Image Credit: Bob Tisdale – bobtisdale.wordpress.com
By WUWT Regular Just The Facts
The recent Adjustments/Corrections to the HadCRUT4 and CRUTEM4 Temperature Data Sets by the Met Office Hadley Centre and Climatic Research Unit got me thinking about the cumulative impact of Adjustments/Corrections on our temperature records. Bob Tisdale then triggered the first vein of this analysis when he recently produced and provided the graph above, which compares the ICOADS (International Comprehensive Ocean-Atmosphere Data Set) v2.5 data set to HadSST3, HADISST and ERSST.v3b. ICOADS is the original unadulterated Sea Surface Temperature record. HadSST3, HADISST and ERSST.v3b, all include adjusted/corrected ICOADS data, e.g.:
[Note: Bold and non-link underlines below are mine. I am testing out a new three speed review approach, i.e. if you really want to know it, read it all, if you want an overview, read the underlines and non italics, if you want the key concepts, read the bold and non italics. Please let me know in comments if this approach works for you.]
HadSST3 The SST data are taken from version 2.5 of the International Comprehensive Ocean-Atmosphere Data Set, ICOADS (external web page), from 1850 to 2006 and on GTS observations from 2007 onwards. HadSST3 is produced (a slightly more detailed description) by taking in-situ measurements of SST from ships and buoys, rejecting measurements that fail quality checks, converting the measurements to anomalies by subtracting climatological values from the measurements, and calculating a robust average of the resulting anomalies on a 5° by 5° degree monthly grid. After gridding the anomalies, bias adjustments are applied to reduce the effects of spurious trends caused by changes in SST measuring practices. The uncertainties due to under-sampling and measurement error have been calculated for the gridded monthly data as have the uncertainties on the bias adjustments following the procedures described in the paper.
The HadSST3 page references this paper “Improved Analyses of Changes and Uncertainties in Sea Surface Temperature Measured In Situ since the Mid-Nineteenth Century: The HadSST2 Dataset“, Rayner, et al., 2005, as the basis for their adjustments/corrections. It states within that:
a. Bias correction and its uncertainties Seawater has been sampled for temperature measurement on board ship by various different means at different times. This change from using insulated (wooden) to uninsulated (canvas) to partly insulated (rubber) buckets, engine room intakes, and hull sensors, along with changes in ships speeds, has introduced changing relative biases into the database. Folland and Parker (1995) developed corrections to be applied to SST data between 1856 and 1941 to ameliorate the effect of these changes and to bring the older data into line with data from the modern mix of measurement methods. For details of the development of these corrections, the reader is referred to Folland and Parker (1995).
Here’s Parker, Folland, M. Jackson (1995) paper MARINE SURFACE TEMPERATURE: OBSERVED VARIATIONS AND DATA REQUIREMENTS Here are some of the adjustments/corrections detailed within:
“Overall global warming in SST between the 1860s and the 1970s is about 0.3 °C greater in the present analysis than in Folland et al. (1984), mainly owing toreduced early corrections applicable under the assumption of the predominant use of wooden buckets (Section 3).”
“The largest, positive corrections are in early winter (December) over the Gulf Stream and the Kuroshio, where warm water, cold dry air, and strong winds cause rapid evaporative heat loss from the buckets. The corrections approach 1 °C by 1940 in these regions in early winter. Corrections are also large (around 0.4 °C to 0.5 °C by 1940) in all seasons in the tropics because of the high rate of evaporation when SST is high. Some negative corrections are made in mid latitudes in summer, mainly where the mean air temperature around the bucket exceeds the mean SST.”
Here’s their Figure 7, which shows the impact of their adjustments/corrections.
“How do we know that these corrections are trustworthy? The agreement of SST anomalies with largely independently corrected NMAT anomalies (Section 7 and Figure 7) is the strongest support to the results, and suggests that the impacts of future refinements and reduction of uncertainties in this area will be small.”
So who do you think provided the “largely independently corrected NMAT” SST anomalies, which are “the strongest support to the results”? Wait for it…
“Folland et al. (1984) applied corrections to NMAT to compensate for the historical increases of the average height of ship’s decks. These rose from about 6 m before 1890 to 15 m by the 1930s and 17 m by the 1980s. The corrections, based on surface layer similarity theory, removed a spurious cooling of about 0.2 °C between the late nineteenth century and 1980. On the other hand, Jones et al. (1986) used anomalies (not actual values) of regional, mainly coastal, land surface air temperature to adjust anomalies of nearby MAT. This was possible because anomalies of MAT and nearby ‘coastal’ land surface air temperature are found to be similar in recent data over periods as long as a decade, even though the absolute values differ considerably. However, because Jones et al. (1986) used COADS summaries, they were unable to separate NMAT from day MAT which are affected by historically varying, on-deck solar heating: their corrections therefore differed from those of Folland et al. (1984). In both these early studies, about 0.5 °C was subtracted from MAT for 1942-5, a period of non-standard measurement practices owing to war. “
Yes, that Jones et al. (1986) reference is Phil Jones, and Tom Wigley too, at the Climatic Research Unit (CRU), University of East Anglia (UEA). And it turns out that Rayner, Folland and Parker all worked at the Hadley Centre, Met Office.
This 1992 Jones and Wigley paper “Corrections to Pre-1941 SST Measurements for Studies of Long-Term Changes in SSTs” appears to be a seminal work in the development of Sea Surface Temperature record adjustments/corrections:
Many factors can influence a sea surface temperature reading (Barnett, 1985; Jones et al., 1986; Bottomley et al., 1990; Jones et al., 1991). Some of these introduce random errors while others result in systematic, non- cancelling errors. The most important factor is the method of collecting the sample, with the two basic methods being to haul a sample on deck with a bucket, or to measure the temperature of the intake water used for engine cooling. Here, we are concerned with bucket measurements. These are affected by the kind of bucket used, the exposure of and physical conditions surrounding the bucket, how long the bucket was left before reading the thermometer, and ship speed.
In COADS we do not have detailed information concerning the methods of measurement, nor any indication of what method was used for the individual readings that make up the data. There is,nevertheless, strong evidence that readings before 1940 were predominantly bucket measurements, while those since 1945 were predominantly intake measurements (Jones et al., 1986). Furthermore, it is likely that the major difference between the data for these two periods is the non-climatic bias due to the evaporative cooling of the canvas bucket, an effect which would clearly cause pre-1940 data to be cooler than post-1945 data (Jones et al., 1991).
In order to derive correction factors for the bucket-derived temperatures, we have modified the model developed by Folland and Hsiung, 1987 and Bottomley et al., 1990, to estimate the cooling of an uninsulated canvas bucket. The main difference between our work and that of Folland and Hsiung (1987) is that we have solved the governing equations analytically. This makes application of the model less demanding computationally, and it allows us to perform a variety of analyses.
2. The bucket model
If you have not already, you really should take a look at Section 2. “The Bucket Model” within Jones and Wigley’s 1992 paper, as it is a classic work in gibberish…
Continuing…
4. Correcting SSTs using the bucket approach
4.1 Optimum exposure time
For 1905-40, SSTs may be corrected using the evaporating bucket model. Although average ship speed probably varied over this period, within the range of likely values ship speed does not noticeably affect the implied exposure time. We have used a ship speed of 7ms-1. Wind speeds of 60% of the anemometer speed produce slightly better results than the 40% reduction case, and lead to slightly lower optimum exposure times (by less than 1 minute on average) so we have used this value. As the most likely exposure time lies in the range 3-6 minutes, we use 4 1/2 minutes in making final corrections.”
“4.2 The final correction factors
Final correction factors depend on the location, month and year. These variations are summarized in Figures 3 to 5. Correction factors vary slightly from year to year depending on coverage changes. Figure 3 shows mean correction factors for the Northern Hemisphere. Southern Hemisphere mean corrections are shown in Figure 4. The transition from small corrections in the early decades to larger corrections after 1905 is due to the change from wooden (i.e., better insulated and assumed to require no correction) to un-insulated buckets. Correction factors are largest in the winter half year. Northern Hemisphere corrections show slightly larger season-to-season variations. Figure 5 shows how the “winter” (JFM) and “summer” (JAS) – using Northern Hemisphere seasonal labels – corrections vary with latitude. Correction factors are lower in higher latitudes in general, particularly in the 45-75°N band where the “summer” corrections are near zero.”
It appears that the Team that brought us Climategate, was hard at work adjusting/correcting the Sea Surface Temperature record back in the 80s and 90s…
Here Jones and Briffa team up to summarize the purported basis of the Sea Surface Temperature record adjustments/corrections in their paper, “Global Surface Air Temperature Variations During the Twentieth Century: Part 1, Spatial, Temporal and Seasonal Details“, P. D. Jones and K. R. Briffa, 1992.
“Problems with the homogeneity of sea surface temperature (SST) data arise due to differences in the method of sampling the sea water. Before the second world war the sea water was collected in an uninsulated canvas bucket. There was a delay of a few minutes between sampling and measuring the temperature. During this time the water in the bucket generally cooled slightly by evaporative means. Since the second world War most readings have been made in the intake pipes through which sea water is taken onboard ships to cool the engines. This change in measurement technique was quite abrupt at around 1941, although there are still significant numbers of bucket measurements (using plastic and thus better insulated buckets) made today and some intake measurements were made prior to the second world war.
Comparative studies of the two methods indicate that bucket temperatures are cooler by 0.3-0.7″C (James and Fox, 1972). Correcting the SST data for this measurement change may seem, at first, seem an intractable problem. Folland and Parker (1990; 1991) of the UK Meteorological Office, how- ever, have developed a method for correcting the canvas bucket measurements based on physical principles related to the causes of the cooling. The cooling depends on the prevailing meteorological conditions, and so varies according to the time of year and location. Although the cooling is therefore a day-to-day phenomenon, the various influences are basically linear, so cooling amounts can be calculated on a monthly basis. The main free parameter is the elapsed time between sampling and reading. This is generally unknown and must be estimated from the data. The primary assumption in this estimation is that there have been no major changes in the seasonal cycle of SSTs over the period of record. Since the amount of evaporative cooling has a strong seasonal cycle in many parts of the world, an optimum exposure time can be chosen; namely that which minimizes the residual seasonal cycle in the corrected data.As a check on the validity of the method, the implied optimum exposure time turns out to be quite consistent spatially (see Jones and Wigley, 1990; Jones et al., 1991 for more details).
The major problem with the technique is that it is not known with any certainty what types of buckets were used to take measurements during the nineteenth century. Assuming canvas buckets rather than wooden buckets (which are better insulated) leads to corrections which infer SSTs warmer than land temperatures by about 0.2″C. The discrepancy almost disappears if wooden buckets are assumed. Although there is documentary evidence to support wooden bucket use during the mid-nineteenth century, considerable doubt remains about the transition from wooden to canvas buckets. The seasonal-cycle elimination method is not precise enough to choose between the two possibilities. The corrections used here have been derived using the wooden bucket assumption in the nineteenth century (see Jones et al., 1991 for details).
“The major problem with the technique” and “The Bucket Model” are that they rely upon an array of assumptions and estimations, which are based on very limited empirical data, and were made by people like Phil Jones and Tom Wigley, who have apparent biases, and appear to have been working the propagate the Catastrophic Anthropogenic Global Warming narrative since the early eighties. It is interesting to note that the Jones et al. papers on Sea Surface temperature adjustments/corrections do not appear listed within the otherwise quite encompassing collection of Jones’ work on the UEA website.
Steve McIntyre has written extensively about bucket adjustments starting back in 2005, i.e. Changing Adjustments to 19th Century SST;
You may recognize Folland as a major IPCC author (Folland et al. [2001] is sometimes the citation). SST sampling is not homogeneous – it changed from buckets to engine inlets – engine inlet temperature ran a little hotter. Both canvas and wooden buckets appear to have been used. There are millions of SST measurements and how the measurement was done is not known for most measurements (as far as I can tell.) There are two main adjustments in Folland et al. The first is a one-time adjustment for from buckets to engine inlets in December 1941. This is premised on a comparison between the “corrected” NMAT temperature [ I haven’t checked what these “corrections” are] and the uncorrected SST temperatures.
Buckets and Engines, The Team and Pearl Harbor, Bucket Adjustments: More Bilge from RealClimate, Rasmus, the Chevalier and Bucket Adjustments, Did Canada switch from Engine Inlets in 1926 Back to Buckets?;
CA readers are aware that I discussed bucket adjustments on a number of occasions long before Thompson et al 2008, in particular, questioning the absurd IPCC assumption that all SST measurements switched from buckets to engine inlet on the day after Pearl Harbour. In March 2007, a year before Thompson et al 2007, in light of new historical information bucket usage, I provided a scoping estimate of the potential impact of a different changeover scenario, based on then-just-published Kent et al 2007. The direction of the impact is precisely the same as that shown in the present HadCRU estimates over 4 years later. The difference between the two appears to be that the present HadCRU estimate assumes that bucket changeover impact has ended by 1970, while, in my 2007 post (based on Kent’s evidence of widespread bucket usage in the 1970s), I presumed that the changeover continued until the 1990s.”
and HadSST3;
A new HadSST3 version has been recently published. It starts the process of unwinding Folland’s erroneous Pearl Harbour bucket adjustment, an adjustment that has been embedded in HadSST for nearly 20 years.
Folland’s erroneous adjustment had been originally criticized at CA in 2005 here and further discussed at length in March 2007 at CA here, a post in which I observed that no climate scientist had made any attempt to validate Folland’s bizarre adjustment and that correcting Folland’s error (through a more gradual and later changeover to engine inlets than the worldwide overnight change that Folland had postulated after Pearl Harbour) would have the effect of increasing SST in the 1950s, in turn, potentially eliminating or substantially mitigating the downturn in the 1950s that was problematic for modelers.]
However, not until Thompson et al 2008 (submitted Jan 2008; published May 2008) was the problem with the Folland adjustment clearly acknowledged by the “community”. The importance of Thompson et al in resolving the problems arising from the Folland adjustment were credited by Susan Solomon and Phil Jones in the commentary accompanying the Nature article.) Both lead author David Thompson and co-author Mike Wallace, though very prominent climate scientists, had negligible (or no) publishing history on the topic; as one commenter at James Annan’s blog put it, they came out of “left field”. Thompson was an ozone specialist. The other co-authors, John Kennedy of the Hadley Center and Phil Jones of CRU, were, of course, actively involved in the field.
Now over three years later, in a new SST edition (HadSST3), the Hadley Center has accepted and implemented Thompson et al’s criticism of Folland’s Pearl Harbour adjustment. Instead of implementing an overnight changeover to engine inlets in December 1941 as before, the changeover is now phased in through the mid-1970s. This results in changes to SSTs between 1941 and ~1975.
However, Steve does not appear to have dug too far into the pre-1945 adjustment/correction highlighted by Bob Tisdale’s graph.
One piece of this puzzle I can’t seem to find is the oft cited Bottomley et al., i.e.: Bottomley, M., C. K. Folland, J. Hsiung, R. E. Newell, and D. E. Parker, 1990: Global Ocean Surface Temperature Atlas. MIT Press, 20 pp. plus 313 plates. According to the Global Ocean Surface Temperature Atlas GOSTA:
This is the January 1993 version of the Global Ocean Surface Temperature Atlas (GOSTA) (Bottomley et al., 1990) referred to as ATLAS7 or MOHSST5. The data in this atlas are a compilation of marine observations from the United Kingdom Meteorological Office Main Marine Data Bank with some additional data from the US Fleet Numerical Oceanography Center. The Atlas includes the climatology of sea surface temperature (SST) and the difference between marine nighttime air temperature (NMAT) and SST. These climatologies are based on data collected between 1951 and 1980. Also included are SST and NMAT monthly anomalies from 1856 to 1991. The data were corrected to remove what are believed to be observational biases due to changes in instrumentation. These correction are based on scientific research summarized in the introduction to the hard-copy version of GOSTA (Bottomley et al., 1990). All data are presented on a 5 by 5 degree grid wherever data existed. The climatology of SST can be made available on a 1 by 1 degree grid.
The quality of marine observations is thoroughly discussed in the hard copy volume of GOSTA as well as in the references therein. The user should note that the data were collected using a variety of instruments and observational procedures aboard vessels of different shapes and dimensions.
Here is the GOSTA data, however I would like to see the “scientific research summarized in the introduction to the hard-copy version of GOSTA (Bottomley et al., 1990).” to understands what those adjustments/corrections are based on, but even Google Scholar comes up dry.
If anyone can find an electronic copy of Bottomley et al., 1990 and/or can offer additional information on the adjustments/corrections made to the to the Sea Surface record, please post them in comments.
jeez says: May 25, 2013 at 3:02 pm
Apparently the electronic version of Bottomley et al seems to the version known as GOSTAplus which was a CD Rom.
Perhaps you can get it from here: http://badc.nerc.ac.uk/view/badc.nerc.ac.uk__ATOM__dataent_GOSTA
Wow:
It is probably worth requesting a copy of the data just to see what the Met Office does…
The link below may be helpful as well.
http://badc.nerc.ac.uk/data/gosta/paper3.html
Yep, more Bottomley references:
A lot of people mistakenly consider that ships make sea surface temperature measurements, they do not. Further, it is extremely dangerous to start comparing data sets obtained from differing methodology.
Whenever sea temperatures are taken (whether by bucket, engine intake, or ARGO buoy) one is not measuring the same stretch of water. Measurments may be taken in broadly similar positions but sea temperature can vary quite substantially over relatively short distances. There is never a like for like comparison. That is one issue, and the splicing together of these 3 data sets is another issue. They should be seen as 3 distinct data sets, and no attempt should be made to splice them together.
Bucket measurements are rife with errors inherent in the procedure. So too, the more recent method which relies upon water temperature measurements taken at the engine inlet. Let me explain.
The water which is used for engine cooloing purposes is drawn from the water inlet which is positioned low down on the keel. Its vertical position from the foot of the keel and from the vesseel’s water line varies from ship to ship.
Each ship has differing displacement and centres of buoyancy, and the vertical distance from the water line to the foot of the keel varies from ship to ship. The size of the ship and the maximum draught at which a ship may operate is dependent upon its design and configuration. Many readers might have heard of common ship clases such as Panamax (the maximum size of ship that can transit the Panama canal), or Suezmax (the maximum size of a ship that can transit the Suez canal). There are numerous classes of vessels and the fully laden maximum draught of these vessels can vary from between say about 6m through to 25m. However, it is important to bear in mind that there are many factors that will impact upon what draught a vessel may be sailing at at any moment in time, and this is frequently not its maximum draught.
Ships are commercially traded assets and as they are operated their gross deadweight and buoyancy varies from voyage to voyage. Indeed, it is constantly varying during the performance of a voyage (as there are changes to consumables, ballasting and the amount of cargo being carried).
Some times a vessel will be sailing in ballast (free of cargo), sometimes partly laden (eg., say 10%, or 20%. or 30% etc full of cargo), and other times she will be sailing fully laden. All of this has a significant impact as to the draught that a vessel draws. This in turn impacts upon the depth at which sea water is drawn for engine cooling purposes.
This variatuion is also added to by the amount of consumables on board, such as fresh water, bunkers, general stores (this could vary from a hundred to a few thousand tonnes). This variation is further added to by the manner in which the Master may decide to trim the vessel. Vessels are trimmed partly by the manner in which cargo is loaded but also specifically by way of water ballast which ballast is stored in tanks located at different parts of the ship, some of which are low down, some of which are high up, some are located to fore whilst other to the aft). Vessels are usually trimmed by the stern (this gives better steerage amongst other operational considerations), and the trimming of vessels (and indeed the same vessel from voayage to voyage) can vary considerably, eg., from say 20 or so cm to the stern, to 2 to 4m to the stern. This in turn also impacts upon the depth at which sea water is drawn for engine cooling purposes.
The draught of a vessel can also be impacted upon by squat, which is a phenomena which may alter the depth at which a vessel sits according to its speed (no doubt many have heard of sailing vessel’s planing, and this is a similar, but reverse effect, which may occur to large ships. With squat, a vessel can be forced to draw a deeper draught than she would do if not moving.
The upshot of the above is that SHIPS DO NOT MEASURE SEA SURFACE TEMPERATURE, but instead measure sea water temperature drawn at depth. This depth can vary from between about 3m to 23m. This is not an insignificant variation.
Is there such a thing as an average ship? Personally, I would say no. Is there such a thing as a typical voyage? Again, I would have to say no. There may well be a typical type of ballast voayage for a particular class of ship, and a particular laden voyage for a particular class of ship, but there is no such thing as a typical voayage when one takes account of all the differening types of vessels which are plying trade world wide.
With the above cavat in mind, I guess that ships are typically recodfing their logs sea water temperatures by way of measuring sea water temperatures drawn at a depth of between 7 to 14m below the surface.
Of course, ships are not conducted scientific surveys (well very few are) and one should not consider measurements taken by them as being taken by employing the scientific mathod. For eample, how well calibrated is the temperature guage? Further, commercial considerations may imact upon details recorded in the ship’s logs. The operation of ships is rife with legal claims. Indeed, it may well be the case that nearly every voayage will give rise to legal claims (the vast majority of which are settled amicably). But it is important to bear this fact in mind. Owner/operators of ship’s potentially face claims for underperformance, eg., time lost due to slow steaming, or failure to properly heat cargo making it more difficult to dischagere, or the overconsumption of bunkers etc. Now I would not wish to say this is common practice in the shipping industry but there may be a temptation for some owner/operatiors to record exagerated data in the logs, eg., to portray weather conditions more severe than they truly were, or to claim that a current is more adverse or less favorable than it truly was, or that more or less fuel was being consumed than truly was the case. This practice can also apply to sea water temperature. Vessle’s sometimes carry heated cargoes. It is expensive to heat cargoes. The need to heat a cargo will depend upon the characteristics of the cargo being carried but also on ambient sea water temperature and length of voyage. A ship may wish to claim that the sea water was cooler than it actually was so that it may legitimately claim for the use of bunkers for heating the cargo at an earlier point of time and for a longer period. If the ship’s engine is not well maintained and prone to over heating, it may wish to claim that the ambient sea water was warmer than it truly was. So there may be commercial considerations which may tempt the less honest ship owner/operator to incorrectly declare (either upwards or downwardfs) the sea water temperature throughout the voyage.
I have little doubt that it is all but impossible to make the required adjustment of water temperatures taken by one ship to those taken by another ship, and from day to day dependent upon how the ship in question is on that day being operated.
Sea water temperatures taken by ships should be seen as a guide of a ball park figure, but not as an exact science. They are not.scientific. One cannot compare bucket measurents with water inlet measurements with ARGO measurements.
The 10th para of my above comment should have read:
The upshot of the above is that SHIPS DO NOT MEASURE SEA SURFACE TEMPERATURE, but instead measure sea water temperature drawn at depth. This depth can vary from between about 3m to 23m. This is not an insignificant variation.
[Reply: Fixed. Now folks won’t need to count 10 paragraphs 😉 -ModE ]
Tonyb says: May 25, 2013 at 3:56 pm
the take home message is that other than a very few well travelled sea routes which might provide a small amount of useful information, the SST data prior to 1950 is not worth wasting time on if you are looking for data sufficiently robust to use in policy making decisions
I would actually argue that the data after 1950 isn’t much better, especially as it relates to “well traveled sea routes”. For making policy decisions we probably shouldn’t use anything prior to November, 2007 when the deployment of Argo was completed…
Tonyb says:
May 25, 2013 at 3:56 pm
As I pointed out in my post at 2.33 and as Alan s Blue pointed out at 3.31pm the methodology is so flawed and the margin of error so great that worrying about the use of an insulated or non insulated bucket is akin to angels dancing on the heads of pins
. the take home message is that other than a very few well travelled sea routes which might provide a small amount of useful information, the SST data prior to 1950 is not worth wasting time on if you are looking for data sufficiently robust to use in policy making decisions
Tonyb
//////////////////////////
I fully concur with your comment.
I have some 30 years experience in the shipping industry, and the same can be said about the post 1950 data. See my comment of 5:21 pm which is not an exhaustive list of the problems, but hopefully it gives a flavour of the more obvious short comings with the data, namely that ships are reporting sea water temperatures taken at depths vary from a few metres through to 23 metres, they are not providing sea surfasce temperture.
If ship’s were all drawing sea water temperature at the same depth, and accurately reporting this, the ship’s data would be useful. However, ship’s are not taking measurments at the same depth and therefore one is not compiling data of like for like measurements.
Further, biases creep in. The average size of a ship today, is not the same as that of 10 years ago, or that of 20 years ago etc. As new markets open up the distribution of tonnage alters to meet that market.
justthefactswuwt says:
May 25, 2013 at 5:39 pm
/////////////////////////////////////////////////
justthefactswuwt
Your comment of 5:39pm crossed with my comment of 5:41pm.
You might be interested in my comment of 5:21pm. You will see why I consider that the data post 1950 is problematic and should not be relied upon.
The number of buoys deployed in ARGO is wholly insufficient to get a proper handle on sea water temperature, and the data set is way too short. If ocean cycles are in the region of 60 years, 60 years of data would be required as a minimum.
Further, we do not know what biases may be creeping into ARGO. These are free drifting voyages. They drift with currents. Temperature is a factor in currents. because of the drfiting nature of ARGO, the potential for it to acquire a temperature bias (whether this be warm or cool) is probably substantial. Much analysis would be required to see whether such a bias is creeping in, and we are not even begiinning to acquire the data required to carry out such an assessment.
All 3 data sets are problematic and have issues. Definitely, there should be no attempt to splice. They should be seen as seperate and ndependent data sets revealing what they each individually reveal. The challenge, is to assess the error margins which are large with the first 2 data sets, and the third data set is presently way to short to draw any firm conclusion.
It may not be too late for some crowd-sourcing research on the bucket-sampling. Most of the senior mariners would be gone by now, but there might be a few young’uns left who drew the short straw and got the job. I obtained a few responses that had a good match to something John L. Daly wrote on the subject.
Examples? Laughter usually, plus: “I doubt if it was ever done right”; “It was a punishment job like cleaning out the heads”; “Bring the f****** thing in here and shut the door” [during freezing gale] …
Bob Tisdale says: May 25, 2013 at 3:01 pm
Bob Tisdale – bobtisdale.wordpress.com – Click the pic to view at source[/caption]
thanks for using one of my graphs. It’s Figure 15 from the following post:
http://bobtisdale.wordpress.com/2013/05/14/multidecadal-variations-and-sea-surface-temperature-reconstructions/
Thank you for creating it.
I followed that illustration with a comparison of the source ICOADS marine air temperature data and the adjusted MOHMAT night marine air temperature data, which was used for the early adjustment:
http://bobtisdale.files.wordpress.com/2013/05/figure-16.png
[caption id="" align="alignnone" width="850"]
Now here’s a graph that’s similar to the one you presented in your post, but in this one, I’ve replaced the Hadley Centre’s night marine air temperature data with the source ICOADS marine air temperature data. It gives you a better idea of what they did to come up with the current sea surface temperature data during the sketchy period before the 1940s:
Bob Tisdale – bobtisdale.wordpress.com – Click the pic to view at source[/caption]
http://i41.tinypic.com/91mkbt.jpg
[caption id="" align="alignnone" width="850"]
They spent a tremendous amount of time and energy adjusting/correcting the pre-1940s Sea Surface Temperature data set, and the result does not improve our understanding of the historic record at all. It appears that adjustments/corrections made to the pre-1940s data were not a scientific undertaking, but rather.an optics exercise to assure that the Sea Surface Temperature record would conform to the CAGW narrative.
Steve McIntyre says: May 25, 2013 at 3:51 pm
You mention some past CA posts on bucket adjustments, but the list of CA posts in incomplete and omits some commentary on earlier bucket adjustments. The combination of the arbitrariness of the early adjustments and the motivatedness of the adjusters were definitely dig-heres. See also http://climateaudit.org/2005/06/19/19th-century-sst-adjustments/; http://climateaudit.org/2005/06/24/sst-adjustment-2/. and http://climateaudit.org/category/sst/.
Yes, its the arbitrariness, motivatedness, and as you note below, incestuousness:
Justthefacts,
You appear to have missed the link the the CDRom help files I posted above. It looks like this may be the electronic equivalent of the paper you are seeking.
kadaka (KD Knoebel) says: May 25, 2013 at 3:41 pm
It appears to be incorporated into the December 1991 issue of the International Journal of Climatology, available from Wiley for an unknown price:
http://onlinelibrary.wiley.com/doi/10.1002/joc.3370110810/abstract
Global Ocean Surface Temperature Atlas (Gosta) M. Bottomley, C. K. Folland, J. Hsiung, R. E. Newell and D. E. Parker, Meteorological Office (Bracknell) and Massachusetts Institute of Technology, 1990. No. of Pages: iv + 20; No. of plates: 313
That is only a “Book Review” of Bottomley et al., 1990, by “P. D. Jones i.e.:
So Bottomley et al., 1990 was “published during 1990 as a result of funding through the Intergovernmental Panel on Climate Change (IPCC)”. Now I really want a copy of it…
“Bottomley et al. (1990) used two less accurate heat transfer models. Both assumed a wall thickness of 1 cm and somewhat smaller bucket dimensions. Model A assumed completely insulated walls and base with a free-water surface at the bucket rim; model B imposed a linear temperature profile through the walls and base as the calculation proceeded. Model B overestimated heat transfer by at least a factor of two while model A slightly underestimated heat transfer. Bottomley et al. weighted models A and B in the ratio 3:1 respectively.”
ftp://podaac.jpl.nasa.gov/allData/gosta_plus/retired/L2/hdf/docs/papers/1-crrt/1-CRRT.HTM
Yes, there are several tantalizing Bottomley et al. (1990) details in that paper, e.g.:
Enjoy.
Thank you
jeez responded per CDROM here:
http://wattsupwiththat.com/2013/05/25/historical-sea-surface-temperature-adjustmentscorrections-aka-the-bucket-model/#comment-1316608
Still considering how to address the Met Office’s “Restricted Data Access” policy, and I suspect that they’ll provide a copy of the data and not a copy of the paper. If I didn’t think I might be supporting some hard up Warmist, I might go with the Amazon option…
If only for a laugh, It’s worth looking at a bit of written history highlighting another problem with bucket (or any other) SST measurements – an obscure little story from an Australian newspaper in November 1899 (http://trove.nla.gov.au/ndp/del/article/82145577) …
One of the remarkable natural phenomena at sea in the North Atlantic is the sharp demarcation of the Gulf Stream, flowing north along the east coast of the United States, carrying with it the heat of equatorial suns, and the Labrador current, flowing south from the Arctic regions. In his pilot chart one hydrographer gives an excellent description of this line of demarcation by quotations from the reports of captains of war vessels of the English navy, in which it is stated that temperatures of 40deg to 60deg were taken within a few yards of each other. It is recorded that in one instance – between Halifax and Bermuda – a vessel had 70deg at the bow and 40deg at the stern, or a difference of 30deg, in the sea-surface temperature in a short ship’s length.
I will never trust the older spot sea surface temperature record. The NH Land series is easily the best “approximation” that we will ever have for 19th Century “Global” estimates. Anything else is guess work.
Yet again the “adjustments” are for tenths of a degree. I doubt that the original recorded temperatures were recorded to a tenth of a degree so the adjustment are based on a spurious level of accuracy. Designed, I suspect, to “prove” the “right answer.”
Justthefacts
As already mentioned the splitting of hairs by angels whilst they simultaneously dance on the heads of pins means the bucket data from Bottomley will do nothing to materially alter the inherent mistakes and huge margin of error in the original bucket reading. However the met office library and archives are extremely helpful in my opinion and I use them regularly for my own research as they are situated only 15 miles from my home.
They do send out material by email if its not too large, so if you really want to pursue this, here is their email address.
Met Office Library & Archive; here is the full address
Mark Beswick Archive Information Officer, Met Office National Meteorological Archive
Great Moor House Bittern Road Sowton Exeter EX2 7NL United Kingdom
Tel: +44 (0)1392 360987 Fax: +44 (0)1392 885681
E-mail: mark.beswick@metoffice.gov.uk Website: http://www.metoffice.gov.uk
If the Bottomley document is in the library itself as a book or paper I can have a look at it for you next time I am there, but you would need to ascertain via email that it is physically available at either library or archive for personal viewing. The two facilities are several hundred yards apart. You would need to tell me precisely what information from the document you seek
tonyb
David Jones says:
May 26, 2013 at 12:01 am
Yet again the “adjustments” are for tenths of a degree. I doubt that the original recorded temperatures were recorded to a tenth of a degree so the adjustment are based on a spurious level of accuracy. Designed, I suspect, to “prove” the “right answer.”
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I can confirm that sea water temperature is measured and recorded to tenths of a degree. Of course, whether the measuremnent is accurate to such is a different matter.
I have mentioned some of the problems. One should not overlook that engine rooms are usually quite hot and the engine itself will conduct heat to the manifold where the measurement is made. This may have a slight impact on water temperature measurements since water manifold condiations may be influenced by such conditions. Again there will be variations from ship to ship.
I did not mention previously but perhaps I should have clarified that ships usually record details every 4 hours unless there are operational requirments that demand more specific monitoring. The spped of vessels varies greatly, say from perhaps around 9 knots to over 20 knots per hour. Around 12 to 13 knots is fairly typical for a general cargo ship so a vessel may typically be sampling water temperatures about every 50 nautical miles of its sea voyage. Many oceans are very well sampled, but all depends upon popular trading routes.
The only sense in this entire report lies in the comments of Mr. Scuba-Diver!
Just The Facts,
It appears that the CD Rom contains these datasets.
http://iridl.ldeo.columbia.edu/SOURCES/.GOSTA/
Plus this documentation.
http://badc.nerc.ac.uk/data/gosta/atlas7help.html
Is everything that is on the CD.
I don’t think you’ll find anything else, but it would be worth it to see what obstacles you may or may not encounter from the Met Office.
The main free parameter is the elapsed time between sampling and reading. This is generally unknown and must be estimated from the data.
They’re going to modify the data based upon an unknown paramter estimated from the data?
As a scuba diver myself, I concur with profitup10
justthefactswuwt says:
”They spent a tremendous amount of time and energy adjusting/correcting the pre-1940s Sea Surface Temperature data set, and the result does not improve our understanding of the historic record at all. It appears that adjustments/corrections made to the pre-1940s data were not a scientific undertaking, but rather.an optics exercise to assure that the Sea Surface Temperature record would conform to the CAGW narrative.”
Can we elaborate on how the adjustments make the data appear to conform better to the CAGW narrative?
From a chemistry perspective that sharp increase in the 1940’s that is sustained in the raw data combined with Henry’s law is evidence that at least a portion of the increase in atmospheric CO2 is from decreased dissolution rate of the ocean.
Also if I recall correctly, the sunspot number peaks were increasing during the time frame that the raw data shows increasing temperatures (1940’s) providing evidence of solar influence that is missing in the adjusted data.
Are there others?
I think we can all agree that the error bars on measurements predating the ARGO era are about as wide as the wake of the ships by which they were taken, which renders them pretty much useless since the error is much bigger than any kind of signal hidden in the data.
Kaboom says:
May 26, 2013 at 6:28 am
I think we can all agree that the error bars on measurements predating the ARGO era are about as wide as the wake of the ships by which they were taken, which renders them pretty much useless since the error is much bigger than any kind of signal hidden in the data.
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Hmmm… wide error bars- yes, but unwise to view Argo as other than an incrementally improved data source, considering known issues with current drift, etc. ignoring pre- Argo data would be as great an error as ignoring paleo- climate data, for instance. We’ve a fine enough handle on the pre- Argo data to be able to spot and account for anomalies such as was induced during WWII.
I agree strongly with several previous comments along the lines that the proper way to handle the data, in the absence of a clear, correctable bias, is to treat them as separate records with appropriately large error bars.