by Zeke Hausfather , Steven Mosher, Matthew Menne , Claude Williams , and Nick Stokes
[Note: this is an AGU poster displayed at the annual meeting, available here as a PDF. I’ve converted it to plain text and images for your reading pleasure. I’m providing it without comment except to say that Steven Mosher has done a great deal of work in creating a very useful database that better defines rural and urban stations better than the metadata we have available now. – Anthony]
Introduction
Large-scale reconstructions of surface temperature rely on measurements from a global network of instruments. With the exception of remote automated sensors, the locations of the instruments tend to be correlated with inhabited areas. This means that urban
ares [sic] are probably oversampled in surface temperature records relative to the total land surface that is actually urbanized.
It has long been known that urbanized areas tend to have higher temperatures than surrounding less developed (or rural) areas due to the concentration of high thermal mass impermeable surfaces (Oke 1982). This has led to some concern that changes in
urban heat island (UHI) effects due to rapid urbanization in many parts of the world over the past three decades may have been responsible for a portion of the rapid rise in measured global land surface temperatures. This concern is reinforced by lower
observed trends in some interpretations of satellite measurements of lower tropospheric temperature over land areas during the same period (Klotzbach et al 2009).
An analysis of the impact of urbanization on temperature trends faces multiple confounding factors. For example, an instrument originally installed in a city frequently will have warmer absolute temperatures than one in a nearby rural area (especially at night), but will not necessarily show a higher trend over time unless the environs change in such a way that the UHI signal is altered in the vicinity of the instrument. Similarly, microsite characteristics that may be unrelated to the larger urban environment can have
notable effects on temperature trends and act counter to or in concert with the ambient UHI signal.
Moreover, the definition of urban areas is subject to some uncertainty, both in terms of how urban form is characterized and at what distance from built surfaces urban-related effects persist. Published station metadata often includes outdated indications of whether a station is urban or rural, and instrument geolocation data can be imprecise, out of date, or otherwise incorrect.
There is also uncertainty over how much explicit correction is needed for urban warming in global temperature reconstructions, and how well homogenization techniques recently introduced in GHCN-Monthly version 3 both detect and correct for inhomogenities
arising from changes in urban form.
To address these issues and obtain a more accurate estimation of the impact of urbanization on land temperature trends, we examine different urbanity proxies at multiple spatial resolutions and urbanity selection criteria through both simple spatial
weighting and station pairing techniques. This study limits itself to unadjusted average temperature data, though we will examine homogenized data in the future to see how much of the UHI signal is removed.
Methods
We examine GHCN-Daily version 2.80 temperature data rather than the more commonly used GHCN-Monthly data as it contains significantly more stations, particularly during the past thirty years, and allows for separate examination of maximum and minimum
temperatures. A relatively high spatial density of stations is useful to allow sampling into various urban and rural station subsets while minimizing biases due to loss of spatial coverage. After excluding stations that have fewer than 36 months at any time in the
period of record or at least one complete year of data during the 1979 to 2010 period, we are left with 14,789 stations.
A complete set of metadata is calculated for each station using the station location information provided in station inventories and publically available GIS datasets. These datasets include: Distance From Coast (0.1 deg), Hyde 3.1 historical population data (5
arc minute), 2000AD Grump Population density (30 arc seconds), Grump Urban Extent, Land use classes from the Harmonized Land Use inventory (5 arc minutes), radiance calibrated Nightlights (30 arc seconds), ISA- Global Impervious Surfaces (30 arc
seconds), Modis Landcover classes (15 arc seconds), and distance from the closest airport (30 arc seconds). In addition, area statistics at progressive radii are calculated around each putative site location.
Stations are then divided into two classes based on various thresholds for urbanity and two analytical methods are used to estimate the bias in trend due to urbanity: a spatial method and a paired station approach. The spatial averaging method relies on
solving a set of linear equations for the stations in each class. For each group of stations, urban and rural, a time series of average temperature offsets was created by fitting the model:
where T represents the observed temperature for each station, month and year, L is a local average temperature for each station for each month (incorporating seasonal variation) and G is the desired global (or regional) average, varying by year. This is fitted
with a weighting that is inversely proportional to a measure of station density. With a G calculated for both urban and rural, the trends can be compared.
The pairwise method proceeds with the same classification of stations and the following steps are taken. An urban base pair is selected based on the length of record. To qualify as a base urban pair a station must have 30 complete years of data in the 1979-2010 window.
Ten out of 12 months of data are required to count as a complete year. For every urban base station rural pairs are selected based on distance and data overlap. For every urban base station the rural stations are exhaustively searched and all those rural pairs within 500km are assigned to the base station. Since rural stations may have short records the entire rural ensemble is evaluated for data overlap with the urban base pair. 300 months of overlap are required. If the collection of rural stations has less than 300 months of overlap with its urban pair, it is dropped from the analysis. A weighting function is deÞned in the neighborhood of each urban station, which diminishes with distance and is zero outside a certain radius. An average trend is computed for the rural stations within that radius by fitting the model
where t is time in years, and B is the gradient. This trend is then compared with the OLS trend for the central urban station. The differences in the shapes of the distributions of the trends is a function of the number of stations that form the trend estimation.
Urban trends are trends for individual stations, while rural trends are the result of computing a trend for all the rural pairs taken as a complete ensemble.
Discussion
While urban warming is a real phenomenon, it is overweighted in land temperature reconstructions due to the oversampling of urban areas relative to their global land coverage. Rapid urbanization over the past three decades has likely contributed
to a modest warm bias in unhomogenized global land temperature reconstructions, with urban stations warming about ten percent faster than rural stations in the period from 1979 to 2010. Urban stations are warming faster than rural stations on average across all urbanity proxies, cutoffs, and spatial resolutions examined, though the underlying data is noisy and there are many individual cases of urban cooling. Our estimate for the bias due to UHI in the land record is on the order of 0.03C per decade for urban stations.
This result is consistent with both the expected sign of the effect and regional estimates covering the same time period (Zhou et al 2004) and differs from some recent work suggesting zero or negative UHI bias (Wickham et al, submitted).
Stricter urbanity proxies that result in a smaller set of rural stations show larger urban-rural differences in trend. The upper limit on UHI bias between rural and urban stations is on the order of 0.06 to 0.1C per decade. However, these cases are clearly problematic from the spatial coverage aspect, as the number of rural stations becomes vanishingly small when the most stringent filters are applied. Adopting cutoffs that define rural less strictly leads to more reasonable spatial coverage and an estimate of UHI bias in the record that converges on 0.02C to 0.04C per decade across the proxies. The station pair approach avoids this issue by limiting the analysis to areas with both rural and urban stations available, but has limited global coverage and excludes large areas in India and coastal China where rapid urbanization has been occurring in recent decades.
It is likely that homogenization will further reduce the observed UHI-related bias, as many urbanity biases are detectable through break-point analysis via comparison to surrounding rural stations. We are currently in the process of using the Pairwise Homogenization Algorithm (Menne and Williams 2009) on GHCN-Daily data to examine the effects in more detail. However, it remains to be seen to what degree UHI bias can be removed via homogenization in areas like coastal China and India where there are few rural stations and where station densities are not particularly high in the current version of GHCN-Daily. In any case, the acquisition of additional station data outside of urban areas in these parts of the world would likely be benefitial.
Acquiring more accurate station location data will allow us to use higher-resolution remote sensing tools to identify urban characteristics below the 5 km threshold, and better test effects of site-specifc vs. meso-scale characteristics on urban warming biases. In addition, validated site locations allows for more refinement in the definition of rural stations as a function of distance from urban cores of various sizes.
References
Center for International Earth Science Information Network (CIESIN), Columbia University; International Food Policy Research Institute (IFPRI); The World Bank; and Centro Internacional de Agricultura Tropical (CIAT). 2004. Global Rural-Urban
Mapping Project, Version 1 (GRUMPv1): Population Density Grid. Palisades, NY: Socioeconomic Data and Applications Center (SEDAC), Columbia University. Available at http://sedac.ciesin.columbia.edu/gpw.[Aug 14, 2011].
Elvidge, C.D., B.T. Tuttle, P.C. Sutton, K.E. Baugh, A.T. Howard, C. Milesi, B. Bhaduri, and R. Nemani, 2007, “Global distribution and density of constructed impervious surfaces”, Sensors, 7, 1962-1979
Fischer, G., F. Nachtergaele, S. Prieler, H.T. van Velthuizen, L. Verelst, D. Wiberg, 2008. Global Agro-ecological Zones Assessment for Agriculture (GAEZ 2008). IIASA, Laxenburg, Austria and FAO, Rome, Italy.
Klein Goldewijk, K. , A. Beusen, and P. Janssen (2010). Long term dynamic modeling of global population and built-up area in a spatially explicit way, HYDE 3 .1. The Holocene20(4):565-573.
Klotzbach, P., R. Pielke Sr., R. Pielke Jr., J. Christy, and R. T. McNider, 2009. An alternative explanation for differential temperature trends at the surface and in the lower troposphere. J. Geophys. Res.
Menne, M.J., I. Durre, R.S. Vose, B.E. Gleason, and T.G. Houston, 2011: An overview of the Global Historical Climatology Network Daily Database. Journal of Atmospheric and Oceanic Technology, submitted.
Menne, M.J., and C.N. Williams, Jr., 2009. Homogenization of temperature series via pairwise comparisons. J. Climate, 22, 1700-1717.
Schneider, A., M. A. Friedl and D. Potere (2009) A new map of global urban extent from MODIS data. Environmental Research Letters, volume 4, article 044003.
Schneider, A., M. A. Friedl and D. Potere (2010) Monitoring urban areas globally using MODIS 500m data: New methods and datasets based on urban ecoregions. Remote Sensing of Environment, vol. 114, p. 1733-1746.
T. R. Oke (1982). “The energetic basis of the urban heat island”. Quarterly Journal of the Royal Meteorological Society 108: 1–24.
Wickham, C., J. Curry, D Groom, R. Jacobsen, R. Muller, S. Perlmutter, R. Rohde, A. Rosenfeld, and J. Wurtele, 2011. Inßuence of Urban Heating on the Global Temperature Land Average Using Rural Sites IdentiÞed from MODIS ClassiÞcations.
Submitted.
Zhou, L., R. Dickinson, Y. Tian, J. Fang, Q. Li, R. Kaufmann, C. Tucker, and R. Myneni, 2004. Evidence for a signiÞcant urbanization effect on climate in China. Proceedings of the National Academy of Sciences.
Ziskin, D., K. Baugh, F. Chi Hsu, T. Ghosh, and C. Elvidge, 2010, “Methods Used For the 2006 Radiance Lights”, Proceedings of the 30th Asia-PaciÞc Advanced Network Meeting, 131-142
A very interesting and intriguing chart. IMO it looks pretty reasonable. A few years ago prompted by a post on CA, I looked at the population data on all South American GISS locations. Much of the GISS population data is seriously at odds with local census data in countries with rapidly growing and urbanizing populations. The only current rural site in South America that I could find appeared to be an island off the coast of Brazil and even that was growing rapidly.
This raises the point that if you can identify sites that have shifted from rural to urban in the last 50 years you should get a pretty clear UHI signal. Is another coloured dot possible? After all it is the change in population density that is relevant not simply whether a site is rural or urban.
Are there really no stations in Brazil? It is a small map, and I have bad eyes, but I am not seeing a dot, either blue or red, in Brazil.
Right off the bat, I’m suspicious. The classic UHIE study of Barrow, AK, showed substantial effects even in such a remote “rural” location, due to buildings/siting. How many other “rural” sites are similarly affected? Probably most.
FAIL.
Land temps come and go (literally every night). It is the temperature directly over the oceans that are of interest to me. If they demonstrate warming and cooling commensurate with oceanic conditions, you not only have a very good temperature record that clearly cannot be affected by urbanization, you also have cause.
Land temps are useful for weather prediction, clothing selection, and airplanes.
crosspatch says:
December 5, 2011 at 11:16 pm
While it is beyond the scope of your research, I would also be interested in the impact of multidecadal changes in atmospheric weather patterns on UHI over long periods of time. For example, if we were to see a fairly reliable seasonal storm track make a persistent move in location, we might see a significant change in regional temperature trends.
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I have one “pair” that is interesting and it is not even a rural/urban pair but a urban/airport pair:
The city is on the North Carolina/Virgina border and right on the ocean.
Norfolk City
Norfolk International Airport
Here is the raw 1856 to current Atlantic Multidecadal Oscillation Amazing how the temperature follow the Atlantic ocean oscillation as long as the weather station is not sitting at an airport isn’t it?
Other Coastal Cities:
North – Elisabeth City
South – Wilmington NC
BioBob says:
December 6, 2011 at 12:22 am
….The corruption of the science of sampling is truly awesome all the way down to the purported precision down to hundredth of a degree..
Neither have I ever seen an honest accounting of the actual extent / range of all the various errors in the data set.
GIGO – the data is trash no matter how you stack it.
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AMEN!
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Phil says:
December 6, 2011 at 3:45 am
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Thanks, Phil, I hadn’t read your post before posting mine. You provide alot more detail on the Barrow study.
Since fossil fuel use in Barrow is primarily for Winter heating, I would then divide by 4 seasons to obtain an estimate of 0.05°C per decade.
The actual heating season is longer than 3 months in Barrow, isn’t it? 🙂
Very interesting. A recent paper showed that in semidesert to desert environments (Southwest USA for example) the urban environments were actually cooler because of the vegetation people plant. The effects will then be affected by the distribution of rural sites, since many more of them are in undeveloped parts of the world, which tend to be drier.
John Marshall says:
December 6, 2011 at 2:08 am
….The alarmist reconstructions rely on a global network of scientists who are not bothered about altering, deleting or otherwise changing their data to fall in with the AGW ideas.
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OH, you mean like this? http://i31.tinypic.com/2149sg0.gif
Gail Combs says:
December 6, 2011 at 7:02 am
Here is the raw 1856 to current Atlantic Multidecadal OscillationAmazing how the temperature follow the Atlantic ocean oscillation as long as the weather station is not sitting at an airport isn’t it?
Let me guess, a growing airport and the daily onshore wind blows straight across a long section of hot tarmac right to the weather station? Wouldn’t be suprised if this is a systemic problem for all airport stations near an ocean.
All this discussion has missed a basic point.
The concern raised in the AGW hypothesis is that heat is being trapped in the Earth system leading to potentially catastrophic changes in climate. Therefore, to assess the truth of this statement the metrics used should quantify heat not atmospheric temperatures. In the atmosphere temperature is not directly related to heat content.
To quantify the amount of heat being retained in the Earth system it is far more accurate to measure ocean heat content; or, measure incoming radiation and outgoing radiation from satellites outside the system. The metrics that correctly quantify heat content show that there does not appear to be an increase in heat being retained within the Earth system.
The correct metrics failure to show the desired AGW result is not a reason to try to use incorrect metrics. Similarly just because historically the incorrect metrics have been recorded is not a reason to use them – that is searching for keys under the lamppost.
“Summer land surface temperature of cities in the Northeast were an average of 7 °C to 9 °C (13°F to 16 °F) warmer than surrounding rural areas over a three year period, the new research shows. The complex phenomenon that drives up temperatures is called the urban heat island effect.”
http://www.nasa.gov/topics/earth/features/heat-island-sprawl.html
They looked at 42 cities.
Zeke, NASA says 7C to 9C in the summer. You say .03C per decade. Does your data show 7C – 9C in the summer? If not, why not? What is wrong with your methodology? How do you plan to correct it?
The obvious conclusion is that rural stations are becoming more rare and have cleaner data. They should receive more attention and preservation. And some more should be added.
Pete in Cumbria UK says:
December 6, 2011 at 3:50 am
….. Can rural thermometers ‘see’ an infra red glow from urban areas….
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NO.
The most likely problem is micro siting problems. That is moving from a glass min max thermometer sitting out in a field some where to a digital thermometer with a cable. Cable length means the actual “Site” will be moved from the middle of the field to near the side of the building and all of a sudden your “rural” site is no longer actually “rural”
That is what Anthony’s surface station project was all about http://www.surfacestations.org/
list of Several discussions on the subject: http://wattsupwiththat.com/category/weather_stations/
Not much to say except nice job and thanks for the huge and honest effort.
They could save even more money on cabling costs if they were to simply site the weather stations inside the buildings and be done with it. This would pretty much stabilize temperatures at 70F/20C around the globe. We would have a very brief 5C jump in average temperatures from the current 15C, probably due to elevated CO2 inside the buildings, then temperatures would stabilize globally.
crosspatch says:
December 6, 2011 at 1:12 am
BioBob, I think for purposes of “climate change” it really isn’t all that important how accurate it data are so much as you capture the proper trending of it.
I agree, however, this statement from the above is key “…but will not necessarily show a higher trend over time unless the environs change in such a way that the UHI signal is altered in the vicinity of the instrument.
I am very skeptical that one could find any station under “UHI/LHI” influence hasn’t had the effect altered multiple times over the time frame that it was under that influence.
.Someone please do the fact-check on these recollections I have.
As I recall, in the mid-1980’s Weathermen were just itching to utilize the next generation of weather radar, but it was going to cost a lot, and at that time, (unlike today,) Congress was digging in its heels when it came to spending like drunken sailors. NOAA was told it couldn’t get its new radar unless it made significant cuts in other areas.
It was for this reason the excellent system of gathering temperatures got mangled. A lot of faithful employees were replaced by gizmos that needed to be connected to the station by a cord. The cord could not cross a highway, for it was too expensive to cut trenches through the tar. Therefore a lot of thermometers were moved closer to the weather stations, both in Urban and Rural locations.
What is interesting to contemplate is the possibility of ulterior motives being involved. After all, the mid 1980’s was when they left the windows open in Congress to make it uncomfortably hot when Hansen made his speech about Global Warming. If sneaky stuff like that could be done, why not mangle the excellent system of gathering temperatures, to make it easier for Hansen to “adjust” the temperature records?
In the old days I would have deemed this sort of suspicion sheer paranoia on my part, and dismissed it from my thinking. However so many crazy suspicions have turned out to be true I don’t think anything would surprise me any more. And I do know that members of congress change their votes for reasons that have nothing to do with what the vote seems to be about.
The NEXRAD system was passed by Congress in 1988, I think, and ground based temperatures started to get messed up at the same time, “to save money.” Who would have dreamed Hansen would adjust as he adjusted, and the cost-cutting measure would turn out to cost trillions?
Ian W says:
December 6, 2011 at 7:27 am
…..To quantify the amount of heat being retained in the Earth system it is far more accurate to measure ocean heat content; or, measure incoming radiation and outgoing radiation from satellites outside the system. The metrics that correctly quantify heat content show that there does not appear to be an increase in heat being retained within the Earth system.
The correct metrics failure to show the desired AGW result is not a reason to try to use incorrect metrics. Similarly just because historically the incorrect metrics have been recorded is not a reason to use them – that is searching for keys under the lamppost.
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That has nothing to do with the “Science”
The reason IPCC exists and climate scientists are funded is to produce “Data” that scares the crap out of Joe Sixpack so he will cough up more of his hard earned cash and fork it over to the bankers/financiers/”green” corporations and of course the politicians.
Rising temperatures do a dandy job of this. There is no cause for alarm does not.
Imho, local weatherstations were built and run to document local events, local developments.
Very useful.
To have thousands such stations, manipulating their data in order to compensate local developments, and add all this together to show a global mean temperature is the “work hard” approach. Not very smart. Way too many variables, error sources and local dependencies.
Wouldn’t the smarter way be to have a selection of a few truly rural stations only, like National Parks, with a long standing record, unchanged siting and instrumentation?
Not more than a handful per continent. Less work, more reliable results, no manipulation needed.
These few stations would most likely give an unbiased impression about the general land surface temperature trend. Complemented with satellite data for sea surface and all is done.
My question is this. Why do we include urban sites in any temperature reconstruction? When you only look at rural temperatures there is no positive trend in temperatures. The continental USA has shown a drop in temperatures over the past 100 years when you exclude urban sites.
Oh wait, I just answered my own question. Without a scary trend there would be no grant money.
So, using the lowest estimate of UHI of 0.03C/decade over the last 150 years there is a 0.45 degree C signal. Considering the estimate of 0.8 degrees warming during that time period in the US, more than half of the overall warming would be related to UHI. Now, the question to ask is how is this signal being compensated for in the US temperature data? From what I’ve seen it has either been ignored or exaggerated.
Caleb says: December 6, 2011 at 7:49 am
.Someone please do the fact-check on these recollections I have.
I agree with you. It is difficult to ignore the simultaneous rise of temperatures c. 1980, with the change in equipment and therefore siting.
http://i44.tinypic.com/vq5j84.jpg
http://i42.tinypic.com/2luqma8.jpg
JohnWho
“I am very skeptical that one could find any station under “UHI/LHI” influence hasn’t had the effect altered multiple times over the time frame that it was under that influence.”
If you are looking for a “climate change” signal you just want a place that hasn’t changed and there are many of them in practically every region. Little towns off the beaten path with small populations can still be found as can areas where land has been set aside as park or preserve. The problem with UHI impacts on temperatures, though, is that they give you a sunlight bias in your temperatures.
So lets say you have a city in a place that experiences much different weather in La Nina conditions than it does in El Nino conditions. Say your city tends to experience drought in La Nina years (Amarillo?). If the PDO changes from positive to negative and we have more La Nina years than El Nino years, your temperature readings may now be biased by more sunny days per year heating up that concrete in town. So in this case you get an artificial biasing of urban temperatures because of changes in cloud cover. While it always had UHI , the degree of UHI can change depending on cloud cover. UHI would have less of an impact on a cloudy day than on a sunny day. In Phoenix with a missed “monsoon”, UHI would have more impact than in a year with a strong summer “monsoon” and lots of afternoon clouds.
In other words, UHI is basically a sunlight bias. Changes in weather patterns that cause changes in the amount of sunshine will change the amount of UHI bias. I don’t think UHI can be precisely quantified because the amount of UHI impact on the temperatures in a location will vary depending on the amount of sunshine a place receives. I will be willing to bet there is a rough correlation between the amount of UHI offset in a location and precipitation amounts (unless it all falls at night!).
I believe that UHI is so tricky and so fickle that it can’t be accurately removed in any reliable way. It would be best to completely eliminate it from measurements being used to track climate trends.
Gail Combs says:
December 6, 2011 at 7:50 am
Ian W says:
December 6, 2011 at 7:27 am
…..To quantify the amount of heat being retained in the Earth system it is far more accurate to measure ocean heat content; or, measure incoming radiation and outgoing radiation from satellites outside the system. The metrics that correctly quantify heat content show that there does not appear to be an increase in heat being retained within the Earth system.
The correct metrics failure to show the desired AGW result is not a reason to try to use incorrect metrics. Similarly just because historically the incorrect metrics have been recorded is not a reason to use them – that is searching for keys under the lamppost.
________________________________
That has nothing to do with the “Science”
The reason IPCC exists and climate scientists are funded is to produce “Data” that scares the crap out of Joe Sixpack so he will cough up more of his hard earned cash and fork it over to the bankers/financiers/”green” corporations and of course the politicians.
Rising temperatures do a dandy job of this. There is no cause for alarm does not.
I fully agree – but why are the ‘correctly skeptical scientists’ (most posters above) being drawn into complex arguments on how to quantify the incorrect metric? The approach should be – “The IPCC, HADCRUT, GISS etc., are measuring the wrong variable.” and not enter into long debates on how to more accurately measure the wrong variable.