Guest Post by Willis Eschenbach
In a post here on WUWT, Nils-Axel Morner has discussed the sea level in Kwajalein, an atoll in the Marshall Islands. Sea levels in Kwajalein have been rising at an increased rate over the last 20 years. Nils-Axel pointed to a nearby Majuro tidal record extending to 2010, noting that there’s been no acceleration there. A furor seems to have erupted in the warmosphere over his comments, with folks like Tamino pointing out that we have tidal data for Majuro up until 2013, not just 2010 as Nils-Axel highlighted, and those final three years show higher rates of sea-level rise, so indeed there is acceleration there …
Bemused by the excess of heat over light, and dismayed by the battle over twenty-year sea-level trends, as a long time sailor and commercial fisherman with more than a bit of knowledge about tides, let me say that they’re all wrong, warmists and skeptics alike. Here’s the critical graph for any discussion of sea-level rise and fall:
Figure 1. Confidence intervals for the estimation of sea-level rise using tidal gauge data. This means that 95% of the results fall between the two extremes. For twenty year trends, these are from a sea-level rise of three mm/year to a sea-level fall of three mm per year. See endnotes for the corresponding equation. SOURCE: Pacific Country Report, Sea Level & Climate: Their Present State Marshall Islands December 2010
The interpretation of Figure 1 is as follows. Let’s consider twenty-year trends in sea level rise. The uncertainty is 2.8 mm per year … which is about equal to the global average sea-level rise itself.
Now, twenty-year trends are convenient because trends of that length are under discussion by Morner and the rest. It’s also convenient because we have twenty years of satellite records, as well as twenty years of SEAFRAME records in Majuro. The uncertainty in Figure 1 says that IF there were absolutely no change in global sea levels over time, about one tide gauge out of every six would show the sea levels as rising between 1.5 and just under 3 mm per year over twenty years. Another one in six tide gauges would solemnly assure us that the sea level is falling between 1.5 and 3 mm per year over the same twenty years.
SO … if you see a couple of twenty-year trends from two tide gauges that differ by say four mm per year, that is an EXPECTED RESULT of the short length of the data. Let me explain why the uncertainty is so large, and then we’ll look at the Marshall Islands sea level data. The problem is the tides. The ocean tides are a driven resonant system. By “resonant” I mean that ocean water “sloshes” back and forth in the ocean basins, just like the water in a wide basin after you set it down. Each ocean basin has natural resonant periods. The driving forces are the gravity of the sun and the moon. They vary in a hugely complex cyclical motion, which sort of repeats only after over fifty years. The basins have long- and short-period “standing waves” on the surface, or rather waves circulating around a wandering “amphidromic point” where there is no tide. There is no known way to predict what the combination of driving force, natural sloshing, and standing waves will look like at any given point for a given ocean basin. As a result, you have to wait for at least 50 years to get an accurate reading of the rate of sea-level rise. With shorter records, the uncertainty rises rapidly, and with 20-year records, the 95% CI is ± 3 mm per year.
With that as a preface, let’s take a closer look at the sea level rise in the area. First, where are these mysterious “Marshall Islands”, and how many tide gauges in the Marshall Islands have records up to the present?
Figure 2 shows the location of the three tide gauge records in the Marshall Islands that extend up to the present. They are at Wake Island, Kwajalein, and Majuro. The Majuro tide gauge is part of the “SEAFRAME” sea-level measurement project.
Figure 2. Location of Majuro (the capital), Kwajalein, and Wake Island in the Marshall Islands. Australia is at the lower left. Papua New Guinea is the large turkey-shaped island at center-left. The islands in the chain to the right of Papua New Guinea are the Solomon Islands
Now, what do we know about the sea levels at those points? Here are the three records. I’ve spliced together the recent and the previous record at Majuro (Majuro B and Majuro C), as they are nearly identical in their overlap periods. Here are the three records.
Figure 3. All available tidal records which extend to the present, Marshall Islands. Heavy lines show 6-year centered Gaussian averages of the data.
You can see the post-2010 uptick at the end of the Majuro record (red) that Tamino referred to. Now, the whole hoorah has been about the trend of the last 20 years in Kwajalein. The records for Kwajalein and Majuro differ by about 4 mm per year … remember what I said about 4 mm per year above? Not meaningful.
Now, we do have one other source of information about the sea level rise in the Marshall Islands. This is the satellite record. At the time of writing, you could find the satellite sea-level record for any spot on the ocean at the University of Colorado “Interactive Sea Level Time Series Wizard” (it currently says “Under Revision”). Figure 4 shows those results. I’ve left out the annual results this time, and just shown the Gaussian averages, so we can get a sense of the difference between the tide gauge records and the satellite records.
Figure 4. Gaussian averages of the three tidal gauge records shown in Figure 3. In addition, the satellite records for the same location are shown, aligned to the average of the first five years of the common period of record.
I show the data from 1970 so we can compare recent records (last twenty years, back to the early 1990s) and early records (previous 20 years, early 1970s to early 1990s. Now, there are a few oddities here. First, although the satellite records generally “wiggle-match” the tide gauge records, the agreement isn’t all that great.
Next, of the three dataset pairs (satellite and tide gauge), two of the pairs (Wake Island and Majuro) end up together after 20 years. At Kwajalein, on the other hand, the tide gauge record ends up about 50 mm above the satellite record … the cause of this divergence is unknown. It appears to start in 2003, and it may be something as simple as the dock where the tide gauge is located slowly sinking into the sand … or not.
The most internally consistent data that we have, the satellite records, show little difference between the rise in Majuro and Kwajalein over the last 20 years. One is 6.4 mm, one is 7.4 mm … be still, my beating heart.
So Nils-Axel and Tamino are both wrong. We can’t conclude anything either way by comparing Majuro and Kwajalein. Their records are far too short and too similar.
Finally, how unusual are these three satellite-measured trends at Wake, Kwajalein, and Majuro, of 2.1, 6.4, and 7.4 mm respectively? Well, to answer that, I took the approximately half a million areas of the ocean for which the satellite has measured the trends from the University of Colorad, and made a histogram …
Figure 5. Histogram of the sea level trends for each 0.25° square gridcell of ocean area from 89.5 North to 89.5 South.
Now, the trends shown in Figure 5 are 20-year trends. Recall from Figure 1 that the 95% confidence interval on tide gauge records was estimated at just under ± 3 mm. The 95% confidence interval on these satellite measured trends in Figure 5 is somewhat larger, at ± 5 mm per year. Note also that about 12% of the gridcells show a decrease in the sea level, and thus they have a negative trend.
Finally, you need to be aware that the trend that is shown by the tidal gauge data is NOT the rate of sea-level rise, for a couple of reasons. First, what you are seeing is the rate of global sea-level rise PLUS the tidal effect from the sun, the moon, and the shape and resonant frequency of the basin. The means used for removing those tidal effects is beyond the scope of this discussion (see Mitchell for details under “Asymptotic Trend Evaluation”). However, generally what has to be done is the 112 different major solar/lunar tidal components are estimated from a tidal record to date at a specific location. Then the “best guess” estimate of the combined tidal effect is subtracted from the observed change in sea level. What remains is the best estimate of the actual change in the underlying sea level, but it still needs to be corrected for the land uplift/subsidence.
So for example, the measured change in the sea level at the Majuro B (SEAFRAME) tide gauge was +5.6 mm/year 1993-2010. But after subtracting the tidal effects, it drops to 4.3 mm/year. And after removing land subsidence effects, the actual trend was estimated by the SEAFRAME folks at 3.8 mm/year.
To complete the circle, here are the Majuro and Kwajalein tide gauge and satellite records, aligned on their 1995-2000 averages.
Figure 5. As in Figure 4, but with the Majuro records adjusted upwards by 59 mm so that they are all aligned on the average of their 19/95-2000 period.
SUMMARY: TIDE GAUGE AND SATELLITE DATA, MAJURO AND KWAJALEIN
• The early (1973-1993) and late (1993-2013) trends in Majuro were about the same.
• In Kwajalein, the early trend was about flat, and the later trend was quite steep.
• Given the close physical proximity of the two atolls, and the similarity of the two satellite records, one or the other of the tidal records may contain an error.
• After about 2003, the Kwajalein record wiggle-matches with the two satellite records. The Majuro record does not. On the other hand, after diverging from the two satellite records in 2003, the Majuro record ends up agreeing with them, while the Kwajalein record ends up ~ 50 mm higher than the other three. Go figure.
° The post-1993 Majuro tide gauge “B” is a modern design acoustic SEAFRAME gauge, and is presumably quite accurate.
• There is absolutely no statistical significance in the ~4 mm difference between the 20-year tide gauge trends for Majuro and Kwajalein. And the satellite trends, as you can see above, are nearly identical.
• In short, there is no evidence for or against an acceleration in sea-level rise in the three Marshall Islands records.
Best to all,
w.
DATA AND CODE: Spreadsheet is here … enjoy
UNCERTAINTY EQUATION—The empirical equation relating years of record (YR) and uncertainty (one standard deviation) is:
Uncertainty (mm/yr) = 0.102 * EXP( -4.939 * EXP( -0.02 * YR ) )
This says that with a fifty-year record we still have an uncertainty of plus or minus two-thirds of a millimetre per year, or 63 mm (2.5 inches) per century.
Kwajalein atoll is a string of islands enclosing a lagoon. Between the islands the water is shallow with reefs nearly reaching sea level. During a low spring tide one can walk across the reefs from one island to the next in some spots.
According to the map below, the Kwajalein tide gauge is on the lagoon side of the island of Kwajalein (the southeasternmost and largest island in the atoll).
https://www.bodc.ac.uk/data/information_and_inventories/gloss_handbook/stations/111/map/%7Bmapdir%7D/
As I mentioned in the previous thread, there was an in-filling in of the shallows between the three islands north of Kwajalein in 2002, and this changed the inflow-outflow between the ocean and the lagoon. I don’t know how much it affected the tide gauge readings, but it’s probably not insignificant.
MostlyHarmless says:
August 2, 2013 at 7:40 am
… with Darwin and Fremantle included – the method works particularly well there.
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It certainly sounds like you know what you are doing, but are you sure that you want to use Darwin? Daily tidal variations at Darwin are quite dramatic (as much as 8 meters) and any tidal component errors in sea level determination are likely to be much magnified there compared to other locations.
The Geo
Is it possible to compare the land “altitude” record from the GPS data to see if there’s any indication of subsidence/consolidation of the atolls themselves?
=======================
I think (opinion) that it’s possible, but not easy. It’s a geometry problem. Most of the time GPS satellites will be at low elevation angles and thus contribute mostly latitude/longitude information with only a little altitude information.
IMHO, tidal gauge data that isn’t backed up with solid altitude change information for the gauge is more or less useless for sea level change estimation. But I seem to be the only person who thinks that, so maybe I’m overlooking something.
Willis,
“I’ve spliced together the recent and the previous record at Majuro (Majuro B and Majuro C), as they are nearly identical in their overlap periods.”
Why do you continue to muddy the waters with superficial junk science???
Roger Andrews says:
August 2, 2013 at 6:34 am
Thanks, Roger. Figure 5 shows only two of the three Marshall Islands records. Overall, one record accelerated (Kwaj), one decelerated (Wake), and and the trend of one stayed about the same. Furthermore, because of the huge error in sea level rise from the tidal effects, there is no statistical difference between the three.
So no, Roger, those three records don’t provide evidence either way. That’s the whole point of my post. A 20-year tide gauge record has an inherent 95%CI of about ± 3 mm …
Roger, while I thank you for the information, I must say I despise the habit of posting uncited, unreferenced, unsupported results as you have done. Your cited graph is a great example of the kind of garbage I deal with daily. Which “18 tide gauge records” are they referring to? Where is the data? Is the average area-weighted, or not? What are the error margins on the result? Do all 18 stations run the full timespan? Have they combined SEAFRAME data with other data?
Since I can’t answer a single one of those questions from your graph, it goes straight into the garbage on my planet. It’s useless information, without patrimony or provenance, and as such is worse than no information at all.
Please, folks, if you are posting a graph, cite the source of the data or the graph. Otherwise, you’ll get roundly ignored, by me at least.
w.
Thanks, Peter. You say (emphasis mine):
pe51ter says:
August 2, 2013 at 7:22 am
I think we should correct your definition/explanation of a confidence interval (see figure 1). A 95% confidence interval will cover the true value of the thing we are trying to estimate on 95 out of of 100 occasions that we compute it. Each of those 95 out of 100 intervals will be different. In some cases the true value will be slap in the centre of the interval and in some cases it will be near the edge. So you are not correct when you imply that 95% of results will fall between the extremes of a single interval.
I don’t see the difference between your two statements. Both of them say the same thing, that 95% of the outcomes will fall between the extremes of a single interval, which is the 95% CI of ± 3 mm for a twenty year record.
What am I missing?
w.
arthur4563 says:
August 2, 2013 at 8:14 am
Curiously, the oceans do indeed “rise at certain spots”. Look at Figure 5. Heck, over the last 20 years about 10% of the gridcells have fallen, with negative trends.
Which is why I share your bewilderment at anyone grabbing one tide gauge record and proclaiming anything.
w.
The Geo says:
August 2, 2013 at 8:58 am
The SEAFRAME stations like Majuro all have an associated GPS. Other stations, like Kwajalein, do not.
w.
kuhnkat says:
August 2, 2013 at 9:43 am
Sorry, but there’s an ~ 7 year period of overlap. The correlation of the two datasets during the overlap period is 0.98 …
In addition, I’ve noted the splice procedure in the text, and provided the spreadsheet so you can see exactly what I did, and you can judge whether it’s a valid procedure or not.
Finally, I spliced them together because that’s what Tamino did when he made his claim. If I’m going to discuss his claim, then I need to follow his procedure.
What is “superficial junk science” about that, and why?
w.
JDN says:
August 2, 2013 at 8:11 am
@Willis:
I would be very interested in hearing more about areas where sea level is rising at an average 15 mm/yr. In 20 scant years, the sea level is reported to increase by a foot (~30 cm). What does that look like? Are these places anywhere near an island?
Would Australia count? This map shows the trend in SLR for ’92 to ’12 from sat altimetry
http://tinyurl.com/msltrends92-12
You may note that Australia and New Zealand are surrounded by quite a bit of red, although sea level measures form non satellite sources suggest something much different. This video of Dr. Willie Soon covers a number of arguments I have made in the past about why no one should get exited about sea level until something serious that has been above water shows indications of going under water.
To those who still can’t get past the notion that the seas of the world are anything but level
http://en.wikipedia.org/wiki/File:Geoid_height_red_blue_averagebw.png
and
http://bulletin.aviso.oceanobs.com/html/produits/aviso/welcome_uk.php3
Don K says:
August 2, 2013 at 9:26 am
It certainly sounds like you know what you are doing, but are you sure that you want to use Darwin? Daily tidal variations at Darwin are quite dramatic (as much as 8 meters) and any tidal component errors in sea level determination are likely to be much magnified there compared to other locations.
You’re right about the tidal range, but my correlation with SOI works very well there – better than the Pacific stations in fact, and it would work just as well for all W Australian stations as they have virtually identical sea-level profiles, though different rates. I’ve now posted charts, including a reconstruction for Majuro (Willis’ reconstruction is sound, average difference only 12mm), and charts for Kwajalein, Pago Pago, Pohnpei, and an up-to-date (June this year) sea-level chart for Majuro, which shows the uptick has subsided, following SOI down to around zero at end 2012.
Almost the exact opposite is happening on the W coast of N America, as Californian stations show. When sea-level rises in the west, it falls in the east, and vice-versa, but over an underlying upward trend of course. That current (20 years) underlying trend in the west is around 2.5 mm/year from my corrections, which is rather less than the published global rate from altimetry.
Roger Andrews quotes: “In short, there is no evidence for or against an acceleration in sea level rise in the three Marshall Islands records.”
The Roger Andrews says, “This statement is incorrect. Figure 5 shows clear evidence for an acceleration in SLR after 1990.”
Willis was trying to explain. There are complex and fairly chaotic changes in sea level due to tides and ocean water “sloshing” around. Then there are issues with the measurements themselves. Given the above, it is expected that you could easily find 3 tidal gauges that show an acceleration that does not actually exist or show a deceleration or even a drop in sea level that does not exist.
The idea is that even if the gauges show an acceleration in sea level rise especially over a short period like 20 years, this is not scientifically valid evidence that sea level rise is accelerated due to the previously mentioned chaotic tidal changes and potential problems with making the measurements. You are correct that it is “evidence” It just isn’t convincing or statistically significant evidence.
Willis:
Here’s a plot of the 18 tide gauge records with accompanying data. The mean is arithmetic because I’m calculating sea levels relative to coastlines, not absolute sea levels.
http://oi44.tinypic.com/1085lyr.jpg
Incidentally, a polite request for more data would have been more appropriate than dismissing my work as “garbage” before you’d even seen where it came from.
Though it is really off the topic that Willis was really getting at there are some interesting things about sea and earth heights that need to be discussed when trying to find what is going on with sea level. Willis was kind to arthur 4563 when discussing the variability of some sort of standard worldwide sea level.
The sea and even the earth are not ever static. The earth’s geoid in fact varies by up to 100 meters in a somewhat static fashion over the global surface. Tidal forces seen in the oceans also can be seen on the earth. There are earth tides at times as great as a meter. Rebound of portions of continents from removal of glaciers can cause some dramatic changes in gauge measurements. Subsistence of islands can do the same. This is a very dynamic earth we live on and trying to get even long term sea height measurements is a daunting task.
In one of my previous lives I worked on a program called Seasat which had a synthetic aperture radar on it. I was a field type that tracked this satellite but I was very curious about one of my babies and looked at the data as it was developed and was put out to the public. Sea heights throughout the ocean basins varied a lot. Things like seamounts affected heights. It was an eye opener as to how un-static the oceans were. We need to keep relearning what we think we really know.
Bernie
This is not about tides. Roger Andrews is pointing to the mid-90s shift in trade winds.
Tides are just one element of what can be seen. Of course trade winds cause some long term height differences in the Pacific that put some these tiny signals in the noise. And many other elements are at work here. Teasing out “real” sea height values is a daunting task.
To clear up some evident confusion.
All I’m saying is that Figure 5 does in fact show evidence for an acceleration in the rate of sea level rise in the Marshall Islands after about 1990. I haven’t commented on whether or not this acceleration is statistically significant or on what might have caused it, although the fact that we see it when 18 tide gauge records in the central Pacific are averaged together suggests that it may be real.
Roger Andrews says:
August 2, 2013 at 12:22 pm
A polite request for more data? Why should I care about your data? YOU should care that there is a LINK to your data and code. I assume that the plot is the result of a spreadsheet. Where is the spreadsheet? Without it, as I said, that’s just garbage. Artfully delivered garbage, to be fair, and apparently meaningful … but in fact useless in this discussion. I can’t demonstrate the error bands on your results. I can’t see if you’ve made stupid mistakes. I can’t measure the autocorrelation and see if it’s significant (as I suspect it will be). It’s of no use to me at all.
I’m certainly not going to root around in the PSMSL looking to duplicate your spreadsheet. If you think your spreadsheet shows interesting results, then publish a link to it.
And yes, you’re right, without such a link, your graph may not be garbage … but it sure as hell won’t gain any traction with me.
w.
Roger Andrews says:
August 2, 2013 at 3:46 pm
Thanks for the clarification, Roger. What Figure 5 shows is one record, Majuro, that has a fairly constant trend beginning to end.
The other record, Kwajalein, is basically flat for the first half of the Figure and rises after that.
That is not “evidence for an acceleration in the rate of sea level rise in the Marshall Islands”. This is particularly true when the only other Marshall Islands record, Wake, shows no such acceleration. Like Majuro, it has a fairly constant trend end to end.
So two out of the three Marshall Islands records show no increase in the rate of sea level rise. That’s many things, but it’s not “evidence for an acceleration”.
Next, you say it is “evidence” but that you don’t know whether the change is statistically significant. It doesn’t become “evidence” until it is actually shown to be statistically significant. I’ve shown that the difference in the two trends is NOT statistically significant, so it is not evidence.
Next, whether the average of the 19 records is significant remains unanswered. The uncertainties in even long tidal records are large. Many of the records you cite are only 30 years long. From Figure 1, that gives them a ± 1.5 mm/year 95%CI.
Additionally, such averages tend to be highly autocorrelated. As a result, the difference in the pre- and post 1990 trends may not be statistically significant. So I wouldn’t draw any conclusions without a statistical analysis of the results. With highly autocorrelated data, what looks like a trend may be just random fluctuations …
Finally, you need to bear in mind that not one of the records you accessed has had the tidal effect filtered out. Those records are the SUM of the slow tidal changes and the underlying sea level changes (if any). The sun-moon tidal cycle roughly repeats with an 18.6-year period, with a closer return to original conditions every three cycles (55.8 years). That’s why you need fifty years of tide gauge data to determine the change in the underlying sea level.
So what we are looking at in your graph may be just the tidal action and the standing waves. Remember that while overall the sea level has gone up over the last 20 years, the sea level in about 10% of the 0.25° gridcells has actually gone down over that time … that should give you an idea of the size of the standing waves in the Pacific basin.
Best regards,
w.
Paul Vaughan says:
August 2, 2013 at 2:15 pm
Cite? Not saying I disbelieve it, quite the opposite. I’m saying I’m interested.
w.
Lol tide gauges are normally within harbors where weather and construction play a large part in the long term averages. As for GPS its based on a theoretical model of the earth and even DGPS is only accurate to 2meters which is great for ships and meaningless for survey results.
What “tidal effects” did you remove from the Majuro data, Willis? Enlighten us please. Monthly sea-levels are mean sea-levels, and average out all the high-frequency tidal components. Over the course of a year, all the others are accounted for too, except the 18.6 year nodal tidal cycle, and its amplitude is about 25mm for Majuro. Only a fraction of that can possibly affect the tide height over the entire cycle. The NTC increases tidal amplitude – high water is higher and low water lower, both by half the NTC amplitude at any location. There may be a residual of as much as 10-20% of the amplitude at some stations, less at others, and only about 25% of stations worldwide exhibit any detectable NTC variation. The NTC varies in phase and amplitude around the globe, with an extreme range of between 10 and 100 mm.
If your truly interested in why tide gauges, even 18 averaged over the pacific, is meaningless, read this article concerning DATUM. http://geokov.com/education/datum.aspx
But now Tamino can’t descend in to more statist panic.
Tidal variation between locales is one reason that Holgate 2007 combined the result of a number of sea level gauges worldwide, to see the picture of overall global sea level rise history (using 177 stations and using 9 particularly high quality stations over various continents), and, as they observed:
“The rate of sea level change was found to be larger in the early part of last century (2.03 ± 0.35 mm/yr 1904–1953), in comparison with the latter part (1.45 ± 0.34 mm/yr 1954–2003).”
On the decadal rates of sea level change during the twentieth century
S. J. Holgate
Geophysical Research Letters, Vol. 34
http://www.joelschwartz.com/pdfs/Holgate.pdf
Overall, sea level rise rate deaccelerated over the past century.
Figure 4 of that paper (full-text linked above) plots the sea level record in the cumulative rise form which most people are used to seeing, favored by alarmists since it looks like more of a continuous upwards trend than if plotted otherwise.
Figure 2, however, is particularly informative by plotting the sea level record as a rate of change over time, showing the derivative, in a manner usually never ever, ever seen from most sources since it is too revealing of the truth and not suited for making misleading propaganda.
While the misleading style of plotting used in most (other) publications makes the derivative of change not easy to see, the depiction of figure 2 in contrast reveals how there are cycles in such fitting with cycles in cosmic ray forcing as illustrated in the middle of the following:
http://s23.postimg.org/qldgno07f/edited4.gif
(enlarges on click)