Guest post by Paul Homewood
It is generally accepted that sea levels increased during the 20thC at a rate of about 185mm or about 7”. Furthermore studies suggest that there was no acceleration in this rate during that time. One of the best known studies was by Bruce Douglas, who produced the above graph from Tide Gauge records for 23 geologically stable sites.
Satellite monitoring of sea level, which began in 1993, however, shows that the current rate of increase is about 2.8mm/year.
So, question – has the rate of sea level rise really accelerated in the last two decades. In this study, I will be extending Douglas’s work up to 2011 to find out.
Methodology
Douglas based his work on tide gauge records from PSMSL, (The Permanent Service for Mean Sea Level), and used the following criteria :
- Each record should be at least 60 years in length
- Not be located at collisional plate boundaries
- At least 80% complete
- Show reasonable agreement at low frequencies with nearby gauges sampling the same water mass
- Not be located in regions subject to large post glacial rebound.
He subsequently identified 23 sites that met these criteria. (These are listed in Appendix A). The tide records at each site were adjusted for any post glacial (isostatic) rebound, i.e any rise or sinking of the land, so as to isolate the eustatic sea level, i.e. the quantity of water in the ocean.
Of Douglas’s 23 sites, only 12 have full or nearly full records since. (Newlyn’s records go up to 2009, but are included). From these 12 stations, I have reconstructed the Douglas graph.
A point I will keep emphasising is that I am not trying to establish “the actual amount of sea level rise”, but am looking to quantify “the relative rate of change”. In other words, is the current rate of rise greater (or smaller) than the rise during the last century.
Bearing this in mind, my reconstruction is not adjusted for isostatic rebound. There are two reasons for this :-
1) Any such adjustment is adding a certain amount of subjectivity, which is absolutely not necessary.
2) As the objective is to compare the rate of sea level change between 1900-2000 and 2001-2011, the isostatic factor is irrelevant, as it is, to all intents and purposes, a fixed amount.
Reconstruction
Figure 1 shows the spaghetti graph for each station, which naturally does not tell us a huge deal. However Figure 2 averages all twelve stations together, with a cumulative three year running average plot, exactly as Douglas did.
Figure 1
Figure 2
Two things stand out :-
1) The new reconstruction indicates a sea level rise from 1900-2000 of 168mm, actually a pretty good fit with the original Douglas calculation of 185mm. The difference between the two datasets can be ascribed to two factors :-
a) No adjustment for isostatic rebound in the new reconstruction.
b) The elimination of the 11 stations, which do not have recent records.
We have already discussed isostatic rebound and this does not affect the trend line of the graph one way or the other.
As for the reduction in the number of stations, Appendix A shows that there are now no Southern Hemisphere sites in the new dataset. Could this be skewing the average? More on this later, though.
2) The sea level rise has stuck pretty close to the long term trend (red line), both throughout the record, but more significantly in the last decade. This is our first indication that there has been no acceleration in the trend, at least in these 12 stations. Contrast the last decade, for instance, with the period 1940-60 when levels were consistently rising faster than trend.
Before we look more closely at the figures, it is worth remembering that the three year average used above combines both the 2011 La Nina and the 2010 El Nino in the 2011 average, thus smoothing out any ENSO variability. (With no such smoothing, the 2011 figure would show a sharp drop.)
A closer look
We don’t have to rely on eyeballing the graph in Figure 2. Figure 3 shows the year on year changes in sea level (rather than the cumulative change).
Figure 3
While there is considerable inter annual variability, the 10 year running average indicates no upward trend. But we can actually go one step further, by focusing in on the 10 year average and therefore a much smaller range, as shown in Figure 4.
Figure 4
The red line is the trend and actually shows a small decline since 1900, although the last 10 years are slightly higher than trend at 2.15mm/year. However, the 10 year figures are comparing 2011 with 2001, when sea levels were lower than usual, having declined for two years, as Figure 2 illustrates.
Figure 5 gives a broader perspective by listing the average annual increase to 2011, depending on which start year is selected.
Start Year mm/yr increase to 2011 1990 2.20 1991 1.41 1992 0.23 1993 1.00 1994 1.44 1995 0.35 1996 1.09 1997 -1.08 1998 0.65 1999 0.78 2000 1.89 2001 2.15 Figure 5
Bearing in mind the increase in the 20thC was 1.68mm/yr, there has been nothing unusual in trends since the 1990’s, regardless of which year you compare with. Indeed, the evidence would suggest a declining trend.
Southern Hemisphere
As previously mentioned, the reconstruction now includes no Southern Hemisphere sites, with three New Zealand sites (Auckland, Dunedin and Lyttleton) and two Argentine sites (Buenos Aires and Quequen) disappearing because of the lack of recent records. Could the recent trend be biased because of this?
Although there are now no sites with records back to 1900 in the Southern Hemisphere, there are a few with continuous records since the 1960’s. In New Zealand and Argentina, Wellington and Palermo respectively fit the bill. To these I have added two Australian stations, Port Adelaide and Port Lincoln. There are no such records available in other Southern Hemisphere countries. The sea level changes are plotted in Figure 6 and make interesting reading.
Figure 6
There is a clear decline in the trend, which the actual figures emphasise. Between 1966 and 2000, sea levels rose by 2.99mm/year, at the four stations averaged together. (1966 is the earliest year that we have records for all four sites). By comparison, between 2000 and 2010, they actually fell by 1.73mm/year. Furthermore, because there are no records for any of these sites in 2011, the plot finishes in 2010, when global sea levels appeared to be higher than normal.
In other words, the exclusion of Southern Hemisphere stations, far from causing the reconstructed sea level trends to be understated, seems to have had the opposite effect. (For the record the New Zealand and Australian stations show falls since 2000, whilst Palermo shows an increasing trend).
Let me make this clear. I am not claiming this small sample is representative of the Southern Hemisphere as a whole. But I would claim that it is a reasonable substitution for the stations excluded from the original Douglas study.
Church & White
In 2011, John Church and Neil White published their paper, “Sea Level Rise from the Late 19th to the Early 21st Century”. This attempted to reconcile sea level measurements from tide gauges and satellites. They concluded that between 1993 and 2009, sea levels rose by 3.2mm and 2.8mm per annum as measured by satellites and tide gauges respectively, as shown below in Figure 7.
Figure 7
Global average sea level from 1990 to 2009 as estimated from the coastal and island sea-level data (blue with one standard deviation uncertainty estimates) and as estimated from the satellite altimeter data from 1993 (red). The satellite and the in situ yearly averaged estimates have the same value in 1993 and the in situ data are zeroed in 1990. The dashed vertical lines indicate the transition from TOPEX Side A to TOPEX Side B, and the commencement of the Jason-1 and OSTM/Jason-2 records
Two things stand out though.
1) 1993 is used as the starting point (being the start of the satellite record). However, as Church and White themselves point out :
“However, the reconstruction indicates there was little net change in sea level from 1990 to 1993, most likely as a result of the volcanic eruption of Mount Pinatubo in 1991. “
In other words, the trends have been calculated from an abnormally low point in the long term record. (Shades of 1979 and satellite temperatures!). This dip can be seen very well on the original Douglas graph, shown again below.
2) The exercise stops in 2009, when sea levels were at a cyclical peak, as confirmed by both satellite records and tidal gauges.
So Church and White are comparing an unusually low point in the cycle with an unusually high one. Of course, their choice of dates was purely circumstantial, but, particularly over such a short period of time, such a choice of dates renders their results pretty meaningless. (Figure 5 shows just how much difference the choice of start dates can make). Satellites suggest a drop of 5mm from 2010 to 2011. Based on this, Church and White’s tidal gauge estimate of 2.8mm/year becomes 2.2mm/year, from 1993 to 2011.
Is 2011 unrepresentative?
Both satellites and tide gauges confirm that sea levels fell in 2011 with La Nina. So, is using 2011 as the end year disguising an accelerating trend?
I would answer this in two ways :-
1) As previously mentioned, I have opted for a 3 year average, in order to replicate the Douglas exercise. This has conveniently averaged together the 2009/10 El Nino and the 2010/11 La Nina within the 2011 “3 year average”, and consequently giving a robust underlying number. (Over the next two years this number should decline as the 2009 and 2010 figures are removed from the average, assuming, of course, no new El Ninos).
2) I have also shown 10 year averages, which to some extent dilute and smooth out changes in a single year. (For interest, if sea levels in 2010 and 2011 are averaged together in the reconstruction, the 2011 figure is increased by about 10mm. If the average annual increases in Figure 5 were calculated against the 2010/11 average, the increase since, for example, 1993 would be 1.56mm/year , instead of 1.00mm).
Conclusions
In the reconstructed analysis, there is no evidence of an acceleration in the long term rate of sea level rise, which remains at below 2mm/year. Furthermore an analysis of Southern Hemisphere sites suggests a slowing down in the rate. The sample sizes in both cases are small and give limited geographical coverage. Nevertheless, they give a similar coverage to the original Douglas study, which has generally been accepted as giving an accurate assessment of 20th Century rise. (For instance, the IPCC quote a figure of 1.7mm/year).
The divergence with satellite data can, logically, only be due to one or more of the following factors :-
1) The original Douglas study is based on an unrepresentative sample or inaccurate records. If this is so, it would suggest that the rise of 1.85mm/year, that Douglas calculated for the 20th Century, is significantly understated.
2) Satellite measurements are wrong.
3) The relatively short satellite record is too short to give a accurate long term trend, particularly as it starts at a low point in the cycle.
4) The exclusion of 11 stations from the reconstruction has reduced the true rate of sea level rise. It would appear, however, hugely unlikely and coincidental that these 11 stations had a rapidly increasing trend, while the other 12 showed no trend change at all. In any event, we have seen that this is not the case in the Southern Hemisphere analysis.
One final comment. From this study, it appears that the number of reliable tidal gauge sites, with reasonably long and complete records, is on the decline. Is too much reliance being put on satellites? Maybe. But when sea level rise is such an important and controversial topic, I find it both astonishing and rather sad that this is being allowed to happen.
References
1) PSMSL data is available here.
2) Further information is available from the University of Colorado Sea Level Research Group.
3) Details of the Bruce Douglas study are here.
APPENDIX A
LIST OF SITES
Location Country/State Sea Level mm
2000
Sea Level mm
2011
Increase mm/yr
1900-2000
Increase mm/yr
2000-2011
Trieste Italy 7060 7070 1.44 0.91 Santa Monica CA 6996 7011 2.19 1.36 San Francisco CA 7050 7086 1.53 3.27 San Diego CA 7059 7115 1.49 5.09 Marseilles France 6990 7035 0.82 4.09 Fernandina FL 7262 7225 2.22 -3.36 Brest France 7133 7115 1.97 -1.64 Honolulu HI 7044 7068 1.36 2.18 Key West FL 7211 7215 2.16 0.36 Newlyn UK 7097 7157 1.46 6.66 Pensacola FL 7064 7095 2.51 2.82 La Jolla CA 7060 7104 1.63 4.00 AVERAGE 1.68 2.14 LIST OF SITES ORIGINALLY IN DOUGLAS, BUT EXCLUDED DUE TO LACK OF RECENT RECORDS
Location Country/State Auckland NZ Balboa Panama Buenos Aires Argentina Cascais Portugal Cristobal Panama Dunedin NZ Genoa Italy Lagos Nigeria Lyttleton NZ Quequen Argentina Santa Cruz Tenerife
Gasp! 20 Cm? In only 130 years?
Quick. EVERYBODY! Don’t stop to think. Run the other way. High ground is this way… Er, no, this way… oh Woe is us!
Now I understand Al Gore’s reticence about beach-front property… er, wait.
@ur momisugly Stephen Rasey
I believe the too many stations Douglas chose fail a tectonic setting test. Long records are probably to be had from China, Japan, Hong Kong, India, Persian Gulf, Scandinavia, Gibralta, Lagos and Luanda. New York, Boston, and the sea faring town of New England probably have long records, too. Gather them all. Group them by tectonic setting. Let the data speak for themselves. Don’t cherry pick the locations by some isostatic rebound criteria.
I presume Douglas had good reasons to pick the stations he did and leave out the ones you suggest.
Honestly don’t undestand this, anyone give me the basic idea why the satellite measurements are so substantially different from the tide gauges? I had somebody argue with me not long ago that sea level rise ‘accelerated’ because the older tide gauge data showed a smaller increase than the satellite data does now. This article suggests I was right to doubt this claim, but I still can’t explain the satellite / tide gauge discrepancy because I don’t understand it at all. Heelp?
To put the rate of sea level rise in perspective, the Atlantic Ocean is widening at 10 times the rate of sea rise. Dust and landfill accumulate faster. Tells–ancient city mounds made of dust and debris–grew faster than the sea rises. And as we know, coral has grown fast enough to keep up with most or all past rates. Plenty of geological processes dwarf the rate of sea rise, making its modern measurement more theoretical than problematic. –AGF
In Appendix A sea level is given for each site for 2000 and 2011 with the values all being in the general vicinity of 7 meters +/-. My question is 7 meters relative to what exactly?
An interesting presentation on sea level rise and estimates of trends: http://publicwiki.deltares.nl/download/attachments/76616483/present.pdf
Section 4 covers the problems of overestimating the trend in sea level rise – where forecasts do not match observations, but analysis exaggerates the trend. Problems identified included: sensitivity to starting period (so, cherry picking the start); sensitivity to the end period (cherry picking the end); use of the “nodal cycle” (starting at the bottom of a cycle, terminating at the top); improper calculation of trends; using trends obtained from different datasets to argue for an increase in rate of rise; application of “corrections”, etc.
Certainly a fraught area of study: the problem is more complex and results are far less clear than those promoting alarm would care to admit. Gee, isn’t that unusual?
Paul S: The 2001 to 2010 trend at Port Adelaide is ~5mm/yr and at Port Lincoln is ~2.5mm/yr. but…. The historic tide gauge records from Port Adelaide and Outer Harbour are one of the more important datasets from the Australian region purporting to show a significant rate of local sea level rise. However, geological evidence including radiocarbon dated palaeosea level indicators, indicates that most of this rise is due to subsidence of the land. The subsidence is significant but localized, and can be largely attributed to human activities associated with port development, reclamation and industrialization….
The tide gauge data from Port Adelaide and Outer Harbour have been used in global sea level rise calculations without adequate local neotectonic correction. Although outside the zone of greatest land subsidence, three‐quarters of the secular rise in mean sea level of 2.5–2.9 mm/year indicated by the tide gauge records can be attributed to land level changes. Hence the local sea level trend is a rise of 0.7 mm/year.
From A. P. Belperio “Land subsidence and sea level rise in the Port Adelaide estuary: Implications for monitoring the greenhouse effect”, Australian Journal of Earth Sciences: An International Geoscience Journal of the Geological Society of Australia
Volume 40, Issue 4, 1993 [OK so it’s quite old :-)] pp 359-368
this business of measuring sea level is a hundred times worse than herding ten thousand cats with two dogs.
firstly i worked for thirty plus years at a shipyard on the west coast. my desk was about 100 feet from the waters edge. it was, depending on the tide anywhere from six to fifteen feet below sealevel.
secondly there is this matter of measurement. if you take ten sheets of standard copy machine paper then their thickness is approximately 1 MM. or .039″. for the folks that like to throw that figure around remember that machinests work to .0005″ all day every day and some work to .0001″ (the limit where thermal expansion can be detected on the shop floor) as a normal thing. the engraved lines on insturments are about .006″ wide and most individuals with a little training can “split the line”.
if you are trying to measure sea level in a station in a harbor then have you considered the following variables. tides, in southern california in a south facing harbor, the tidal variation between spring extreme high tide and spring extreme low tide can be as much as 12 feet (and it happens in a matter of about 12 hours). then there is the business of temperature. the railroad people who have literally miles of steel rail to measure consider that the coeficient of expansion of steel is .0001″ per inch per degree farenheight change in temperature. so for the soul that wants to hang a tidal guage from the golden gate bridge, just when do you take the measurement . the bridge is probably about 3/16″ (.187″) taller in the afternoon than it was in the morning. (you can’t say we will do it at 1200 local time because the high tide low tide cycle works on about a 11.5 hour period.) besides if you would care to walk across a really large bridge you would find that out in the middle they bounce up and down quite a bit naturally [getting stopped out in the middle of a suspension bridge during a traffic jam at rush hour can be quite scary what with the swaying, and bouncing that they do.]
then there is that thing that all harbors have called “surge”. in the los angles/long beach harbor it is a very long period “wave” that takes about 15 minutes to happen. in simplification it is a change in the local appearent sealevel that changes with weather, temperature, large ships going by, small ships going by, tugboats with fuel barges manuevering…….. of course the occasional tsunami contributes……. even a rowboat twenty feet from the guage can affect the readings. then we have the chop. what effect does chop have on the sealevel guage. i know that they are hidden in vertical pipes at the waters edge (used to do a bit of fishing beside one) with inlet holes down pretty deep. but do the lads ever consider that the wind that blows chop toward the gauge also moves water towards it and vice versa therby giving a false reading………………..
i guess that what i’m leading up to is that there are so many variables in measuring ocean levels that the authority on this must be a world class statistician who grew up in huntington beach ca and is working at either a major estuary or harbor having gotten his/her degree at Pepperdine. (its within sight of the Pacific Ocean).
remember, its the dumb little things that will mess you up.
C
To say nothing of the variation in air pressure.
notalotofpeopleknowthat tidal observations are corrected for the ‘inverse barometer’ – a 1mb (0.03″Hg) increase in local atmospheric pressure will depress your local sea level by very close to 1cm (0.4″). A low pressure system over your locality at 975mb (28.79″Hg) will increase your local sea level by ~15 inches. Kinda puts the annual mm level changes into perspective.
Stephen Rasey says:
May 16, 2012 at 7:06 am
I think a separate study needs to be done using tide gauges anchored into granitic plutons and measure sea level, glacial rebound and all. Favor the passive margins of continents.
John Daly (“Still Waiting for Greenhouse) thought that Australia was tectonically stable and much less affected by PGR than either Europe, Asia or North America. He has a table on this page:
http://www.john-daly.com/ges/msl-rept.htm
showing that:
Eleven of the 27 stations [in the National Tide Facility Survey 1998] recorded a sea level fall, while the mean rate of sea level rise for all the stations combined is only +0.3 mm/yr, with an average record length of 36.4 years. This is only one sixth of the IPCC figure. There was also no obvious geographical pattern of falls versus rises as both were distributed along all parts of the coast.
But there’s more. It was shown earlier that Adelaide was a prime example of local sea level rise due to urban subsidence. It’s two stations in the above list are the only ones to record a sea level rise greater than the IPCC estimate. The same NTF survey pointed out the Adelaide anomaly and directly attributed it to local subsidence, not sea level rise, on the grounds that the neighboring stations of Port Lincoln, Port Pirie and Victor Harbour only show a rise of +0.3 mm/yr between them. If we exclude Adelaide from the list, the average sea level rise for the other 25 stations is then only +0.16 mm/yr, or less than one tenth of the IPCC estimate.
Very nice! This just might be the most useful data for understanding global warming that exists.
Once corrections are made for isostatic rebound and land subsidence, the multi-year average rate of sea level rise is a direct measure of the warming rate – more warming of the ocean means more thermal expansion of the water and more warming also increases the ocean volume through melting of continental ice masses. What this data says is that the ocean (and glaciated land mass) was warming just as fast from 1900 to 1910 as it warmed from 2000 to 2010. Since the sea-level rise has been ruler-straight for the last 100 years, and since CO2 concentrations were far lower in 1900 than 2000, one can conclude that CO2 isn’t the dominant factor in creating the heat balance disequilibrium that has existed for the last 100 years.
Mark Bofill says:
May 16, 2012 at 12:25 pm
Honestly don’t undestand this, anyone give me the basic idea why the satellite measurements are so substantially different from the tide gauges?
==========================
Because, since satellites fall out of orbit….and get closer to the earth……satellite measurements are adjusted up……just like UHI
For the record, the tidal gauges for the two Australian sites read :-
Port Adelaide – 1966 – 6875mm
2000 – 7021mm
2010 – 6988mm
Port Lincoln – 1966 – 6897mm
2000 – 7034mm
2010 – 6975mm
pk says:
May 16, 2012 at 1:54 pm
=============================================================================Very interesting. Still, your desk was below sea level; apparently the pumps never gave out. And the complications you describe remain miniscule compared to the problems with measuring global T, and could be more easliy overcome.
As for the wakes of boats, here’s something you might find interesting–I read in an old book about sea level on Lake Geneva that reported consistent changes measured right when the steamers entered or left harbor–on the opposite shore! While initially we conceive of boat propulsion as resulting from propeller thrust, the fact remains that the prop current can only push water against water, which must ultimately result either in a circumpolar current or in a transfer of energy to the lithosphere. Such a transfer is effected by a small rise in sea level on the shore. Similarly the lift of a plane is accomplished by increasing the air pressure beneath and behind it. The point being, the wake of a boat is in fact higher than the surrounding water.
Cheers, –AGF
Erosion?……………………………………….!.WUWT.
Thanks for all the interesting articles and comments.
Mark from Los alamos.Your remark is quite convincing,but there is one more point to discuss:According to IPCC (AR4.5) sea level increase is depending on two factors Ocean temp
and ice melting ,about half for each factor.If ocean temperature and ice melt can be presumed
varying together,then they must have been nearly constant all the time since 1880.Means the ocean temperature has not increased at all.Where is the CO2?
@agfosterjr:
its a pretty common thing to be fishing on a quay wall and see small waves breaking on the wall and the only reasonable explanation was a ulcc going by a mile away and thirty minutes past.
what i was trying to illustrate is that there are so many variables in this matter that its not particularly bright to make hard rock claims of sub millimeter activity or movement.
the reason for my desk being below sealevel was that a benchmark that was surveyed monthly and established in 1943 had dropped 23 feet by 1953 and then re risen by about 15 feet by 1968.
the cause of sinkage was attributed to subsidence caused by oil “recovery” activities. the rerise was attributed to steam injection to enhance that recovery.
C
Broome in the NWest of Australia had the main town centre built at the high tide mark before 1900, for the Pearling Induistry, and is still there, at the same high tide mark in 2012.
http://pindanpost.com/2011/05/16/sun-pictures-broome-victim-of-agw/
http://pindanpost.com/2012/04/10/biggest-broome-tides-for-2012/
Can satellites ever correctly measure MSL?
http://www.esri.com/news/arcuser/0703/geoid1of3.html
jh says:
May 16, 2012 at 2:08 am
Point of information.
How does the eruption of a volcano affect measured rise in sea level?
The aerosols released affect the amount of water vapour in the atmosphere, and hence the amount of water in the oceans.
As the study I quoted above shows, the effect is large, several times larger than the ‘normal’ annual rate of sea level rise and continues over several years.
Which suggests that a component of sea level rise may result from reductions in anthropogenic aerosols (overwhelmingly in the NH) and may partially explain the NH – SH sea level change differences.
All the evidence in fact shows that contrary to the IPCC’s claims, sea-level rise is not accelerating. UK oceanographer Simon Holgate (2008) analysed nine long sea-level records for the period 1904-2003. He found that between 1904 and 1953, sea-level rise was 2.03 mm per year, compared with 1.45 mm per year for the period 1953-2003.
Further proof that sea-level rises are not increasing, as the climate models predict, comes from a paper by Phillip Watson (2011). Based on century-long tide gauge records from Fremantle, Western Australia (1897 to present); Auckland Harbour in New Zealand (1903 to present); Fort Denison in Sydney Harbour (1914-present); and Pilot Station at Newcastle (1925 to present), Watson concluded there was a consistent trend of weak deceleration from 1940 to 2000. Climate change researcher Howard Brady of Macquarie University was quoted in The Australian of Friday 22 July 2011, p. 1, as saying that the recent research meant sea level rises accepted by CSIRO were already dead in the water as having no sound basis in probability. He added that divergence between sea-level trends from climate models and sea-level change from the tide-gauge records was now so great that it was clear there is a serious problem with the model.
For further evidence that the IPCC’s case is a massive fraud, please go to my website:
http://jpenhall.wordpress.com/2011/04/02/why-i-remain-a-climate-sceptic-in-relation-to-human-emissions-of-co2/
John Penhallurick
In all these studies of sea level rise, there is talk of warming water and talk of isostatic rebound, but precious little about sediment filling in the oceans.
The entire Grand Canyon washed down the Colorado river and filled in a large chunk of the Gulf of California. That has to count for something. How about all the other tons of sediment per day washing down the global rivers?
http://chiefio.wordpress.com/2011/04/01/where-did-the-grand-canyon-go/
Then there is all the volcanic “stuff” from all the ocean floor volcanoes and rifts. Just ignored?
Frankly, the floor of the ocean is relatively thin and under strong compression from the spreading zones in the middle. Think maybe something 10 miles thick and 1000+ miles long can ‘buckle’ a bit some times? Up and down? We ASSUME the ocean floor is static when we know it isn’t static. That, IMHO, is a problem…
Excellent post, Paul. Very clear, well-written and informative. I particularly liked the table showing how start year effects the 2011 result, and your expose of Church & White’s post-normal science approach to the analysis. Many thanks.
agfosterjr says:
May 16, 2012 at 9:06 am
Oddly enough, LOD responds to sea level rise differently depending on whether the source is thermal expansion or melting ice. …
I might add that the LIA and MWP can be roughly inferred from reconstructed LOD. –AGF
Thanks for the interesting comment. I’ve reposted it for discussion.
Please link the LOD reconstruction you refer to.
http://tallbloke.wordpress.com/2012/05/17/a-g-foster-jr-lod-and-sea-level/