1ST Quarter 2011 Sea Level Anomaly Update And An Initial Look At The Impacts Of ENSO On Global Sea Level
Guest post by Bob Tisdale
It’s been more than two years since my last Sea Level anomaly update using the data from the University of Colorado Sea Level Research Group . I visit their website regularly, but each update seems to be an extension of the monotonous 3.22 mm per year linear trend with another wiggle or correction that keeps it at or near that trend. That aside, since it has been two years and since there have been significant El Niño and La Niña events since then, I felt it would be good to update the Sea Level anomaly graphs at my blog.
There’s another topic that prompted this post: The University of Colorado’s recently updated webpage included a discussion of how sea levels should start to rise again in response to the ebbing of La Niña conditions in the tropic Pacific, 2011_rel2: GMSL and Multivariate ENSO IndexBut the graph they included did not appear to go along with the description, so I’ve also discussed detrended sea level and the Multivariate ENSO Index (MEI) in this post.
Let’s get the Sea Level update portion out of the way first.
SEA LEVEL UPDATE – MONTHLY DATA
Figure 1 illustrates the global Sea Level anomalies on a monthly basis, from January 1993 to March 2011. I started with the Global Sea Level (2001 rel2) with the seasonal signal included. The data also includes Inverse Barometer and Glacial Isostatic Adjustments. I converted it to monthly data, then determined anomalies from the monthly averages of the base period, which was the entire term of the data, 1993 to 2010. And as discussed earlier and illustrated in Figure 1, the global sea level anomaly data seems simply to follow the linear trend with some minor multiyear divergences.
Figure 1
I followed the same routine for the Atlantic, Indian, and PacificOcean data, Figures 2, 3, and 4, respectively. The Atlantic data appeared to have flattened from 2005 through 2008, but it swung back up in 2009. The Indian Ocean data is noisy, being impacted by ENSO and the phenomenon known as the Indian Ocean dipole, and it seems to be continuing its rise without any multiyear decreases in trend. The Pacific Ocean Sea Level data, however, appears to have flattened since 2006, though it does make a rise and fall in response to the 2009/10 El Niño and the 2010/11 La Niña. How long will it continue to rise at the reduced rate?
Figure 2
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Figure 3
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Figure 4
And, for those interested, Figure 5 is a spaghetti graph that compares the Global Sea Level anomalies and the data for the three major basins. All have been smoothed with 12-month running-average filters to reduce the noise.
Figure 5
SEA LEVEL UPDATE – ANNUAL DATA
Some readers prefer annual data. I’ve presented the Global, Atlantic Ocean, Indian Ocean, and Pacific Ocean data on an annual basis in Figures 6 though 9.
Figure 6
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Figure 7
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Figure 8
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Figure 9
NOTE ABOUT KNMI CLIMATE EXPLORER
KNMI has added the University of Colorado Global Sea Level anomaly data to its Climate Explorer on the Monthly climate indices webpage. They also have the ocean basin and sea subsets that are presently available through the University of Colorado’s Regional Sea Levelwebpage. The updating at the Climate Explorer can occasionally lag the University of Colorado, so the data at KNMI as of this writing is still 2011_rel1. But there is a wonderful benefit to using the KNMI Explorer for that sea level data: KNMI presents it on a monthly basis.
DETRENDED GLOBAL MEAN SEA LEVEL VERSUS ENSO INDEX
Before we begin, I want to clarify two things. I am not questioning the University of Colorado’s prediction that Sea Levels will rise again shortly in response to the ebbing La Niña event in the following discussion. And I am also not implying that my findings show an error with the Sea Level data. This discussion presents a multiyear divergence between an ENSO index and the detrended Global Sea Level anomalies that I find interesting.
The University of Colorado Sea Level Research Group has recently added a discussion of the impact of ENSO on Sea Level. Refer to their 2011_rel2: GMSL and Multivariate ENSO Index webpage. To explain the recent decline in Sea Level, they provide the following illustration, Figure 10, and discussion:
The Multivariate ENSO Index (MEI) is the unrotated, first principal component of six observables measured over the tropical Pacific (see NOAA ESRL MEI, Wolter & Timlin, 1993,1998). To compare the global mean sea level to the MEI time series, we removed the mean, linear trend, and seasonal signals from the 60-day smoothed global mean sea level estimates and normalized each time series by its standard deviation. The normalized values plotted above show a strong correlation between the global mean sea level and the MEI, with the global mean sea level often lagging changes in the MEI. Since the MEI has recently sharply increased (coming out of a strong La Niña), we expect the global mean sea level estimates to also reverse their recent downward trend and begin to increase as the La Niña effects wane.
Figure 10
Detrended Global Sea Level Anomalies in Figure 10 mimic the MEI data, but I don’t know that I’d call it a strong correlation. In fact, the correlation coefficient for those two datasets is only 0.44. So let’s detrend the monthly Global Sea Level anomalies, standardize the data, and compare them to the MEI data, Figure 11. (Note that the MEI is a standardized dataset, but the University of Colorado standardized it again for their graph, so I did too.) My Figure 11 is a reasonable reproduction of the University of Colorado graph, Figure 10. They presented 6-week averages of the sea level data, and I’ve presented it on a monthly basis.
Figure 11
Now let’s smooth both datasets with a 12-month running average filter, Figure 12. The detrended and standardized Global Sea Level anomalies definitely do not always follow the ENSO index. And it doesn’t appear that any other method of scaling the two datasets will provide better results, but let’s try two more.
Figure 12
For Figure 13, I did not standardize the detrended Global Sea Level anomalies, but I scaled the MEI data based on a linear regression analysis. That doesn’t help. All that seems to do is emphasize the differences between the two datasets, especially the two Bactrian camel-like humps in the detrended Sea Level data compared to the three moderate El Niño events between 2002 and 2007.
Figure 13
Last, for Figure 14, let’s assume that the “Super” 1997/98 El Niño was the only ENSO event during the period that was strong enough to overcome the year-to-year noise in the Sea Level data, and that the evolution phase of that El Niño event should be “cleanest” since the decay phase in the sea level data includes the aftereffects of the El Niño. Then we can scale the MEI data and shift it down so that the leading edges of the two datasets align during the evolution of the 1997/98 El Niño. Now, note how the Detrended Global Sea Level anomalies diverge from the MEI data during the decay phase of the 1997/98 El Niño. Then they rise, remaining well above the ENSO index data through 2005, when they start to drop until they realign again during the decay phase of the 2009/10 El Niño. Interesting, isn’t it? It’s something that needs to be investigated further.
Figure 14
Detrending the Atlantic and Indian Ocean datasets and comparing them to the MEI data that has been scaled to the response to the 1997/98 El Niño does not seem to shed any light. Refer to Figure 15 for the Atlantic Ocean data and Figure 16 for the Indian Ocean data. But the detrended Pacific Ocean data, Figure 17, has a response that’s similar to Global data, so it might hold the key.
Figure 15
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Figure 16
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Figure 17
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A NOTE ABOUT THE ENSO INDEX
Someone is bound to ask why the detrended Pacific sea level data precedes the MEI data. Let’s replace the MEI data with scaled NINO3.4 Sea Level (not Sea Surface Temperature) Anomalies, Figure 18. The detrended Pacific Sea Level anomalies do not lead the NINO3.4 Sea Level Anomalies. Keep in mind that I used the MEI data because the University of Colorado used it, not because it was the right ENSO index to use with Sea Level data.
Figure 18
As illustrated in Figure 19, the NINO3.4 region Sea Level anomalies precede the NINO3.4 SST anomalies and the Multivariate ENSO Index data. And they should. The NINO3.4 Sea Level data captures the Kelvin waves and the subsurface temperature anomalies traveling from west to east across the equatorial Pacific, which lead the response of the NINO3.4 Sea Surface Temperatures and many of the additional variables used in the Multivariate ENSO Index.
Figure 19
CLOSING
The answer to what causes the multiyear divergence of the detrended global sea level anomalies from the ENSO index might rest in the process of ENSO and the significant redistribution of warm waters from the tropical Pacific following the 1997/98 El Niño event. Then again, mass from glacial runoff is also a major contributor to Sea Level. Did it temporarily increase for a few years after the 1997/98 El Niño? For now, I’ll treat the decade-long divergence as a curiosity, but I’ll keep looking for an explanation.
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Bob – thanks again for the excellent data analysis.
My comment is it looks like there might be a solar cycle signal in the data – for example in Fig 17. The problem is you’d have to have about 3 solar cycles worth of data in each of the 3 datasets before you had any chance at a multiple regression. Probably more. But is interesting that the biggest El Nino’s occurred at the solar minima and the biggest departure betweem MEI and GSL corresponding to the solar maximum. I don’t know why the Indian Ocean should be left out of this however.
Thanks Bob and Anthony.
Don K and jrwakefield,
Interesting comments. One can’t but be sceptical of a satellite’s ability to measure a pear-shaped-geoid-with-flat-spots. As Bob Carter says, it’s at the limit of human knowledge, or words to that effect.
As someone who has lived by the sea for over seven decades, I have had a very reliable benchmark on the east coast of Australia for the last five decades and on average, the highest astronomical tides of today are between 8 and 12 inches [20 and 30 cms] lower than they were forty eight years ago.
This is naturally not the most accurate of measurements but it shows to me that there is no observable sea level rise.
@R. Gates
“Let’s see what AR4 has to say”
So, essentially, you reference a IPCC report that is now 4 years old. A report that references even older scientific research, pseudoscientific research and opinion propaganda called grey literature. And you do it, I envision with a straight face, today? Although IPCC don’t deal with science but a few models of a bunch of more models that, according to IPCC, doesn’t include all the potential vital variables. And although you do know, because I’ve read as much, that you know that scientific process is an ongoing process, as in old research getting trumped by new.
Question is though, why do you still destroy our climate?
Thanks Bob,
The .1 mm/yr rate increase apparently happened between 2011-06-20 and 2011-07-29.
jrwakefield: Thanks for the link to the PSMSL webpage. I looked around their website but for some reason I could only find the daily data and I did not want to deal with that. The Sydney Fort Denison2 data gives some interesting trend results for the long-term and satellite-era:
http://i52.tinypic.com/91mgls.jpg
Or if we smooth the data with an 11-year filter:
http://i51.tinypic.com/f0yvqp.jpg
I doubt the rest of the stations would give similar results, but that was an interesting way to start.
“philincalifornia says:
August 18, 2011 at 4:25 pm
Bob, why factor in the glacial isostatic adjustment ?? Most people out in the real world want to know by how much sea level is actually rising relative to the land they live on. Just the facts – no contrived bells and whistles.”
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There are two components to GIA, one controversial, the other uncontroversial, but maybe not entirely correct. The uncontroversial one is that the weight of the glaciers depressed the land underneath them. When the glaciers retreated, the land bounced back. Some of it in the northernmost latitudes is still rebounding/bouncing. So, if you are measuring sea level at Churchill, Manitoba and actual planetary sea level didn’t change at all for a century your tidal gauge at Churchill might tell you that sea level has dropped 80cm or so (I didn’t look up the GIA but I know it is very high). I don’t think anyone has any problem with correcting that out, although I have some doubts that the GIA corrections being made are all that accurate. It’s apparently not easy to compute GIA.
The controversial component is much smaller. It comes about because the melted waters from the glacial icesheets have found their way into the oceans and their weight is purportedly depressing the ocean bottoms. CU claims to be correcting the sea level rise for this although I’m not sure that the correction is present in all their data. The correction 0.03mm/year isn’t large. I’m not a fan of this correction being made to sea level values. because it seems to reflect a sort of “phantom sea level change” that won’t show up on tidal gauges or satellite altimetry. The problem I perceive is that when using sea level marks from biblical times and before, this second GIA component is going to show up as offsets of a meter or more between analysts who apply the “correction” and those who don’t. It would be better I should think not to include this component in sea level measurements and to incorporate it as a correction to sea volume values in analyses where it is appropriate.
“As someone who has lived by the sea for over seven decades, I have had a very reliable benchmark on the east coast of Australia for the last five decades and on average, the highest astronomical tides of today are between 8 and 12 inches [20 and 30 cms] lower than they were forty eight years ago.”
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The problem is that neither the ocean or the land will stand still. Measuring sea level is a bit like trying to measure the heights of a grade school class full of active four year olds. You need to take a lot of measurements in a lot of places then average them. For example, Churchill, Manitoba is rising because it is rebounding from the removal of a very thick ice sheet. New Orleans on the other hand is sinking because the sediments it is built on are compacting (pumping of ground water could also be an issue there). Tide gauges in either of those places will not give you an especially good idea of what it going on in the rest of the planet. The PSMSL and Colorado University web sites have reasonable overviews of what is involved http://www.psmsl.org/ http://sealevel.colorado.edu
You may well be living in an area of local uplift. Other folks aren’t. It appears that on average the oceans are rising between 17 and 33 cm a century with a lot of local variations. And no, we don’t know why the numbers from satellites and tidal gauges are so different. I think everyone would be a lot happier if we did.
Thanks as usual, Bob. I always appreciate the work you do. Sea level is also impacted by production of groundwater from no or slow to recharge aquifers, so called fossil water that has been in the ground for perhaps millions of years. This fossil water is about evenly divided between agriculture irrigation and make up water to evaporative cooling towers, primarily in steam power generation plants. The big players in fossil water production are India, China and USA.
Water levels in the producing wells have started dropping which decreases the water production until larger pumps are installed and the pumps dropped lower in the well. The lower water production has been dropping for the past few years, especially in USA and China. At peak, the fossil water production, adjusted for some recharge, increased the sea level by 2.6 mm/year.
JFD
spangled drongo says:
August 18, 2011 at 6:00 pm
Don K and jrwakefield,
Interesting comments. One can’t but be sceptical of a satellite’s ability to measure a pear-shaped-geoid-with-flat-spots. As Bob Carter says, it’s at the limit of human knowledge, or words to that effect.
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You darn well should be skeptical. However, it’s not prima facia impossible for the satellites to achieve sub mm accuracy in sea level measurements. The satellites do have a pretty good idea where they are and how they are oriented. They average many hundreds of thousands of data points a day. And wherever possible, they use differences between values, not absolute measurements. In short, they use every trick in the book to try to get meaningful sea level data that can be compared over time intervals. They question is whether they are making significant errors that do not average out and that add up over time. We just don’t seem to know for sure.
The satellite measurements of sea level trend have error bars large enough to justify corrections of +/- 5mm/yr. The overlapping satellite trends from competing groups strongly disagree over the last 5 or 6 years. One gives around 3 mm/yr, while the other is closer to 0.7 mm/yr. One obvious ‘correction’ is to adjust the satellite trends to be close to the tidal gauge trend. But then you need to choose your reference tidal gauge(s) wisely.
Nils Axel Morner has some things to say about the satellite sea level data.
http://www.telegraph.co.uk/comment/columnists/christopherbooker/5067351/Rise-of-sea-levels-is-the-greatest-lie-ever-told.html
“One of his most shocking discoveries was why the IPCC has been able to show sea levels rising by 2.3mm a year. Until 2003, even its own satellite-based evidence showed no upward trend. But suddenly the graph tilted upwards because the IPCC’s favoured experts had drawn on the finding of a single tide-gauge in Hong Kong harbour showing a 2.3mm rise. The entire global sea-level projection was then adjusted upwards by a “corrective factor” of 2.3mm, because, as the IPCC scientists admitted, they “needed to show a trend”. “
The satellites probably measure very well. But the global ocean height is a calculation that has to take into account not just the noise of waves but of tidal influences that vary daily, weekly, monthly and longer, I’m sure. Then there is the temperature expansion component, as has been noted, which can be almost nothing to, in the case of the Pacific, a lot. Not to mention the non-spherical orbits of satellites that decay with time, and which earlier required unexpected corrections.
An error analysis of the satellite data would be very interesting, I mean, the limits of certainty in each portion of the analysis and how the final result can have a certainty as described. The problem of certainty is in the adjustments to individual datapoints, not in the datapoints themselves. Intuitively I cannot see that there is equal accuracy and precision in the accuracy of the level proposed.
Also, the Indian Ocean has warmed the most of all the oceans. Has the expansion in one ocean added an undiscussed, significant portion to the rise of the global oceans?
If the 1998 divergence between sea level and ENSO was due to glacial melt, then the 2009 reconvergence must be un-melt. Tallbloke’s anecdotal reported research from Greenland may confirm this.
Colodaro now predict increased sea level linked to an ending La Nina – but it looks like we’re heading back down into La Nina again. So they might be disappointed.
Sea level is indicative of OHC so this recent decline particularly in the Pacific is important. What does it portend?
R.Gates: I’m trying to figure out why you troll in here. It must be majorly irritating for you.
Andres Valencia says:
August 18, 2011 at 4:04 pm
“One thing I noticed as I updated the Sea Level Research Group, University of Colorado, graph of 2011-07-29 in my page at http://www.oarval.org/ClimateChange.htm is that they have increased the rate from 3.1 to 3.2 ± 0.4 mm/yr.
I can see no reason for that, given the latest lack of ocean level rising.”
The answer is that due to recent sea level behavior the actual rate of rise had had declined to 2.8 mm per year using the averaging algorithm they’d employed for years. So they added a 0.3mm per year fudge factor to account for settling ocean basins, thereby changing “sea level” to “sea volume” (without relabeling their graph) which brought the rate of rise up to 3.1mm per year. Then they introduced a “new and improved” averaging algorithm to bring the average all the way back up to 3.2mm per year. The whole episode reeked of “tortured logic” employed to reach a per-conceived answer.
Although I always do appreciate Bob’s meticulous write-ups, my eyes are now sufficiently glazed over by this one to assure an uncharacteristically swift decent into sleep at this late hour. Goodnight!
If you read this ten year old article by John Daly you will understand all the big problems in using radar technology to measure sea level.
In fact the problems are so great that the measurements must be corrected by calibrating them with reference to a selection of tide gauges. This of course means that the actual measurement is done by the tide gauges, not by the radar altimeter which only measures short-time fluctuations.
Am I correct?
See the article by John L. Daly:
TOPEX-Poseidon Radar Altimetry:
Averaging the Averages
http://www.john-daly.com/altimetry/topex.htm
Ágúst
rbateman says
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Nature does not do straight lines,
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Opooop! rbateman has just declared Newton and a whole bunch of other crazy guys to be fools. Apparently light does not travel in straight lines, objects do not naturally travel in straight lines and a whole bunch of other stuff.
Don K says: August 18, 2011 at 8:00 pm
“..question is whether they are making significant errors that do not average out and that add up over time. We just don’t seem to know for sure.”
The satellites can at least be “ground truthed” to all the locations on the planet where we have tide gauges which we know are very accurate with respect to the local sea level. It doesn’t matter too much about individual tide gauge sites moving up or down tectonically for example as the sheer number of physical sites we have will show whether the satellites agree with the local physical measurements consistently.
I would have thought just taking the average of all the tide gauges is going to accurately measure the “global average sea level” anyway. On top of that sea level only matters locally to land masses anyway so is the more important measument anyway.
Satellite orbit = 20,000,000 km. 2 mm = !0 ^-8%. (if my maths is correct)
Accuracy of measuring method = sorry I don’t know but probably quite high in comparison.
Satellite orbit should have been metres not km!
“Doug Proctor says:
August 18, 2011 at 8:57 pm
The satellites probably measure very well. But the global ocean height is a calculation that has to take into account not just the noise of waves but of tidal influences that vary daily, weekly, monthly and longer …”
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Yep, and it’s much worse than that of course. For example, they need to know the satellite orientation because the radar antenna isn’t at the altitude of the satellite’s center of mass and also because if the satellite is tilted the altimeter may be measuring the distance to something further away than the nearest point on the Earth. And floating ice or even heavy rain can introduce biases in the readings for areas where they are present. As far as I can see, honest attempts — many of them quite clever — are made to deal with the many problems
I haven’t come across an error budget for satellites, but the JSON2 Handbook http://www.osdpd.noaa.gov/ml/ocean/J2_handbook_v1-4_no_rev.pdf contains a wealth of information on the design of that particular satellite.
My bottom line: There are things to like about satellites for measuring sea level. Much more even coverage than tidal gauges for example. And they don’t really seem to need GIA adjustments — which doesn’t stop the nice folks at CU from making GIA adjustments anyway. But a reasonable person probably should be somewhat skeptical about their accuracy
Maybe the tide guages are right, or maybe the satellites are.
But if the tide guages are wrong, then they have been consistently wrong for a century or more in which case there is no evidence that sea level rise is accelerating.
That systematic difference between guages and sats has to go bust sometime; the discrepancy is cumulative. Surely one or t’other has to suddenly be discovered to be way off?
Stein’s Law: If something cannot go on forever, it will stop.
typo: gauges. ;p
Don K says:
August 18, 2011 at 7:44 pm
You may well be living in an area of local uplift. Other folks aren’t. It appears that on average the oceans are rising between 17 and 33 cm a century with a lot of local variations.
Here’s a daft idea. We pick a few spots that have no isostatic rebound and no sinking issues and use those to determine actual sea level rises. Can these be identified? I don’t know why the likes of New Orleans and Japan would even be included in the measurements?
Note on my last post: A “Per-conceived answer” is a lot like “preconceived answer”, only more dastardly..
CH