Guest post by Andi Cockroft
Firstly, let me declare that I am not a current student of Geology or Geophysics. I studied Mathematics, Computer Science and Geology at University way back in the 60’s and I have focused my entire working life in IT. To this day, I still run a small IT company in New Zealand.
I follow the workings of the climate models with interest, since much of my University life was spent on Numerical Analysis and Stochastical Processing – the pre-cursors to today’s modelling. Although back then, Computer power was measured in kilo-flops, and the first mainframe I worked on was 20K. A 1Mb mainframe was but a pipe-dream – our biggest was 128K.
On the other hand, my groundings in Geology were at a time when my Professor was still agnostic about plate tectonics (although my tutor was an avid proponent thankfully). It was a time when magnetic striping of the mid-Atlantic was known but not totally understood. It was also a time when isostacy (although an old theory) was finding new support.
So, I offer this post not as any particular expert in the field, but rather to stimulate discussion from those far more familiarity with the concepts than I – please feel free to correct my impressions and limited understanding of the various topics
All I am proposing here are some of the fundamental questions that bother me regarding Isostacy, melting or re-freezing ice-caps and the effect on global mean sea-level (GMSL).
Firstly, just what is GMSL? I don’t believe it can ever be measured against one specific location on the globe – for just about everywhere on this planet is in motion to some degree or other – north/south, east-west, up/down – although our impression is of a stable terra-firma, geologically speaking it isn’t – it is more like the skin of a rice-pudding floating on the more fluid layers below.
If you ever played with your rice-pudding as a child, let the skin form and then pressed on it with your spoon? Press on one place and the skin will rise in another. So the Earth responds to increasing or decreasing pressures (or mass) on its crust.
The earth’s crust (or lithosphere) “floats” on the more fluid asthenosphere. The thickness and relative buoyancy of that part of the lithosphere will determine just how high or low it will “float”. When the buoyancy is in balance, it is said to be in isostatic equilibrium. There are many places that still today are not in isostatic equilibrium.
In terms of mountain building, where for instance the Indian plate is hurtling northwards into the Eurasian plate giving rise to the Himalaya Mountains – the gravity measurements tell us that just like an iceberg, there is just as much if not more “Everest” below the crust as there is above it – the buoyancy of that extra material below is needed to support the weight of the Mountain Range above.
Imagine ice floating in a bath – add more weight on top and the ice will sink such that the Archimedes principle of displacement is yet again in equilibrium. Indeed, add too much weight and the whole iceberg will sink regardless – but that’s a diversion (think 2Km thick glacier!)
So back to the question – what is GMSL? To my way of understanding, it can only be measured against a theoretical spot, and must in this age of satellite and gps be measured relative to a reference datum and/or the calculated centre of the earth. Since the earth is not a true sphere – it is I believe referred to as an “oblate spheroid” – the averaging out of these measurements must be translated back into local datum to be able to measure against tide-gauges etc.
Then again, I have always maintained that Sea-Level is a local phenomenon – for many reasons.
Tides, temperature, winds, air-pressure as well as such phenomena such as ENSO etc
But given that statements implying GMSL was 300’ lower than today during the last ice-age, I ask the question – “but what was the real or relative sea-level back then in say New York State?” – in places under Kilometres of ice apparently. Certainly what is now the Great Lakes was inundated by huge ice flows.
That sheer weight of ice would have had the effect of pushing the underlying land-mass downward, to some extent counteracting the drop in GMSL – in fact (just in my imagination) – I believe that these areas would have been significantly below GMSL even with its 300’ decline.
Sorry I do not have the knowledge to do the calculation, but I hope here that group-science can answer the question.
There have been statements that New York was about 150 – 200 Kilometres inland during the last Ice Age 20,000 years ago – but would it have been? Wouldn’t Isostacy have taken the land-mass down with it?
One of the problems faced by modern day measurements of GMSL, is that Isostacy is still at work.
Remove the massive ice-flows from ice-age North America, and the continental land mass does not rebound instantly – it rebounds (uplifts) slowly – it is still rebounding today. As things equal themselves out over Geologic time, the land masses continue to rise, and as a counter, the ocean basins are actually falling. In other words, the oceans themselves gain a greater capacity to store water.
This expansion needs some accounting for, and this Global Isostacy Adjustment (GIA) is estimated at about the equivalent of 0.3 mm per year in GMSL, this at least partially offsets the predicted 3mm per year expansion of the oceans due to warming (that seems to have paused just now). Indeed, if thermal expansion of the oceans has paused, GIA will continue unabated and actually serve to lower observed GMSL.
All of this is a very roundabout way of me arguing that Sea Level is a local phenomenon, and calculating a GMSL whilst academically interesting serves no actual use. Certainly not in terms of Government and Policy decision-making.
In England, long before Liverpool was ever heard of, the River Dee provided the main shipping for the North West. First Chester (used by the Romans), then further out to Burton and Neston and ultimately Parkgate were the main points of embarkation for Ireland. Visit Parkgate today, and the sea is many hundreds of metres away with a huge salt marsh in between.
In New Zealand, where I have lived this past quarter-century, there are many places where erosion is eating into the coast and houses are inexorably marching towards oblivion. In others, accretion of up to 1 metre per year is extending the land-mass ever seaward.
Yet Local Government in these areas is focused almost entirely on projected changes to GMSL rather than what is physically happening.
The local authority here is planning on Climate Change bringing inundation despite all the evidence that the sea is retreating !!!
However, I digress. Looking further at Geologic Changes, and back to Isostacy for a moment, where two tectonic plates collide, one usually will ride over whilst the other suffers subduction. This is where we will find seismically active areas (sadly Christchurch here and many more such as Japan, China etc). We will also likely find mountain-building – as mentioned earlier, the Indian plate is still moving northward (150mm or 6” pa), and the Himalayas are still rising (5mm or 0.2” pa) – in geological terms still very active.
At the same time, the subduction zone may well create significant volcanic activity – New Zealand has its fair share.
But just about anywhere plates collide will see some degree of uplift. Again using New Zealand as an example, the main mountain range in the South Island is the Southern Alps. Current measurements show an uplift rate of about 7mm per year.
How this translates into vertical movement at either east or west coast I have been unable to determine, but it has to be happening, and ongoing.
In Wellington, the biggest recorded earthquake was a magnitude 8.2 in 1855. This uplifted the east of the City between 2 and 3 metres. Today’s airport is built on this uplifted land, and the current business district sits on reclaimed marshland exposed at that time.
Wandering along Wellington’s Lambton Quay (where boats used to dock), reveals brass plaques set into the pavement showing the shoreline in 1840 – the current Quay is about 300 metres away.
Given the magnitude of that earthquake, I suspect Wellington’s rate of uplift over larger time-intervals will be outpacing GMSL, but I could be wrong. By thesis, Cole (2010) identifies a shift in vertical position around 1944 – this following two large earthquakes in the preceding years.
There is nothing to suggest that Wellington’s upward thrust (to the east of the Wellington Fault) has ceased, so the next “big one” will likely see further uplift and hence a relative drop in Sea Level.
Local effects of Plate collisions, Isostacy rebound (eg Great lakes) etc., all serve to modify the impact of GMSL .
If we are to believe recent reports, some of the small Island Nations such as the Maldives may in fact be growing rather than being swamped under an ever-rising tide. Explain that one – I understand coral growth may be at work here but I’ve not seen anything truly convincing yet.
In other places, we are seeing true inundation but usually accompanied by more rational explanation such as pumping ground water.
So is the observed increase in GMSL of 3mm pa actually causing any significantly observable effects?
I remember the Thames Barrier being built to protect London from inundation, but that was to protect against a storm surge – where a massive low pressure system in the North Sea causes a correspondingly massive increase in local Sea Level. This is of the order of metres, not 300mm per century.
And one final question. As Cole (2010) discovered, atmospheric pressure has been falling over time.
Ill-equipped as I am to perform the calculations, is this drop in barometric pressure yet one more factor affecting the calculation for GMSL?
As I said at the start, I do not have the skills necessary to answer these and many other questions posed above – just taking a leaf out of “justthefacts” methods – and asking from you the pundits to engage and answer via group-science. Be kind for I am not as used to this medium as Anthony and other major players.
If global average atmospheric pressure is declining, then the mass of the atmosphere is declining. The only possible cause over these timescales is decreasing water vapor and condensed water (clouds).
The main atmospheric pressure decline corresponds with the main period of late 20th C warming, the mid-70s to the mid-90s. Which indicates the two phenomena have a common cause. Although the relationship breaks down in the lead up to the 1998 super El Nino and subsequently.
Decreasing atmospheric water vapor and clouds can either result from less surface evaporation (mainly ocean) or increased precipitation.
In my view the common cause is decreasing anthropogenic aerosols over this period. While aerosols are known to act as condensation nuclei they are also known to decrease precipitation efficiency and prolong cloud lifetime (see link below, table 1).
Decreasing aerosols will have decreased this effect, increasing precipitation and decreasing atmospheric mass.
As I have previous explained decreasing anthropogenic aerosols was also a significant and in all likelyhood the primary cause of the late 20th C measured warming. Thus the common cause.
http://hal-insu.archives-ouvertes.fr/docs/00/29/56/33/PDF/acp-5-715-2005.pdf
The increasing precipitation efficiency resulting from decreased aerosols will have also contributed to rising sea levels during this period.
crosspatch says:
March 3, 2012 at 5:50 pm
Crosspatch, in all the years that I’ve been reading this blog I have never read one that had me ROFLA (rolling on the floor laughing out loud). I almost fell of my chair! Thanks!
An article in the Washington Post on early artifacts.
http://www.washingtonpost.com/national/health-science/radical-theory-of-first-americans-places-stone-age-europeans-in-delmarva-20000-years-ago/2012/02/28/gIQA4mriiR_story.html?hpid=z5
It tends to provide some physical evidence for a much lower sea level during the ice age. From the article: “Lowery also contacted the Cinmar’s captain, Thurston Shawn. The tusk and blade were so unusual that Shawn had made a point of marking the spot on his charts. It was 60 miles east of the Virginia cape, in 240 feet of water. At the end of the last ice age, when the oceans were low, that spot was land, on the coast.”
Recovered in a scallop were a Mastadon tusk and an 8″ stone blade. So yes, there is at least some physical evidence or lower sea levels.
Thanks for the article
No mention of the Geoid yet? That does a nice job of complicating things still further.
Enjoy (:-
http://en.wikipedia.org/wiki/Geoid
Could it be that water vapour is gradually precipitating out of the atmosphere to lower the pressure over time? If so the liquid water will still be applying mass to the crust but more localised in rivers and lakes and spread over the ocean.
Anything is possible says: March 3, 2012 at 9:34 pm
“No mention of the Geoid yet? That does a nice job of complicating things still further.”
Yes, the geoid is the right way of defining GMSL.
Terry Jackson says:
March 3, 2012 at 9:29 pm
There are other marine finds of interest (not so deep, though):
http://www.emu.edu.tr/underwater/Symposiums/symposiums1/abstracts/marineachology.html
crosspatch says:
March 3, 2012 at 5:50 pm
Crosspatch,
That is the dumbest and funniest thing I’ve seen on these pages in quite a while. Thanks for the belly laugh! I’m glad I had just cleared a swallow of gin and tonic, before I read that….. It doesn’t feel very good when it squirts out your nostrils!
Thanks again! I needed that.
MtK
I recall at the time the Thames Barrier was built that the consensus [sorry] was, the north half of the island had been depressed by the ice caps, and was slowly tipping back towards equilibrium now that they have gone. Evidence was the white cliffs of Dover, being sort of ‘tear along the dotted line’. Also, the increasing weight of London itself (built on clay). Some places in Scotland still rise and fall with the weight of the tide.
I think a good start would be to change the name of the Planet from EARTH to BLANCMANGE.
Mean sea level atmospheric pressure is 1013mb. Cole’s graph suggests around 1008mb. Seems strange.
Andi,
A thought provoking post – Thank You!
Interesting, that Cole 20101 tidbit about decreasing atmospheric pressure. The following potential ’causes’ occur to me:
1) Atmosphere gases are being lost to space, suggesting a weakening magnetic field for earth perhaps combined with a more active sun over the time period studied.
2) Significant amounts of atmospheric gases (N2 and O2) were being extracted from the atmosphere by chemical reactions and ‘tied up’ in inorganic compounds on the planet, sufficient to reduce atmospheric pressure.
3) Water vapor in the atmosphere is decreasing over time, cause(s) unknown.
4) The Cole 2010 study is in error. Atmospheric pressure is not decreasing.
5) Crosspatch 5:05 pm knows more than he is telling!
Sincerely, Thanks for contributing!
Mtk
Warmer temperatures (UHI) might account for lower barometric pressure. Urbanized areas causing a “heat low” where rising air from urban sprawl creates more days with lower barometric pressure.
If that air then cools and settles where there doesn’t happen to be a barometer, the corresponding increase in pressure somewhere else gets missed. The areas that are most likely to have a the most barometers are also the areas most likely to have UHI impact. So I guess it is also possible to have ULPI (urban low pressure islands).
Lazy Teenager- all values need a reference point even satelites (they need lots of rf to cope with their natural motion).
I’d bet that the decrease in atmospheric pressure is related to an actual loss of atmospheric gases to space via auroral fountains and such. This might just be caused by the decreasing strength of the magnetosphere over the last 150 years or so. At least that’s what I’m thinking.
Hi Andi,
Good article! I’ve had the same ‘problem’ with sea level measurements for a long time now. It seems to be assessed as if it’s a body of water inside a pan of specified size and known bottom. In reality, it’s on the surface of a globe, and the sea floor and ‘edges of the pan’ are constantly changing. Likely more important is that it’s rising over here while it’s falling over there, many thousands of volcanoes are adding to the sea floor, erosion moving sediments into the ocean, tides and currents depositing sediments in other areas, tectonic plate movement as you noted, and so on. Then you see earthquakes such as Japan’s, where subsequently significant areas that were above high tide level now no longer are, and a large area of the sea floor is known to have significantly shifted. All of these things and others I’m sure I’ve omitted or don’t even know about are constantly ‘playing’ with the shape of the ocean basins and edges.
Look at some of the GRACE satellite renderings of the earth’s shape based on gravity – all of that must impact oceans also. It’s like the oceans are contained by silly putty walls and floor that’s constantly being warped, cracked, filled in, and so on, rather than something with a fixed shape.
I fully admit that this has been my conceptual game when it comes to sea level, however, and I haven’t taken the time to educate myself on the state of the research in this area. As a result I’ve always sort of shrugged my concerns off and accepted that the scientists studying sea level likely have some reasonably idea of how to factor in some (most? a few?) of these factors. I took that attitude even tho I’ve seen some research that was far too easy to punch holes in simply based on evaluating basic scientific method compliance or lack thereof. Of course the shenanigans occurring with ‘climate science’ have made me a bit more leery of just trusting the scientists – especially if they are actively associated with AGW type research and are only looking at sea level issues in that context.
Anyhow, that’s my two cents – I’m right there in the same boat with you just lookin’ and ponderin’ the sea level!
To: davidmhoffer says: March 3, 2012 at 7:44 pm, and Roger Carr, thanks for the levity! (if I’ve missed anyone who added to the jokes, it’s because I haven’t read all the comments yet)
re post by: crosspatch says: March 3, 2012 at 11:26 pm
Crosspatch, sorry I missed including you in the thanks for humor!
Just try saying ULPI out loud, rapidly several times in a row, folks, I dare you!
RE: John F. Hultquist says:
March 3, 2012 at 7:50 pm
“These suggest (to me) that the depression of the land mass is also very regional – that is, not depressed very far out from the terminus of the ice.”
A really neat example of this is seen in the sheer sides of Scandinavian fiords. During the tens of thousands of years the last Ice Age lasted, ice poured out from a Scandinavian ice cap (like Greenland’s) in its interior, grinding away at the rock in valleys. At any given moment the ice in these valleys weighed roughly the same, however the total weight of ice and rock did not stay the same, because you have to subtract the weight of all the rock that was ground to powder and washed out to sea. Then, because the weight of the rock was less, there was a local isostatic rebound much like the rebound you see when the weight decreases due to the melting of ice. What this means is that the rock on either side of a valley glacier is rebounding upwards even as the center of the valley is worn away and moves downwards. The more it grinds away, the higher the sides of the valley rise. In a sense a glacier builds its own retaining walls, and an icecap builds its own restraining circle of mountains.
An elegant paper on this topic is found at http://folk.uio.no/yuripo/papers/medvedev_geology_2008.pdf
Scandanavian scientists seem to produce the best work on this stuff. I assume it is because they have only to look around at their local landscape to see examples of isostacy.
As far back as the late 1700’s a Swedish geologist noted the sea seemed to be sinking in Scandinavia even as it seemed to rise in parts of Greenland. (The southern tip of Greenland was actually rising as the rest of Greenland sank, because the weight of ice towards the center pushes crust down, causing a plastic movement sideways beneath, causing a rise in the edges.)
Further north in Greenland the weight of the ice coming down the valleys, due to the Little Ice Age, was depressing the land at the foot of the valley even before the ice went that far. To me this suggests there may be evidence of Viking ports in Greenland underwater. (Send me the grant money, and I’ll send hot-blooded young scientists in wetsuits up there to scuba dive, looking just off shore in Greenland’s fiords for Viking artifacts, as I work in a warm office staffed by beautiful blonds in Olso.)
Well, that does it. We’re done.
By 132766 there will be no air left on Earth.
@Lazy teenager
when water warms, it expands. are you sure about that ?
when ice melts it flows into the sea. are you sure about that ?
A change in atmospheric pressure of 1 mbar equals about 1 cm difference in SL. See this bit from the Jason2 Data Products Handbook
5.10.1. Inverted Barometer Correction
As atmospheric pressure increases and decreases, the sea surface tends to respond hydrostatically, falling or rising respectively. Generally, a 1-mbar increase in atmospheric pressure depresses the sea surface by about 1 cm. This effect is referred to as the inverse barometer (IB) effect.
The instantaneous IB effect on sea surface height in millimeters (see parameter inv_bar_corr) is
computed from the surface atmospheric pressure, Patm in mbar:
inv_bar_corr = -9.948 ∗ (Patm – P)
where P is the time varying mean of the global surface atmospheric pressure over the oceans.
The scale factor 9.948 is based on the empirical value [Wunsch, 1972] of the IB response at mid
latitudes. Some researchers use other values. Note that the surface atmospheric pressure is also
proportional to the dry tropospheric correction, and so the parameter inv_bar_corr approximately
changes by 4 to 5 mm as model_dry_tropo_corr changes by 1 mm (assuming a constant mean global surface pressure). The uncertainty of the ECMWF atmospheric pressure products is somewhat dependent on location. Typical errors vary from 1 mbar in the northern Atlantic Ocean to a few mbars in the southern Pacific Ocean. A 1-mbar error in pressure translates into a 10 mm error in the computation of the IB effect.
Note that the time varying mean global pressure over the oceans, P, during the first eight years of
the T/P mission had a mean value of approximately 1010.9 mbar, with an annual variation around
this mean of approximately 0.6 mbar. However, the T/P data products provided a static inverse
barometer correction referenced to a constant mean pressure of 1013.3 mbar.
In regard to the Geoid, here’s one map. Note the scale.
http://en.wikipedia.org/wiki/File:Geoid_height_red_blue_averagebw.png
Erm, doesn’t The ideal gas law have something to say about falling pressure and it’s effect on the temperature of a gas? Anyhoo, I would have thought that with our vast knowledge and teraflops of computing power, we could have a damn good stab at working out the volume of water in the oceans instead of using a surrogate like global sea level.
I guess there are more questions here that we’re unable to answer. Oh sure we have our hypotheses, but these are mere guesses, and nature shows over and over again that things are different.
One problem for instance is that the theoretical ice volume that would have to match the sea level lowering (ca 130 meters) during the Last Glacial Maximum, can’t be matched on land, without violating some observations somewhere. It used to be on Siberia, until it was discovered that there was no ice at all. Meanwhile it has been revealed that Antarctica did not really have a lot more ice during the Last Glacial Maximum. So now we are looking at a gigantic American Ice Sheet of 4-6 kilometers thick, that must have accumulated in a mere 100,000 years, while the 3km thick and fast accumulating ice sheet of Greenland took at least 200,000 years. So where-ever you want to put that ice, you’re violating something one way or another.
But do we know how mantle slab movements modify the sea level and what about a pulsating earth, the equatorial bulge growing and shrinking?
http://beyondprophecy.blogspot.com/2010/05/equatorial-bulge-growing.html
I think that we are not even in the infancy of understanding what’s going on with Earth, deep below our feet and what it did to sea levels in the past.
In regard to the difference between satellite observations and tidal gauges see this map
http://www.aviso.oceanobs.com/fileadmin/images/news/indic/msl/MSL_Map_MERGED_Global_IB_RWT_NoGIA_Adjust.png
It shows the MSL trends from Oct 1992 to Jul 2011. Note the large red orange blob north and east of Australia. the sats indicate this area has experienced sea level rise of 9-12mm/yr for the entire nearly two decade period. Now consider this story
http://www.theaustralian.com.au/national-affairs/sea-level-rises-are-slowing-tidal-gauge-records-show/story-fn59niix-1226099350056
Tidal gauges that are pretty much cheek by jowl with the area the sats claim as having about the fastest rising SL on the planet show not much happening