Guest essay by Ross McKitrick University of Guelph
June 4, 2015
UPDATED June 8 2015: Some changes and corrections noted in red. Also added MAT records and Kent figure 18
Background
The idea that there has been a hiatus in global warming since the late 1990s comes from examination of several different data sets:
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HadCRUT(land surface + ocean) |
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HadSST(ocean surface only) |
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NCDC(land surface + ocean) |
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GISS(land surface + ocean) |
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RSS(lower troposphere) |
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UAH(lower troposphere) |
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Ocean Heat Content (0-2000m)Argo floats (black line)NOAA SST est’s (red solid and dashed lines) |
(Added Fig 14 above) Marine Air Temperatures by latitude band
Black: HadNMAT2
Red: HadMAT1
Green: MOHMAT4
Blue: HadSST3
Light blue: C20R
Sources: all data accessed through http://www.climate4you.com/GlobalTemperatures.htm except last one, taken from http://www.nature.com/nclimate/journal/v5/n3/full/nclimate2513.html.
The IPCC’s recent report identified this hiatus and commented as follows (Working Group I, Chapter 9, Box 9.2):
The observed global-mean surface temperature (GMST) has shown a much smaller increasing linear trend over the past 15 years than over the past 30 to 60 years… Depending on the observational data set, the GMST trend over 1998–2012 is estimated to be around one-third to one-half of the trend over 1951–2012.
K15 New Estimates
Karl et al. (2015, which I’ll call K15) have struck a very different note, saying that the post-1998 trend is much higher than previously thought, and is in fact about the same as that of the post-1951 interval. Their trend estimate revisions are as follows:
The big source of the change is an upward revision (+0.06 oC /decade) to the global post-1998 Sea Surface Temperature (SST) trend, with only a small change to the land trend:
LAND OCEAN
So what changed in the SST records? Bear in mind that there are very relatively few records of air temperatures over the oceans, especially outside of shipping lanes and prior to 1950. So to get long term climate estimates, scientists use SST (i.e. water temperature) data, which have been collected since the 1800s by ships. The long term SST records were never collected for climate analysis and they are notoriously difficult to work with. Many judgments need to be made to yield a final record, and as the K15article shows, changes in some of those assumptions yield major changes in the final results.
A Primer on SST Data
There is a large literature on methods to derive a consistent climate record from the SST archives. The contribution of K15 is to take one such record, called the Extended Reconstructed Sea Surface Temperature version 4 (ERSSTv4), and use it to compute a new global climate record. The difference in recent trends they report is due to the changes between ERSST versions 3b and 4.
Almost all historical SST products are derived from the International Comprehensive Ocean-Atmosphere Data Set (ICOADS, http://icoads.noaa.gov/) or one of its predecessors. ICOADS combines about 125 million SST records from ship logs and a further 60 million readings from buoys and other sources.[1] A large contributor to the ICOADS archive is the UK Marine Data Bank. Other historical sources include navies, merchant marines, container shipping firms, buoy networks, etc.
SST data have historically been collected using different methods:[2]
· Wooden buckets were thrown over the side, filled with seawater and hauled on deck, then a thermometer was placed in the water;
· Same, using canvas buckets;
· Same, using insulated buckets;
· Automated temperature readings of Engine Room Intake (ERI) water drawn in to cool the ship engines;
· Ship hull temperature sensors;
· Drifting and moored buoys.
In addition, there are archives of Marine Air Temperature (MAT) taken by ships that have meteorological equipment on deck.
Here are some of the problems that scientists have to grapple with to construct consistent temperature records from these collections:
· Ships mainly travel in shipping lanes, and vast areas of the oceans (especially in the Southern Hemisphere) have never[3] been monitored;
· Sailors are not inclined to take bucket readings during storms or perilous conditions;
· Readings were not necessarily taken at the same time each day;
· During the process of hauling the water up to the deck the temperature of the sample may change;
· The change will be different depending on how tall the ship is, whether the bucket is wood or canvas, whether it is insulated, and how quickly the reading is taken;
· The ERI intake may be just below the surface in a small ship or as much as 15 m below the surface in a large ship;
· Similarly the hull sensors may be at widely-varying depths and may be subject to temperature effects over time as the engines heat up the hull;
· MAT readings are taken at the height of the deck, and modern ships are much taller than older ones, so the instruments are not at the same height above sea level;
· Buoys tend to provide readings closer to the water surface than ERI data;
· There were not many surface buoys in the world’s oceans prior to the 1970s, but there are many more now being averaged in to the mix.
Now add to these challenges that when data is placed in the archive, in about half the cases people did not record which method was used to take the sample (Hirahari et al. 2014). In some cases they noted that, for example, ERI readings were obtained but they not indicate the depth. Or they might not record the height of the ship when the MAT reading is taken. And so forth.
Ships and buoys are referred to as in situ measurements. Since in situ data have never covered the entire ocean, most groups use satellite records, which are available after 1978, to interpolate over unmonitored regions. Infrared data from the Advanced Very High Resolution Radiometer (AVHRR) system can measure SST accurately but need to be calibrated to existing SST records, and can be unreliable in the presence of low cloud cover or heavy aerosol levels. In the past few years, new satellite platforms (Tropical Rainfall Measuring Mission or TRMM, and the Advanced Microwave Scanning Radiometer or AMSR-E) have enabled more accurate data collection through cloud and aerosol conditions.
Hadley, GISS and Hirahara et al. (2014)[4] all use satellite data to improve interpolation estimates over data-sparse regions. The ERSST team (i.e. K15) did prior to version 3b but doesn’t anymore, due to their concerns about its accuracy.
The Three Main ERSSTv4 Adjustments
The measurement problems mentioned above all well-known. A great deal of work has been done in recent decades both to try and recover some of the metadata for in situ temperature readings, and also to estimate corrections in order to overcome biases that affect the raw data. K15 have made some relatively minor changes to the bias correction methods, and the result is a large increase in the post-1998 trend.
A. They added 0.12 oC to readings collected by buoys, ostensibly to make them comparable to readings collected by ships. As the authors note, buoy readings represent a rising fraction of observations over recent decades, so this boosts the apparent warming trend.
B. They also gave buoy data extra weight in the computations.
C. They also made adjustments to post-1941 data collected from ships, in particular a large cooling adjustment applied to readings over 1998-2000.
Taken together these changes largely explain the enhanced trend over the past 15 years. So now everybody needs to decide if they think these adjustments are valid.
Perhaps they are. The main problem for us observers is that other teams have looked at the same issues and come to different conclusions. And the post-1998 K15 data don’t match that from other independent sources, including weather satellites.
A. Looking at the first adjustment, K15 take the buoy data and add 0.12 oC to each observation. They computed that number by looking at places where both buoy data and ship data were collected in the same places, and they found the ship data on average was warmer by 0.12 oC. So they added that to the buoy data. This is similar to the amount estimate found by another teams, though the bias is usually attributed to ships rather than buoys:
Recent SST observations are conducted primarily by drifting buoys deployed in the global oceans (Figs. 1, 2). The buoys measure SST directly without moving seawater onto deck or to the inside of a ship. Therefore, buoy observations are thought to be more accurate than either bucket or ERI data… In the present study, we regard this difference as a bias in the ERI measurements, and no biases in drifting buoy observations are assumed. The mean ERI bias of +0.13 oC is obtained and is within the range for the global region listed in Table 5 of
Kennedy et al. (2011).
(quote from Hirahari et al. 2014 p. 61)
That quote refers to a paper by Kennedy et al. (2011 Table 5)[5] which reports a mean bias of +0.12 oC. However, Kennedy et al. also note that the estimate estimated bias in each location is very uncertain: it is 0.12 
oC ! Also In other words, the bias varies quite a bit by region. This is a key difference between the method of K15 and that of others. K15 added 0.12 oC to all buoy data, but the Hadley group and the Hirahari group use region-specific adjustments while the Hirahari group modify the bias adjustment for the estimated time-varying fraction of insulated versus uninsulated buckets.
B. There is not much detail about this step. K15 simply say that because the buoy data are believed to be more reliable, they were given more weight in the statistical procedure, and “This resulted in more warming.” Steps A + B accounted for just under half of the additional warming.
C. It has been noted by others previously that SST data from ships shows a more rapid warming trend than nearby air temperature collected by buoys (Christy et al. 2001).[6] K15 compute an adjustment to SST data based on comparisons to Nighttime MAT (NMAT) records from a data set called HadNMAT2. This step entailed making a large cooling adjustment to the ship records in the years 1998-2000. K15 say that this accounts for about half the new warming in their data set. They defended it by saying that it brought the ship records in line with the NMAT data. However, this particular step has been considered before by Kennedy et al. and Hirahara et al., who opted for alternative methods that did not rely exclusively on NMAT, instead making use of more complete metadata, perhaps in part because, as Kennedy et al. and others have pointed out, the NMAT data have their own “pervasive systematic errors”,[7] some of which were mentioned above. So rather than using a mechanical formula based solely on NMAT data, other teams have gone into great detail to look at available metadata for each measurement type and have made corrections based on the specific systems and sites involved.
Numerical Example
Here is a simple numerical example to show how these assumptions can cause important changes to the results. Suppose we have SST data from two sources: ships and buoys. Suppose also that ships always overestimate temperature by exactly 1 degree C and buoys always underestimate it by exactly 1 degree C. We have one set of readings every 10 years, and we are not sure what fraction is from ships versus buoys. Both ships and buoys accurately measure the underlying trend, which is a warming of 0.1 oC /decade from 1900 to 1990 then no trend thereafter.
The Table below shows the simulated numbers. Suppose the true fraction of ships in the sample starts at 95% in 1900 and goes down by 8% every decade, ending at 7% in 2010.
| Year | Buoy | Ship | True Ship % | True Avg |
| 1900 | 2.00 | 4.00 | 0.95 | 3.00 |
| 1910 | 2.10 | 4.10 | 0.87 | 3.10 |
| 1920 | 2.20 | 4.20 | 0.79 | 3.20 |
| 1930 | 2.30 | 4.30 | 0.71 | 3.30 |
| 1940 | 2.40 | 4.40 | 0.63 | 3.40 |
| 1950 | 2.50 | 4.50 | 0.55 | 3.50 |
| 1960 | 2.60 | 4.60 | 0.47 | 3.60 |
| 1970 | 2.70 | 4.70 | 0.39 | 3.70 |
| 1980 | 2.80 | 4.80 | 0.31 | 3.80 |
| 1990 | 2.90 | 4.90 | 0.23 | 3.90 |
| 2000 | 2.90 | 4.90 | 0.15 | 3.90 |
| 2010 | 2.90 | 4.90 | 0.07 | 3.90 |
The true average is calculated using the weight in the True Ship % column, adding 1 oC to the buoy data and subtracting 1 oC from the ship data. The result is shown in the graph:
The thin black and gray lines are the ship (top) and buoy (bottom) data, while the thick black line in the middle is the true average.
But now suppose we don’t know what the correct adjustment is for the buoy data or the ship data, and we don’t know the True Ship % figures either. We will estimate the global average as follows:
· Adjust the buoy data up by +2 oC every year (a bit too much)
· Adjust the ship data down by 1 oC every year (the right amount)
· After 1940 we will also apply a cooling adjustment to the ship data that starts at -0.25 oC and goes up by that amount every decade
· We further cool the ship data by 1 oC in 1990 and 2000 only
· We estimate the ship %, starting it at 99% in 1900 (a bit high) and reducing that by 7% every decade (a bit too little) up to 1990, at which point we observe the True Ship % and follow it exactly thereafter.
Before looking at the results, ask yourself if you think these adjustments will make much difference.
| Year | Buoy | Buoy adj | Ship | Ship Adj | True Ship% | True Avg | Est Ship % | Est Avg |
| 1900 | 2.00 | 2.00 | 4.00 | -1.00 | 0.95 | 3.00 | 0.99 | 3.01 |
| 1910 | 2.10 | 2.00 | 4.10 | -1.00 | 0.87 | 3.10 | 0.92 | 3.18 |
| 1920 | 2.20 | 2.00 | 4.20 | -1.00 | 0.79 | 3.20 | 0.85 | 3.35 |
| 1930 | 2.30 | 2.00 | 4.30 | -1.00 | 0.71 | 3.30 | 0.78 | 3.52 |
| 1940 | 2.40 | 2.00 | 4.40 | -1.25 | 0.63 | 3.40 | 0.71 | 3.51 |
| 1950 | 2.50 | 2.00 | 4.50 | -1.50 | 0.55 | 3.50 | 0.64 | 3.54 |
| 1960 | 2.60 | 2.00 | 4.60 | -1.75 | 0.47 | 3.60 | 0.57 | 3.60 |
| 1970 | 2.70 | 2.00 | 4.70 | -2.00 | 0.39 | 3.70 | 0.50 | 3.70 |
| 1980 | 2.80 | 2.00 | 4.80 | -2.25 | 0.31 | 3.80 | 0.43 | 3.83 |
| 1990 | 2.90 | 2.00 | 4.90 | -3.50 | 0.23 | 3.90 | 0.23 | 4.10 |
| 2000 | 2.90 | 2.00 | 4.90 | -3.75 | 0.15 | 3.90 | 0.15 | 4.34 |
| 2010 | 2.90 | 2.00 | 4.90 | -3.00 | 0.07 | 3.90 | 0.07 | 4.69 |
The new estimated average is the red dashed line.
The fit is not bad up to 1990, but the accumulated effect of all the small mistakes is the artificial trend introduced at the end of the series. At this point we would hope to have some independent data on the post-1990 trend to compare the result to in order to decide if our methods and assumptions were reasonable.
This example proves nothing about K15, of course, except that small changes in assumptions about how to deal with uncertainties in the data can have a large effect on the final results. But that was already clear because the K15 themselves explain that their new assumptions—not new observations—are what introduced the warming trend at the end of their data set.
Conclusion
Are the new K15 adjustments correct? Obviously it is not for me to say – this is something that needs to be debated by specialists in the field. But I make the following observations:
· All the underlying data (NMAT, ship, buoy, etc) have inherent problems and many teams have struggled with how to work with them over the years
· The HadNMAT2 data are sparse and incomplete. K15 take the position that forcing the ship data to line up with this dataset makes them more reliable. This is not a position other teams have adopted, including the group that developed the HadNMAT2 data itself. BTW, if you are interested, the global HadNMAT2 temperature anomaly is the black line in the figure below. The data series ends in 2010.
(Added above)(Kent, et al (2013), Global analysis of night marine air temperature and its uncertainty since 1835 1880: The HadNMAT2 data set, J. Geophys. Res. Atmos., 118, 1281–1298, 1836 doi:10.1002/jgrd.50152)
· It is very odd that a cooling adjustment to SST records in 1998-2000 should have such a big effect on the global trend, namely wiping out a hiatus that is seen in so many other data sets, especially since other teams have not found reason to make such an adjustment.
· The outlier results in the K15 data might mean everyone else is missing something, or it might simply mean that the new K15 adjustments are invalid.
It will be interesting to watch the specialists in the field sort this question out in the coming months.
Ross McKitrick
Department of Economics
University of Guelph
rossmckitrick.com
[1] Woodruff, S.D., H. F. Diaz, S. J. Worley, R. W. Reynolds, and S. J. Lubker, (2005). “Early ship observational data and ICOADS.” Climatic Change, 73, 169–194.
[2] See http://www.metoffice.gov.uk/hadobs/hadsst3/Kennedy_2013_submitted.pdf for a review.
[3] Rayner, N. A., D. E. Parker, E. B. Horton, C. K. Folland, L. V. Alexander, D. P. Rowell, E. C. Kent, and A. Kaplan, (2003): Global analyses of sea surface temperature, sea ice, and night marine air temperature since the late nineteenth century. Journal of Geophysical Research, 108(D14), 4407, doi:10.1029/2002JD002670.
[4] Hirahara, S. et al. Centennial-Scale Sea Surface Temperature Analysis and Its Uncertainty, Journal of Climate Vol 27 DOI: 10.1175/JCLI-D-12-00837.1
[5] http://www.metoffice.gov.uk/hadobs/hadsst3/part_2_figinline.pdf
[6] Christy, John R., David E. Parker, Simon J. Brown, et al. 2001 Differential trends in tropical sea surface and atmospheric temperatures since 1979. Geophysical Research Letters 28, no. 1
[7] http://www.metoffice.gov.uk/hadobs/hadsst3/Kennedy_2013_submitted.pdf page 28.
If the buoy data is the best then what trend does it show by itself? If that data by itself shows the pause then clearly the claims from Karl et al are wrong. Has anyone looked at this data separated from the ship data?
It seems that the latest alarmist strategy for misleading the public is to blame on man all extreme climate events , even if they are only slightly bigger than the one they have personal knowledge of. They claim that the extra rainfall, floods, storms, heat waves, cold waves, hurricanes, sea level changes, snowfall, etc., are all due to man induced global warming or climate change. Now they are proposing to change the figures to do away with the pause in global temperature increases.
Yet according to the US government’s own climate data, the observable data does not support this claim. Why not? Very simple, there is little global warming happening in North America during the last 10 years. NOAA own climate data shows that for 34 out of 48 sates or 70 % of the states in Contiguous US, the trend of annual temperature anomalies is declining at 0.69F/decade . Only 8 Pacific coast states, including the Northwest, West and Southwest and 6 Northeast states show warming. A similar pattern appears in Canada where 7 out of 11 climate regions show declining annual temperature departures since 1998, one is flat and 3 show warming from the 1961-1990 base. In other words 73 % of Canadian climate regions are also not experiencing global warming. Only the Pacific and Atlantic and the High Arctic regions show warming in North America and this is because they are being moderated by the oceans or ENSO events. Even in the Canadian far north including Tundra, Fiords and Mountains there has been a 6 degree drop in temperatures since 2010
So this fabricated notion that somehow this falsely reported warming climate of North American continent is caused by man and that this is somehow making more extreme weather events and making them worse is pure nonsense espoused by those who cannot explain temperature pause or that increased carbon dioxide levels have only a very minor impact on our North American climate, which is completely opposite to the AGW flawed theory
This is exactly what the surface data shows, the warming was due to changes in where the oceans stored it’s collection of warm water, altering the jet stream, which changed the daily minimum temp surface temps where most of the surface stations are, then when you add the ~18F daily temp increase, it got warmer than it did previously, and now we’re in the process of it switching back.
On average then, Canada is cooling. Waterloo hasn’t warmed in one hundred years.
Some (very basic) questions:
1. If a bucket is tossed overboard then brought back and the temperature of the water measured, the temperature being measured is presumably at or close to the surface. How much difference in temperature is there between surface temperature and the temperature at the inlet for cooling water for the engine(s)?
2. Has anyone ever measured how much difference in temperature there is between the water in the bucket and the temperature where the bucket collected its sample?
3. What is the precision of the thermometers inserted into the buckets? of the thermometers at the cooling-water inlets?
Ian M
I think other comments touched on your question, Ian.
What time of day was it? The profile of the near surface waters changes at night.
Was the air cooler or hotter than the water, and by how much? If we do not know the air temp, we cannot guess how much and how quickly the water will change temp in the bucket.
These measurements are so haphazard they are worthless for estimating global temperature.
There are known and unknown sources of error. Massaging such data in some carefully contrived way can obviously give any result one might wish to achieve.
I see not one hint that the method given in this new paper is in any way empirical.
In fact, it seems to be a particularly ham-handed effort to decide what he result needs to be, and then doing what it takes to get that result.
Finally……A massage with a happy ending! 😉
Can I just interject the loathing of this paper (and rightful loathing it is too) with a bit of realism? The FACT is that warming IS continuing, it is! It’s just nothing, nothing at all like we were told it would be. I know Moncky boy likes to use RSS, but if you choose HadCRUt4, the warming IS continuing.
http://www.woodfortrees.org/plot/hadcrut4gl/from:1998/plot/hadcrut4gl/from:1998/trend:1998
Until that warming stops, and it actually starts cooling (which I think it will), then we don’t have much of a case. And we are in danger of pissing on our own chips if asked to justify the ‘pause’. 21st century warming is still on an upward trajectory. UAH shows this too.
http://www.woodfortrees.org/plot/uah/from:1998/plot/uah/from:1998/trend:1998
We are missing a trick here. PLEASE, people, we should be banging on about the IPCC’s projections, and how far out they were/are. We should be arguing that spending trillions is unnecessary and futile – howsoever the warming is caused.
WHEN, and only when, the 21st century shows a downward trend, then we should set up a fund to pay for full-page advertisements in all the big global dailys, with a simple graph and a footnote, telling the public that they are being conned by their own governments, and by silent scientists. But I say again, the FACT is that warming IS continuing…it simply is. Deal with it. Let’s just wait, and watch.
Oh what fun! I just love to play games with an online etch- a- sketch. See what I’ve made? I looked at RSS for the past decade and blew your conjecture out of the lower troposphere (or did I?)
http://www.woodfortrees.org/plot/rss/from:2005/plot/rss/from:2005/trend:2005
Here are some more pretty RSS graphs, clearly showing cooling at a increasing rate since 1997.
http://www.woodfortrees.org/plot/rss/from:1997/trend/plot/rss/from:1990/plot/rss/from:2001/trend
Incidentally, your UAH data is out of date, the latest release is much closer to RSS.
http://www.drroyspencer.com/2015/04/version-6-0-of-the-uah-temperature-dataset-released-new-lt-trend-0-11-cdecade/
Did you have anything besides ad hom, cherry-picking, shouting and handwaving?
Thought not.
I am running some of the historical temperatures since 1900, and I’m coming up with a much different answer. First of all, I added more weight to the 1900s era thermometers that were in hot springs in Yellowstone, then in the 2000s data I added more weight to the thermometers in Alaska. The results are shocking.
The planet went from an average temperature of 89C (unlivable, imo) in 1900 to -15C in 2014 (also unlivable). If this cooling trend keeps up, we’re all gonna die!
I think it pretty clear that Karl and his team started with the result, and worked backwards from there. This is science at its very worst.
Frankly, I do NOT trust NOAA to give us the truth because as a government agency, they are now forced to advance government policy rather than be an honest broker. Bear in mind, the shrillness of climate alarmists is increasing as we approach a Paris climate treaty meeting and they realize it is likely to be another failure.
I find it peculiar that NOAA also wants to take on the IPCC which is what climate skeptics do.
Somehow, this doesn’t pass the smell test, but I could be wrong.
During 1993-1996, I was New Jersey State Sea Grant Director. NOAA’s Marine Fisheries Services (NMFS- Now NOAA Fisheries) was housed in the building next door. During their off-hours, NMFS scientists were involved with the activist movement promoting certain pro-environmental issues. When speaking publicly, they identified themselves as NMFS Scientists (giving the impression NIMFS supported that particular environmental agenda item), which at the time was contrary to policy that allowed government employees to speak as citizens but not as representatives of their employer/agency
If we look at the chart AMO, it is seen that the temperature difference exceeds 0.5 degree. At minimum of the sun the temperature drops even lower. Europe and Northeast US should be to prepare for 30 years a significant cool down.
http://woodfortrees.org/graph/esrl-amo/from:1950/to:1980/trend/plot/esrl-amo/from:1980/to:2010/trend/plot/esrl-amo/from:2010/trend/plot/esrl-amo/from:1950
“Looking at the first adjustment, K15 take the buoy data and add 0.12 oC to each observation. They computed that number by looking at places where both buoy data and ship data were collected in the same places, and they found the ship data on average was warmer by 0.12 oC. So they added that to the buoy data. This is similar to the amount estimate found by another teams, though the bias is usually attributed to ships rather than buoys:”
‘places where both buoy data and ship data were collected in the same places,”
Don’t tell me there is another spaghetti graph involved which may hide the decline.
I wonder if (Un)Real Climate will be brazen enough to have a puff-piece about this wonderful paper?
0.1 deg.C./Decade (period of 60 years) = 0.00167 deg.C./year = 0.00000456 deg.C./day = 0 deg.C for each day of the last 60 years, on average.
Congratulations Karl, you have just shown that there has been no measurable change, on average, in global temperature for the last 60 years on a daily basis. What an accomplishment!
Surely you are discussing with your NOAA supervisor a plan for you to retire and return to your office the next day by becoming a consultant with a $250,000 yearly salary plus your retirement money, paid in bi-weekly increments.
Ha ha
‘- this is something that needs to be debated by specialists in the field.’
____
reminds on banks specialists manipulating the libor:
Libor – “London Inter-Bank Offer Rate” – but there are also the EU’s Euribor, China’s Shibor and Japan’s Tibor.
____
in the case of libor there where huge fines on concerned banks.
In Climate Science seemingly anything goes / is allowed.
Regards – Hans
atmosphere is comprised 0.04% CO2 from all causes- man’s contribution is 3.4% of that 0.04%- meaning the content of CO2 I nthe atmosphere from man is just 0.00137% of the atmosphere- Can someone pelase explain to me how just 0.00137% of our atmosphere can be ‘almost entirely responsible for climate change’? How can 0.00137% of our atmosphere possibly capture enough ir molecules to back radiate them to cause global climate change? What % of that 0.00137% even actually gets back radiated I nthe ‘right’ direction back to earth? As I understand it, absorbed heat molecules get radiate out in ALL directions, meaning that only a fractio nof that is captured even makes it way back in the ‘right’ direction to earth
Ross writes:”That quote refers to a paper by Kennedy et al. (2011 Table 5)[5] which reports a mean bias of +0.12 C. However, Kennedy et al. also note that the estimate is very uncertain: it is 0.12 +/- 1.7C ! ”
Here Ross is referring to the standard deviation of the individual values, but what we’re interested in is the error of the sample mean. Per Kennedy et al’s Table 5 the standard error of the mean is +/- 0.02C.
It should also be noted that whether one decreases engine intake values or increases buoy data the trend result is the same.
Ross also states that the Hirahari group used region-specific adjustments; this is incorrect. Hirahari et al specifically say: “The biases appear to vary regionally and seasonally with large biases in the Central North Pacific and the southern oceans. However, sampling data are insufficient to attribute the features to the ERI bias. Thus, only the global mean bias is used. So though they note regional variability, they used the global mean.
I also find it troubling that Ross can quote Hirahari to cast aspersions on the use of NMAT data, when Hirahari says – IN THE SENTENCE IMMEDIATELY FOLLOWING THE PORTION ROSS QUOTED – “The use of NMAT to adjust SST data is, to an extent, unavoidable as the heat loss from a bucket does depend on the air-sea temperature difference.
Being polite is not a substitute for being correct. This post has too many errors to be of any real use.
Your quote about use of NMAT being unavoidable is not in Hirahari at all, much less IN! THE! SENTENCE! IMMEDIATELY! FOLLOWING!!!!!!!! it is in Kennedy et al. In any case I wasn’t trying to cast aspersions on NMAT, I was pointing out that other teams use metadata rather than relying exclusively on a mechanical NMAT-based adjustment. As for the error bar, the uncertainty of site-specific adjustments are indicated by the SD, not the SE of the mean.
When the history of the 20th century is written, the names Tom Karl and Sepp Blatter will be mentioned in the same sentence as examples of the same contemporary phenomenon, the workings of organisations that were untouchable political totems “too big to fail”, blindly trusted until discovered to be riddled to the core by corruption and dishonesty. Ten million dollars was the going rate for a world cup, and is probaby also about the price on a result-U-like paper like Karl et al. 2015, served up as an hors d’oevre for the Paris carve up of political and tax-raising power.
“The IPCC’s statement of two years ago – that the global surface temperature ‘has shown a much smaller increasing linear trend over the past 15 years than over the past 30 to 60 years’ – is no longer valid,” said Dr Karl, the director of Noaa’s National Climatic Data Center.
This all looks and smells like a political contrivance, as opposed to science. In fact it looks and smells very similar to a well-known situation from many years ago. When “stories” woven by the Nixon White House relative to the Watergate break-in began to unravel, reporters started to bore in to the White House spokesman, Ronald Ziegler. His response became quite famous.
To Quote from the NYT:
… on April 17, 1973, Nixon stunned reporters by saying that he had conducted an investigation that raised the prospect of involvement by White House officials.
Mr. Ziegler told a puzzled press corps that this was now the ”operative statement,” repeating the word operative six times. Finally, R. W. Apple Jr. of The New York Times asked, ”Would it be fair for us to infer, since what the president said today is now considered the operative statement, to quote you, that the other statement is no longer operative, that it is now inoperative?”
Eventually Mr. Ziegler replied: ”The president refers to the fact that there is new material; therefore, this is the operative statement. The others are inoperative.
From The Nation; The Nondenial Denier
By TODD S. PURDUM
Published in the NYT, February 16, 2003
Fortunately, the IPCC had very high confidence in the science then, and Karl has very high confidence now. So even if the story changes again tomorrow we can all sleep well knowing that the confidence level will always be high;)