El Niños and La Niñas are parts of naturally occurring, sunlight-fueled processes—amazing processes—that produce warm water and redistribute it from the tropical Pacific. When I was first able to fathom the processes, when they finally clicked for me, I was in awe of Mother Nature’s handiwork. Cloud cover, sunlight, ocean heat content, sea surface temperatures, sea level, surface winds, ocean currents, etc., all interwoven, all interdependent, with the events occurring at massive scales. I’ve been sharing their complexity, magnitude and aftereffects ever since. Hopefully, this post will allow you to gain some insight–or spark your interest.
El Niño and La Niña events are extremely important parts of Earth’s climate. They are the dominant mode of natural climate variability on annual, multiyear and decadal timeframes. El Niño and La Niña events impact everything from drought and rainfall to surface temperatures around the globe. Consider this: El Niños and La Ninas occur in the tropical Pacific, but more than a decade ago it was determined that they rearranged sea ice in the Southern Ocean surrounding Antarctica. Recently, they were even linked to temperature of the water below the Antarctic sea ice, through changes in ocean wind patterns. See Dutrieux et al. (2014) Strong Sensitivity of Pine Island Ice-Shelf Melting to Climatic Variability and the corresponding ScienceDaily article here.
The following is Section 1 from my ebook Who Turned on the Heat? This presentation was created to fill the gap between overly scientific texts and the basic (but way too simple) descriptions of El Niño and La Niña processes that are available on the internet. As I noted above, hopefully, it will help you to understand those seemingly complex processes. Please ask questions.
Notes: I’ve struck through text from the book (strikethrough) where it refers to other sections of the book, and I deleted a short note that refers to a feature of Abobe readers (the book is in pdf format). This post contains 29 illustrations, so it may take a little while to load. If they don’t appear full-sized, just give them a click.
[START OF SECTION 1 OF WHO TURNED ON THE HEAT?]
1.1 Preliminary Discussion of the ENSO Annotated Illustrations
Most introductions to the El Niño-Southern Oscillation (ENSO) on the web include boiler-plate descriptions and three illustrations: one each for El Niño, La Niña and ENSO-neutral phases. The reader has to jockey back and forth, scrolling up and down, to read the text and compare it to the illustrations. Unfortunately, much of what’s discussed in the text of those ENSO introductions isn’t shown in the graphics. To overcome that, I’ve prepared a 29-cell series of annotated (cartoon-like) illustrations that first introduce readers to background information about the Pacific Ocean. There are also introductions to trade winds and ocean currents, both of which have important roles in ENSO. With multiple cartoon-like illustrations for each phase and the transitions between them, the reader is taken through a complete cycle of ENSO phases: ENSO neutral to El Niño, back to ENSO neutral, on to La Niña, and then back to ENSO neutral. At each phase, the interaction between sea surface temperatures across the tropical Pacific, trade winds, sea surface height, precipitation and subsurface ocean temperatures are illustrated and discussed. Also presented are the differences between El Niño and La Niña events and the reasons why global surface temperatures vary in response to ENSO events.
To reinforce and confirm what’s presented in this section, Section 3 includes more-detailed, data-reinforced descriptions and illustrations.
1.2 The ENSO Annotated Illustrations
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Now’s a good time to take a quick break from the cartoon-like illustrations. We’ll go into more detail in Section 3 about the interrelated processes taking place before an El Niño, but it’s important now to reinforce what’s been discussed so far. I’ll reword the presentation a little with hope that it will help make things click for you.
The trade winds are an important part of our discussion of ENSO-neutral, or “normal”, conditions in the tropical Pacific. They blow from east to west across the surface and cause the surface waters to also travel from east to west. That makes sense. If you blow on a liquid long and hard enough, the surface of the liquid will move it the direction you’re blowing.
The trade winds also blow clouds toward the west. That’s not hard to imagine, either. This allows that wonderfully strong tropical sun to beat down on the surface of the tropical Pacific and to reach into the subsurface waters to depths of 100 meters. Though most of that sunlight is absorbed nearer the surface, in the top 10 meters (roughly 33 feet) or so, it does reach farther. All of Mother Nature’s glorious sunlight warms the tropical Pacific waters as they travel west.
The trade winds push the waters up against the land masses of Indonesia and Australia. This causes the warm water to, in effect, pile up in the western tropical Pacific, in an area called the west Pacific Warm Pool. The trade winds driving the westward movement of surface waters also draw cool waters from below the surface of the eastern equatorial Pacific, in a process called upwelling. That upwelled water provides a continuous source of cool water at a relatively constant temperature that’s then warmed by the sun as it travels west. The water is, therefore, cooler in the eastern equatorial Pacific, in an area called the Cold Tongue Region, than it is in the west Pacific Warm Pool. Remember, the tropical Pacific stretches almost halfway around the globe, so that nice cool supply of water in the east travels a long way under the tropical sun before it reaches the warm pool in the west.
The trade winds cause the temperature difference between the east and west portions of the tropical Pacific. Now, here’s the interesting part. The temperature difference between the eastern and western tropical Pacific causes the trade winds to blow. That’s right. The temperature gradient of the tropical Pacific sea surface temperatures and the trade winds interact with one another in a positive feedback loop called Bjerknes feedback.
Why does that happen?
There nothing mysterious going on. The warmest water is in the western tropical Pacific. We’ve discussed that, and we’ll confirm it in Section 3. The warm water there heats the air above it, and that relatively hot air rises. All of that rising hot air has to be replaced by other air, and it’s the trade winds out of the east that supply the necessary make-up air. Because the tropical Pacific is cooler in the east, the air sinks there, and eastward-blowing upper winds complete the circuit. Overall, the warm air rises in the west; it cools as it’s carried east by the upper winds; then it sinks in the eastern tropical Pacific, where it heads back to the west as the trade winds. That circuit is called a Walker cell. The trade winds continuously push cool water from the east to the west, sunlight warms the water as it travels west, and when that warm water reaches the west Pacific Warm Pool, it supplies the heat necessary to maintain the updraft, which, in turn, causes to trade winds to blow. The briefest way to explain it: the trade winds and the sea surface temperatures are coupled, meaning they interact with one another.
With all of that warm water being piled up in the western tropical Pacific, and with all of the cool water being drawn from the eastern equatorial Pacific, the surface of the water—the sea level—in the west Pacific Warm Pool is about 0.5 meters (approximately 1.5 feet) higher in elevation than it is in Cold Tongue Region in the east.
Everything’s in tune, running in its normal state. The temperature difference between the east and west keeps the trade winds blowing—and—the trade winds maintain the temperature difference between east and west—and—the trade winds keep the warm water in the west Pacific Warm Pool at a higher elevation than it is in the eastern equatorial Pacific.
We can’t forget about gravity. It’s always there, our constant companion. Gravity would like the sea surface height in the west to equal the height in the east. It likes level playing fields. It’s working against the trade winds, and the trade winds are piling up the warm water against gravity. Still, everything is in relatively constant state of balance, with little gives and takes here and there.
Then some weather event—and that’s precisely what it is, a weather event or group of weather events—causes the trade winds to relax. That means the coupled ocean-atmosphere processes taking place in the tropical Pacific are no longer in balance. Sometimes, the weakened trade winds aren’t strong enough to hold the warm water in place in the west Pacific Warm Pool against gravity, so gravity takes over and all of that lovely warm water that was piled in the west Pacific Warm Pool suddenly sloshes to the east. That’s how an El Niño starts.
I’m now going discuss parts of the process that haven’t been shown in the illustrations yet.
The Pacific Ocean is awfully wide at the equator, so it takes a while, about 2 months, for the warm water to slosh to the east as far as the coast of South America.
Let’s put things into perspective. The west Pacific Warm Pool holds a massive amount of warm water. It varies in size. When it’s large, the west Pacific Warm Pool can cover a surface area of about 19 million square kilometers (7.3 million square miles) but it averages about 12 million square kilometers (4.6 million square miles). Numbers that large are hard to embrace, so, when the west Pacific Warm Pool is larger than normal, think of an area the size of Russia or a little less than twice the size of the United States. Refer to the Mehta and Mehta (2004) presentation Natural decadal-multidecadal variability of the Indo-Pacific Warm Pool and its impacts on global climate. Also imagine the warm water reaches depths of 300 meters (about 1000 feet). Sometimes, during a very strong El Niño, most of that water from the west Pacific Warm Pool will be transported east and much of it will spread across the surface of the central and eastern tropical Pacific. Now remember that the Pacific stretches almost halfway around the globe at the equator. An El Niño dwarfs all other weather-related events. How big are they? Sometimes it takes a pair of tropical cyclones just to trigger an El Niño. Yes, tropical cyclones as in hurricanes.
Let’s return to the ENSO-neutral phase for a second. A weather event—for example, a couple of tropical cyclones or a pair of them that straddle the equator—a weather event that’s teeny by comparison, has caused the Pacific trade winds to relax, which in turn has unleashed a monstrously large phenomenon that is capable of raising global temperatures 0.4 degrees C in less than a year. In turn, there are heat waves and cold spells. Floods will strike some parts of the globe. Drought conditions form in others. Snowfall will pile to record heights in some areas, and in others it will decrease. These effects were studied and documented decades ago, and they’re still being studied, for example, to account for differences between Central Pacific and the more powerful East Pacific El Niño events.
Of course, some publicity seeking climate scientists continue to (very unwisely) blame carbon dioxide for the heat waves and cold spells, flooding and drought, blizzards and low snowfall, creating further disbelief in climate science. They have only themselves to blame for their loss of credibility. I digress.
An El Niño is one of Mother Nature’s ways of reminding us who’s in charge.
Back to the cartoon-like illustrations.
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1.3 Recap of Section 1
Trade winds cause the sea surface temperature and height in the western tropical Pacific to be greater than they are in the east. El Niño events are started by the weakening of the trade winds. The weaker trade winds can no longer hold the warm water in place in the west Pacific Warm Pool, and this allows gravity to carry the warm water east, raising sea surface temperatures in the central and eastern equatorial Pacific.
El Niño events are the abnormal phase of ENSO. The Equatorial Countercurrent strengthens and carries a large volume of warm water from west to east, and that increased volume from west to east opposes the normal east-to-west flow during ENSO-neutral and La Niña phases. The winds also change directions during an El Niño, with trade winds becoming westerlies in the western tropical Pacific. On the other hand, during ENSO-neutral and La Niña phases, the trade winds are blowing in their normal east-to-west direction.
La Niña events are easy to describe. They are exaggerations on the ENSO neutral phase. However, La Niña events play the important role of replenishing the heat given off by the El Niño that precedes it, and sometimes a La Niña can create more warm water than was released by the El Niño.
Warm water that has traveled east during the El Niño and that is not “exhausted” by the El Niño does not remain in the eastern tropical Pacific. It is returned to the West Pacific and Indian Oceans, where much of it remains on the surface. Before the El Niño, most of that warm water is below the surface of the west Pacific Warm Pool and excluded from the surface temperature record. Then, after the El Niño, part of what remains of that warm water is now on the surface of the West Pacific and East Indian Oceans. The opposite does not occur during the La Niña phase. The result: strong El Niño events can raise global sea surface temperatures for extended periods of time. This will be discussed in detail in Section 5.
[END OF SECTION 1 OF WHO TURNED ON THE HEAT?]
Again, if you have any questions, please ask.
Now that you’ve run through the processes, here’s a one sentence description of ENSO: ENSO acts as a chaotic, naturally occurring, sunlight-fueled, recharge-discharge oscillator, where the La Niña phase acts as the recharge phase and El Niño acts as the discharge phase.
As long as the climate science community continues to treat ENSO as noise, they will make little progress in understanding the natural contribution to global warming, and it’s a sizeable contribution. We’ve discussed for years that the climate science community has failed to account for the “leftovers”, the residual warm water, from strong El Niños.
I also used those cartoon-like illustrations in my two-part video series “The Natural Warming of the Global Oceans”, which first aired on the WUWT-TV special in September 2012. That series is available on YouTube. Part 1 is here, and Part 2 is here.
I went into much more detail to explain ENSO processes and the aftereffects of El Niño and La Niña events in my ebook Who Turned on the Heat? I’ve lowered the price of Who Turned on the Heat? from U.S.$8.00 to U.S.$5.00…for a month or so, with hope of increasing sales a little bit. 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 this post), 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. Unless I can find funding for my research, it will be book sales and tips/donations that allow me to return to blogging full-time.
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Bob Tisdale,
“Maybe it’s easier to think of ENSO as an additional ‘source’ of heat when it comes to surface temperatures.”
I got that. I understand how El Nino increases the surface air and sea surface temp averages. But your comment was that ENSO is a “natural contribution to global warming, and it’s a sizeable contribution.”
Are you using the term “global warming” to mean merely the sruface temperature records? Or are you referring to global warming in the sense of an increase in total heat/energy in the global climate system as a whole? If the latter, I still don;t see the mechanism by which ENSO adds heat to the system as a whole And if t doesn’t, then isn’t the “increase in global warming” in fact spurious, merely a product of heat in the system that had not been measured (included in the “global average”), now entering an area of the climate system where it is measured?
Gary @ur momisugly 4:59
Clear sky between the Tropics allow solar rays to penetrate the top layer of the ocean and for the energy to be absorbed in that water. That warms the water. This is natural warming added to the Earth system. Over time that energy will be removed from the water and flow back to space. The system can warm and cool. I read Bob’s material as explaining how the tropical Pacific gets and releases this warmth and redistributes it to other geographic areas.
Over the last few years, in comments, it is apparent that some people would like him to do more – build a model, make a prediction, and so on. He doesn’t do that.
I thank him for what he does do.
GaryM says: “Are you using the term “global warming” to mean merely the sruface temperature records? Or are you referring to global warming in the sense of an increase in total heat/energy in the global climate system as a whole?”
Both, but there are also other natural factors that contribute to the warming of the oceans to depth.
One of my more detailed explanations of the natural warming of ocean heat content can be found in the post “Open Letter to the Royal Meteorological Society Regarding Dr. Trenberth’s Article ‘Has Global Warming Stalled?’”
http://bobtisdale.wordpress.com/2013/06/04/open-letter-to-the-royal-meteorological-society-regarding-dr-trenberths-article-has-global-warming-stalled/
The discussion starts about half-way through the post, under the heading of THE IMPACTS OF EL NIÑO AND LA NIÑA ON OCEAN HEAT CONTENT.
Also see the discussion of Lozier et al. (2008) “The Spatial Pattern and Mechanisms of Heat-Content Change in the North Atlantic” in the post “Is Ocean Heat Content Data All It’s Stacked Up to Be?” It starts after Figure 13.
http://bobtisdale.wordpress.com/2013/03/11/is-ocean-heat-content-data-all-its-stacked-up-to-be/
Regards
Bob:
Especially in introductory presentations, it’s essential to identify unequivocally the primary mechanisms involved in observed phenomena, without getting lost in the weeds of adjunct mechanisms and phenomena It’s no misreading on my part that your presentation fails to do that.
In your Fig. 1-12, you state that gravity takes over and in 1.13 that warm water sloshes east as sea-level flattens. I’ve pointed out that the illustrated eastward spreading of warm water across much of the Pacific cannot be the result of such seiching. And in Fig. 1-19 you speak of subsurface waters “returned west via Rossby waves,” as if they produced mass transport on the requisite scale. In both cases, you appeal to adjunct mechanisms that cannot produce the observed ENSO effects. Along with arrows that mistakenly indicate the deep ocean–rather than continental shelves–as the source of cool upwelling water, this detracts from the physical realism of your presentation.
John F. Hultquist says: “Clear sky between the Tropics allow solar rays to penetrate the top layer of the ocean and for the energy to be absorbed in that water. That warms the water. This is natural warming added to the Earth system.”
Clear skies over the Pacific describes “neutral” and La Nina conditions according to the post. But reported surface temps (described as “global average temperature”) go up during El Ninos, and down during La Ninas, for the reason set forth in the article.
Bob Tisdale says: “One of my more detailed explanations of the natural warming of ocean heat content can be found in the post ‘Open Letter to the Royal Meteorological Society Regarding Dr. Trenberth’s Article “Has Global Warming Stalled?”’”
My questions are not as to ocean heat content. I think I understand that well enough. Fewer clouds during neutral and La Nina conditions allow more sunlight, and thus heat, to enter the Pacific. During El Ninos, this additional heat is then released, with clouds increasing,, ocean heat content decreasing, and less sunlight heating the ocean due to additional clouds.
What I do not see in the above article, or the article you just linked to, is an explanation for the mechanism by which ENSO as a whole “contributes to global warming”, in the sense of an increase in net global heat/energy content.
The warmists claim that additional clouds during El Ninos retain more heat, and therefore the increase in global average temperature reflects an increase in the total heat/energy content of the global climate system. as a whole.
You view is diametrically opposed, so I don’t see how you can think the rise in temps that coincide with El Ninos, is anything other than spurious.
But I appreciate your answers, and will just live with my confusion.
Sky: Two quotes from the UCSD webpage “Pacific equatorial circulation and ENSO (interannual Variability)”:
http://www-pord.ucsd.edu/~ltalley/sio210/Equatorial_circulation/
“At the equator, the easterly trade winds push the surface water directly (frictionally) from east to west. This water piles up gently in the western Pacific (0.5 meters higher there than in the eastern Pacific).”
“When the trade winds weaken or even reverse, the flow of water westward at the equator weakens or reverses and upwelling weakens or stops. Surface waters in the eastern Pacific warm significantly since upwelling is no longer bringing the cool waters to the surface. The deep warm pool in the western Pacific thins as its water sloshes eastward along the equator in the absence of the trade winds which maintain it.”
GaryM says: “The warmists claim that additional clouds during El Ninos retain more heat, and therefore the increase in global average temperature reflects an increase in the total heat/energy content of the global climate system. as a whole.”
And you believe warmists? Refer to Trenberth et al. (2002) for the causes of the warming in response to El Niño events:
http://www.cgd.ucar.edu/cas/papers/2000JD000298.pdf
And while you’re reviewing Trenberth et al, see the following quote:
“The negative feedback between SST and surface fluxes can be interpreted as showing the importance of the discharge of heat during El Niño events and of the recharge of heat during La Niña events. Relatively clear skies in the central and eastern tropical Pacific allow solar radiation to enter the ocean, apparently offsetting the below normal SSTs, but the heat is carried away by Ekman drift, ocean currents, and adjustments through ocean Rossby and Kelvin waves, and the heat is stored in the western Pacific tropics. This is not simply a rearrangement of the ocean heat, but also a restoration of heat in the ocean.”
And for a discussion of the processes that cause the tropical North Atlantic to warm during El Niños, see Wang (2005):
http://www.aoml.noaa.gov/phod/docs/Wang_Hadley_Camera.pdf
Regards
Bob:
Your cited quotes from an introductory course in physical oceanography hardly address the dynamical issues that I raise here. The ill-chosen word “sloshes”–which summons ideas of the fundamental “sloshing” mode of seiching–is later changed to “drains” on the same link, indicating that pressure-gradient forces, rather than gravity alone, are involved in spreading warm waters eastward during the inception of El Nino. Your link clearly identifies the agents of such draining as the strengthened Northern ECC along with the Cromwell current–not the quarter-cycle of the “sloshing” mode as your Fig. 1-12 and 1.13 strongly suggests.
I would like to see you avoid propagating misconceptions about ocean dynamics. While not quite as egregious as the misattribution of anticyclonic oceanic circulation to always-cyclonic planetary vorticity enshrined in WUWT’s reference pages, your attribution of significant westward transport by Rossby waves during the re-establishment of La Nina should be stricken from your otherwise admirable layman’s introduction to ENSO.
Bob, I always enjoy your work. Do you have any thoughts about why the ENSO models have been stubbornly wanting to predict El Nino development for many months now, despite reality not cooperating? The ENSO-meter is actually showing the index having dropped all the way to -0.5.
Bravo, Bob!