Evidence that Global Temperature Trends Have Been Overstated
Dr. Pielke has a new paper, and asked if I’d help “get the word out” I’m happy to oblige – Anthony
Guest post by Dr. Roger Pielke Jr
The paper is important for two reasons. First, it provides confirmatory evidence that the globe has indeed been warming over the period of the satellite records. Indeed the argument that we make in the paper depends upon the presence of a warming trend, Second, it provides a parsimonious and logical explanation for a discrepancy observed in the temperature record that has been often highlighted but which to date been unsatisfactorily explained.
For several years my father has been talking about the possibility of a “warm bias” in the surface temperature record.
We begin our paper by noting a well-documented and puzzling discrepancy in global atmospheric temperature measurements:
Since 1979, when satellite observations of global atmospheric temperature became available, trends in thermometer-estimated surface warming have been larger than trends in the lower troposphere estimated from satellites and radiosondes as discussed in a recent Climate Change Science Program (CCSP) report [Karl et al., 2006]. Santer et al. [2005] presented three possible explanations for this divergence: i) an artifact resulting from the data quality of the surface, satellite and/or radiosonde observations; ii) a real difference due to natural internal variability and/or external forcings; or iii) a portion of the difference is due to the spatial coverage differences between the satellite and surface temperature data. Santer et al. [2005] focused on the second and third explanations, finding them insufficient to fully explain the divergence. They suggest in conclusion that, among other possible explanations, “A nonsignificant trend differential would also occur if the surface warming had been overestimated by 0.05°C per decade in the IPCC data.”
We call the discrepancy between trends observed at the surface and those in the lower troposphere a “divergence” meaning that they are behaving differently. In 2006 the Climate Change Science Program discussed this divergence and found the issue to be “still open.” Our paper conducts an investigation of the neglected first hypothesis proposed by Santer et al. (2005) as follows:
[W]e consider the possible existence of a warm bias in the surface temperature trend analyses using the following two hypotheses related to the divergence between the surface and lower tropospheric temperature records since 1979:
1. If there is no warm bias in the surface temperature trends, then there should not be an increasing divergence with time between the tropospheric and surface temperature anomalies [Karl et al., 2006]. The difference between lower troposphere and surface anomalies should not be greater over land areas.
2. If there is no warm bias in the surface temperature trends, then the divergence should not be larger for both maximum and minimum temperatures at high latitude land locations in the winter.
We conclude that the first explanation offered by Santer et al. [2005] provides the most parsimonious explanation for the divergence between surface and lower troposphere temperature trends, based on recent research suggestive of biases in the surface temperature record. Our findings suggest that the supposed reconciliation of differences between surface and satellite datasets [Karl et al., 2006] has not occurred.
What do we find?
First, we explain why it is that there is evidence of a “warm bias” in the global temperature record. It has to do with how surface temperatures used to calculate long-term trends are constructed – by averaging daily maximum and minimum temperatures combined with the effects of what are called “atmospheric boundary layer processes” on minimum temperatures. In the paper we provide a review of this well-understood area of meteorology. This discussion is somewhat complex and technical, but it is also well-supported and should be non-controversial.
We argue that:
Because the land surface temperature record does in fact combine temperature minimum and maximum temperature measurements, where there has been a reduction in nighttime cooling due to this disruption, the long-term temperature record will have a warm bias. The warm bias will represent an increase in measured temperature due to a local redistribution of heat, however it will not represent an increase in the accumulation of heat in the deep atmosphere. The reduction in nighttime cooling that leads to this bias may indeed be the result of human interference in the climate system (i.e., local effects of increasing greenhouse gases, surface conditions, aerosols or human effects on cloud cover), but through a causal mechanism distinct from the large-scale radiative effects of greenhouse gases.
It is important to underscore that our hypothesis depends upon (a) the presence of a real warming trend, and (b) (to some extent) an increase in greenhouse gases. So if you accept our arguments, then you necessarily are accepting the presence of a warming trend and corresponding increases in greenhouse gases. This too should be non-controversial, but I want to be clear to avoid any possible misinterpretations.
So then let’s look at the data. We use surface data from the Hadley Center in the UK and NOAA in the US, and for satellite data we use the UAH and the RSS datasets. We analyze the data over land and ocean. The figures below show the differences between the surface temperature records and the satellite records for the period 1979 to 2008. Also shown is the difference that would be expected based on the results of a number of climate model runs as presented by the CCSP (i.e., the values from the models are from the CCSP). Clearly there is a visual divergence represented as a increase in the differences over time as well as a visual difference between what has been observed and what the models suggest should be expected.
Figure 1. NCDC minus UAH lower troposphere (blue line) and NCDC minus RSS lower troposphere (green line) annual land temperature differences over the period from 1979-2008. The expected anomaly difference given the model amplification lapse rate factor of 1.2 is also provided. All differences are normalized so that the difference in 1979 is zero.
Figure 2. CRUTEM3v minus UAH lower troposphere (blue line) and CRUTEM3v minus RSS lower troposphere (green line) annual land temperature differences over the period from 1979-2008. The expected anomaly difference given the model amplification lapse rate factor of 1.2 is also provided. All differences are normalized so that the difference in 1979 is zero.
What is really interesting is that the divergence that we observe is statistically significant in 3 of 4 cases over land (that is, NCDC minus UAH, NCDC minus RSS, Hadley minus UAH) but not in any of the cases over the ocean, which is exactly what we’d expect in the presence of a warm bias in the land surface temperature measurements. We think as well that we can explain why there is not a statistically significant difference over land between Hadley and RSS, and this is discussed in the paper.
We then take the analysis a step further:
The warm bias in the temperature data would most likely be in evidence over land areas where larger vertical temperature stratification occurs near the ground along with a reduction of the atmospheric cooling rate. This effect will be largest in the higher latitudes, especially in minimum temperatures during the winter months, since any reduction in the cooling rate of the of the atmosphere will result in a particularly large temperature increase near the ground surface in this strongly stably stratified boundary layer.
So we look at the higher latitudes and find that:
… the northern polar areas have received considerably more warming in the boreal winter with regards to minimum temperatures than with regards to maximum temperatures. The reader should be careful in interpreting these results, however, since the 95% confidence intervals for maximum and minimum temperatures in the polar areas during the winter months is quite large. The trend in minimum temperatures in northern polar areas is statistically significantly greater than the trend in maximum temperature at the 95% level during the winter months. This is consistent with the findings reported in Pielke and Matsui [2005], Pielke et al. [2007] and Lin et al. [2007] of a warm bias in the global analysis of surface temperature trends. This is also consistent with the view that column climate sensitivity is dependent on the depth of the boundary layer [Esau, 2008]. At higher latitudes, boundary layer depths are in general lower and more stable and thus heat is distributed over a shallower layer making the proportional response greater. This leads to more warming at the surface than aloft and thus is not indicative of heat accumulation in the deep atmosphere.
So we believe that we have demonstrated compelling evidence for the presence of a warm bias in global temperature trends that may indeed be reflective of a human influence on the climate system, but is not due to the accumulation of heat in the system. The obvious conclusion from this result, should it be correct and hold up, is that the effects of carbon dioxide on global temperature trends may have been overstated in past assessments by some amount.
Again, this does not mean that increasing carbon dioxide is not a problem, nor does it mean that efforts to decarbonize the economy do not make sense. Our paper has not led me to alter the climate mitigation and adaptation policies that I advocate one bit. It does mean that there remains plenty of questions to ask and answers to find – some perhaps surprising – about the relationship of human activities and the global earth system.
Here is how we conclude our paper:
We find that there have, in general, been larger linear trends in surface temperature datasets such as the NCDC and HadCRUTv3 surface datasets when compared with the UAH and RSS lower tropospheric datasets, especially over land areas. This variation in trends is also confirmed by the larger temperature anomalies that have been reported for near surface air temperatures (e.g., Zorita et al., 2008; Chase et al., 2006; 2008, Connolley, 2008). The differences between surface and satellite datasets tend to be largest over land areas, indicating that there may still be some contamination due to various aspects of land surface change, atmospheric aerosols and the tendency of shallow boundary layers to warm at a greater rate [Lin et al., 2007; Esau, 2008; Christy et al., 2009]. Trends in minimum temperatures in northern polar areas are statistically significantly greater than the trends in maximum temperatures over northern polar areas during the boreal winter months.
We conclude that the fact that trends in thermometer-estimated surface warming over land areas have been larger than trends in the lower troposphere estimated from satellites and radiosondes is most parsimoniously explained by the first possible explanation offered by Santer et al. [2005]. Specifically, the characteristics of the divergence across the datasets are strongly suggestive that it is an artifact resulting from the data quality of the surface, satellite and/or radiosonde observations. These findings indicate that the reconciliation of differences between surface and satellite datasets [Karl et al., 2006] has not yet occurred, and we have offered a suggested reason for the continuing lack of reconciliation.
Tony R (09:06:07) :
The same thoughts keep nagging me also on how much UHI temperature effect is coming from direct diffusion of heat from cumulative energy consumption, as opposed to that deriving from solar storage in concrete brick steel and tarmac. Also how it might coalesce in relatively close-spaced towns and cities, even across seemingly rural areas.
Thought for the day- the best heat sensor is a cat in the cool.
Tell me, are the land temperatures used to calibrate the saellite temperatures? Not the only method, but the original Landsat data was verified with site visits – yep, that’s forest/grass/town/gravel etc.
Is parsimonious used in Dr Pielke’s post in the sense of most rational or most logical ?
Robert Wykoff (09:41:17) :
One problem I have always had with the average temperature being calculated by (Tmax + Tmin) / 2 , is that it is obviously not the average temperature of the day. . . .The average temperature needs many more data points to calculate.
True. We just don’t have the data, but we could in the future.
It wouldn’t be any trick to replace the current surface station indoor readouts with one that performed a continuous temperature integration in addition to the hi/lo/current readout. Internal data storage, internet connection, automatic operation, anything else to add to the list for Santa Claus?
One station owner I surveyed told me it felt like Christmas in July a few years back when they replaced his Stevenson screen with an MMTS. Automating the stations would improve reporting and remove the need for TOBS adjustments, and reduce the need for pretend FILNET temperatures.
You state that there has been an increase in greenhouse gases. What other greenhouse gases other than CO2 have increased? Is the increase in greenhouse gases solely that of carbon dioxide, with no other greenhouse gases decreasing?
Incidentally, slightly off topic, this is probably the most important unanswered question in current global climate modelling. how much affect does the whole mix of gases, liquids and solids in the atmosphere have and how does it affect the climate. We simply do not know the answer, and any models based without knowing are simply guesses and subject to the preference of the modeller.
The conclusion of the paper: “We conclude that the fact that trends in thermometer-estimated surface warming over land areas have been larger than trends in the lower troposphere estimated from satellites and radiosondes is most parsimoniously explained by the first possible explanation offered by Santer et al. [2005]. Specifically, the characteristics of the divergence across the datasets are strongly suggestive that it is an artifact resulting from the data quality of the surface, satellite and/or radiosonde observations.” Yet the title of the paper implies that this is due to a confirmed warming bias at the surface rather than a cooling bias of the satellites which at least in the extracts shown has not been confirmed.
In figure 1 what is the significance of the horizontal black line?
The authors argue that: “Because the land surface temperature record does in fact combine temperature minimum and maximum temperature measurements, where there has been a reduction in nighttime cooling due to this disruption, the long-term temperature record will have a warm bias.”
How does the MSU method deal with this since it also makes two measurements a day at any location (ascending equatorial crossing at 1:30 pm I think)?
Scott Gibson (16:46:57) :
In regards your Q on mixing of GHGs, i see that the initial GOSAT plots are up on their site, and it does look like there may be some issues with the circulation models as far as the mixing goes. Still early days on this, it may be calibration issues. But at least they do have satellites measuring these things now eh.
http://www.gosat.nies.go.jp/eng/result/download/GOSAT_L2_20090528_en.pdf
“… Global Temperature Trends Have Been Overstated” – That’s the surface temperature trends.
In short Satellite temperatures are the ones to trust for the time we have them.
According to Dr Christy the UAH dataset is the only satellite-based temperature dataset that has multiple, independent studies verifying its accuracy.
Dr Christy “In areas where you have high resolution, well- maintained scientific collection of temperature data, the satellites and the surface data show a high degree of agreement, over North America, Europe, Russia, China and Australia, the agreement is basically one-to-one.”
Phil. (17:00:55) : “Yet the title of the paper implies that this is due to a confirmed warming bias at the surface rather than a cooling bias of the satellites which at least in the extracts shown has not been confirmed.”
1. Name a potential source of bias. The authors above have named sources of bias at the surface
2. But I agree that there is no confirmed cool bias in the satellite data.
“How does the MSU method deal with this”
Read the paper. The whole reason why the minimum temperatures at the surface have a warm bias has to do with boundary layer dynamics and disruption of that by surface processes. The surface is not representative of the trend in the Deep Troposphere because atmospheric mixing is minimal at minimum temps. That’s not an issue with satellites because they look at temps in the bulk of the atmosphere.
What a cheap, amateurish criticism of a serious academic paper.
“nor does it mean that efforts to decarbonize the economy do not make sense. ”
That doesn’t make sense regardless of global warming. Billions starving doesn’t make sense.
I am always glad when someone works so hard to bring a well-reasoned counterargument to the consensus. Thank you, Dr. Pielke. However, I am so tired of the quasi-demonization of CO2. As a plant growing enthusiast, I have done quite a bit of reading on the effects of CO2 increases on plant life and can only see benefits to the biosphere of an increased CO2 footprint since atmospheric C02 is at historic lows. I think that besides giving a slight warming upswing, CO2 increases results in more food production, more robust flora, and an overall healthier world.
There is no warming trend in Los Angeles, California. In fact, it is getting cooler, as shown by NOAA’s own data.
http://sowellslawblog.blogspot.com/2009/08/no-warming-in-los-angeles.html
Roger Sowell (19:55:06)
It would make sense that once the UHI affects have topped out, the trends will again show the overall impact of climate changes. Is it possible that this is what is happening in LA, that we aren’t measuring UHI increases anymore but that UHI is now a constant background?
Dr. Roger Pielke Jr starts with a preconceived opinion, writes a paper based on the science, disproves most of the notions that his opinion is based on and and still affirms his fath in those belifs. Nice work.
It couldn’t possibly be that uncle Jim’s propriety fudge factors tend to the warm side, like all his corrections made of past temperatures rounded them down.
Scott Gibson,
I suppose that may be possible, but how are we to know when or if UHI effects top out? Even in the recession, construction continues in Los Angeles, especially on the USC campus which is the present location of the weather station used by NWS. More buildings, more air conditioners, more pavement, more parking lots, it all continues at a slower pace, but it continues.
I suspect the real cause is more cloudy days, or perhaps fewer wind-less days. Also, one half of one year (even 7 months) does not a trend make. But my primary point is that California passed a draconian anti-CO2 law known as AB 32. The supposed list of horrors that AB 32 will prevent includes adverse health effects from hot weather, especially those warmer nights. Gotta watch out for those warmer nights.
I grew up in Houston, and I can attest that those warmer nights killed at least half of my friends. The other half will never be the same. Warmer nights. BEWARE!!!! {sarc off now}
So where is the error in global surface measurements, let’s take a look. First, true temperatures without UHI from stations over Northern Europe and Russia (not cherry picking, these stations have most covering data along time):
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=614028360003&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=634010980003&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=431043600000&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=431042500000&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222234720005&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222246410005&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222208910006&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222245070006&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222233300002&data_set=1&num_neighbors=1
Note almost perfect correlation with solar activity, but not any AGW signal can be seen. Then some big cities from Russia:
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222286980007&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222284400002&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222298380006&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222295700006&data_set=1&num_neighbors=1
http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=222307100009&data_set=1&num_neighbors=1
Strong man-induced signal is seen in these datas. And that is because of UHI. It is strongest in Siberia, because its coldness in winter. This can be seen as large “hot spot” in GISS charts:
http://data.giss.nasa.gov/cgi-bin/gistemp/do_nmap.py?year_last=2009&month_last=07&sat=4&sst=0&type=anoms&mean_gen=1106&year1=1990&year2=2008&base1=1930&base2=1940&radius=1200&pol=reg
So if temperature is measured at surface, only pure rural stations should be considered to avoid UHI. I wonder why GISS does not provide option for rural/urban stations. It seems that global trends of these might be remarkable different. It seems now that whole global warming hysteria is caused by wrong measurement arrangement. Instead northern countries should be worried about rapid cooling following by reducing solar activity. That is what these datas tell.
Since Svalgård and Nahle are at peace, I allow myself to register with interest how Pielke Jr uses the word “heat”.
Richard (18:39:13) :
In short Satellite temperatures are the ones to trust for the time we have them.
Buit which altitude do you take? This plot show different warming/cooling at differing altitudes.
bill (13:11:20) :
http://img512.imageshack.us/img512/6769/amsua19982009.jpg
The slope gets progressively less as height increases
Near surface slope is slightly positive but less than 3300ft
While we are on the topic of overestimation, I have been on a search of methane measurements, not modeled and inferred, but actual measurements. I found little and what I did find was not in agreement. Consider the following study that found no change in methane in a 10 year period ending in 1999.
http://troll.phys.spbu.ru/english/papers/mak_1_1_en.pdf
So please tell me, where would I find a continuous and current record of actual atmospheric methane concentrations that I as a public tax paying individual can see for myself whether or not we are dying in a tundra-melting sea of methane?
Leone, I am a public school teacher so I know it when I see it. I love the way you write. When I read it I can hear your accent. Wonderful.
This overstating of global temperatures sure fooled a lot of people. It also fooled a lot of vegetation and animals and glaciers.
Leone (01:02:20) : Actually, the important message of this paper is that even rural temps can be biased.
Roger Sowell (21:41:16) : Of course the law in question can be shown to have essentially zero climate impact even if you buy the catastrophic climate models. BUT interesting enough!!! California has had some interesting research on trend biases done. Anthony has brought our attention to some of this work before, I believe. For instance, the former State Climatologist (I actually think that he retired rather than being purged like Pat Michaels, George Taylor, Mark Albright, David Legates, or other State Climatologists who had disgraceful Democrat Governors for “bosses”…) Jim Goodridge found that the strength of “warming” trends in California was highly dependent on how populous the area is:
http://www.warwickhughes.com/climate/calif.gif
And in the Central Valley, there is strong Minimum Temperature warming, but not in Maximum Temperature-and not in either in the Sierras.
Christy, J.R., W.B. Norris, K. Redmond and K. Gallo, 2006: Methodology and results of calculating central California surface temperature trends: Evidence of human-induced climate change? J. Climate, 19, 548-563.
bill (01:56:48) : NOAA has been drifting all that time and that is not adjusted data, so I wouldn’t take it as a reliable indicator of trends. However, what we are looking for in relation to surface warming globally (which is not necessarily the best place to look) the comparable series is TLT-temperature of the lower troposphere:
http://vortex.nsstc.uah.edu/data/msu/t2lt/tltglhmam_5.2
Which is a combination of different heights with various weights and blah blah blah-the globe should warm in this layer at a rate that is 1.2 times that at the surface. Obviously it doesn’t even have 1 times as much warming, which doesn’t make much sense at all-and that is where the evidence for warm bias in the surface data (when coupled with other papers showing problems with that data).
Frankly, I am very disappointed by the paper because it assumes that the surface data is measured accurately or that the adjustments to it reflect the true temperatures accurately. From what I have seen there is no objective evidence that the assumption is valid and absent accurate data there is nothing scientific about any paper that uses the reported data.