expansion such as air pressure or water vapour or somesuch? I would welcome your thoughts.

    Warm Regards

  6. Bob Tisdale says:

    Keitho, where have you read that the heat driving the sea level rise in the western tropical Pacific wasn’t knew?

  7. Keitho says:

    Sorry Bob, I wasn’t very clear. I know that the heat was being added to the oceans but El Nino was simply heat being raised from the depths to the surface and so could not add to the total heat by itself, it was just heat being moved about. That being the case how could the El Nino accelerate sea level rise when it is being redistributive rather than additional?

  8. Bob Tisdale says:

    Keitho, many times people with use “El Nino” in a generic sense for the overall processes that present themselves as El Nino and La Nina events. I wasn’t sure if you were using it in that way…still not 100% sure, but I suspect you’re not.

    Sea level anomalies, in part, reflect the heat content anomalies of the total water column…sea surface to sea floor. Ocean heat content data for the tropical Pacific (0-700 meters) show they jumped upwards in response to the 1995/96 La Nina, and that the release from the 1997/98 El Nino was replaced by the 1999-01 La Nina. (La Ninas are of course fueled by sunlight.) So those two La Ninas serve as the primary sources of the heat that caused sea levels to rise in the western tropical Pacific.

    In other words, because satellite-era sea level anomalies data begin in 1991, the trends in the western tropical Pacific are biased positive by those two strong La Ninas.

  9. Keitho says:

    Thanks Bob. I understand now that it is in fact new heat that drives the La Nina effect and causes the accelerated sea level rise. I appreciate your patience.


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  17. Pingback: Final – The 2014/15 El Niño – Part 22 – January 2015 Update – You Make the Forecasts for the 2015/16 Season * The New World

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