Guest Post by Willis Eschenbach
In 2006, I lived for a year in Waimea, on the Big Island of Hawaii. From my house I could see the Mauna Loa Observatory (MLO). This observatory is the home of the longest continuous series of CO2 measurements we have. The recording station was set up by Dave Keeling in 1959, and has operated continuously ever since.
Figure 1. Mauna Loa Observatory ( 19.536337°N, 155.576248°W)
Here’s a view of the observatory:
Every time the subject of CO2 measurements comes up, people raise all kinds of objections to the Mauna Loa measurements. So I thought I’d start a thread where we can discuss those objections, and perhaps dispose of some of them.
Here are the objections that I hear the most:
1. The Mauna Loa results don’t measure the background CO2 levels.
2. You can’t get accurate CO2 measurements from samples taken on the side of an active volcano that is outgassing CO2.
3. The measurements from Mauna Loa are not representative of the rest of the world.
4. What about the Beck data, doesn’t it contradict the MLO data?
5. Keeling chose a bad location.
Before we get into those issues, let’s start by looking at the local meteorological conditions at the site. Mauna Loa is at an elevation of 3397 metres (11,140 ft) on the side of a 4,170 metre (13,680 ft) volcano way out in the middle of the Pacific Ocean. Because it is on an island, it gets the “sea breeze” in the daytime, and the “land breeze” in the nighttime.
These winds are caused by the differential heating of the land and the sea. Land heats up much faster than the ocean. So during the day, the warmer land heats the air, which rises. This rising air is replaced by air moving in from the surrounding ocean, creating the “sea breeze”.
At night, the situation is reversed. The land is cooler than the ocean. This cools the air. The cool air runs downhill along the slopes of the island and out to sea, creating the “land breeze”. Here’s a drawing of the situation:
Figure 2. Day and night breezes at Mauna Loa.
Now that we understand what is happening at Mauna Loa, let’s look at the objections.
1. The Mauna Loa results don’t measure the background CO2 levels. As you might imagine from Fig. 2, the CO2 measurements are taken only at night. Thus, they are measuring descending air that is coming from thousands of feet aloft. This air has traveled across half of the Pacific Ocean, so it is far from any man-made CO2 sources. And as a result, it is very representative of the global background CO2 levels. That’s why Keeling chose the site.
2. You can’t get accurate CO2 measurements from samples taken on the side of an active volcano that is outgassing CO2. This seems like an insuperable objection. I mean, Mauna Loa is in fact an active volcano that is outgassing CO2. How do they avoid that?
The answer lies in the fact that the volcanic gasses are very rich in CO2. At night, they are trapped in a thin layer near the ground by a temperature inversion.
To detect the difference between volcanic and background CO2, the measurements are taken simultaneously from tall towers and from near the ground, at intervals throughout the night. Background CO2 levels will be around 380 ppmv (these days), will be steady, and will be identical at the top and bottom of the towers. Volcanic gasses, on the other hand, will be well above 380 ppmv, will be variable, and will be greater near the ground than at the top of the towers.
This allows the scientists to distinguish reliably between volcanic and background CO2 levels. Here is a description of the process:
Air samples at Mauna Loa are collected continuously from air intakes at the top of four 7-m towers and one 27-m tower. Four air samples are collected each hour for the purpose of determining the CO2 concentration. Determinations of CO2 are made by using a Siemens Ultramat 3 nondispersive infrared gas analyzer with a water vapor freeze trap. This analyzer registers the concentration of CO2 in a stream of air flowing at ~0.5 L/min. Every 30 minutes, the flow is replaced by a stream of calibrating gas or “working reference gas”. In December 1983, CO2-in-N2 calibration gases were replaced with the currently used CO2-in-air calibration gases. These calibration gases and other reference gases are compared periodically to determine the instrument sensitivity and to check for possible contamination in the air-handling system. These reference gases are themselves calibrated against specific standard gases whose CO2 concentrations are determined manometrically. Greater details about the sampling methods at Mauna Loa are given in Keeling et al. (1982) and Keeling et al. (2002).
Hourly averages of atmospheric CO2 concentration, wind speed, and wind direction are plotted as a basis for selecting data for further processing. Data are selected for periods of steady hourly data to within ~0.5 parts per million by volume (ppmv); at least six consecutive hours of steady data are required to form a daily average. Greater details about the data selection criteria used at Mauna Loa are given in Bacastow et al. (1985). Data are in terms of the Scripps “03A” calibration scale.
There is a more detailed description of the measurement and selection process here.
As a result, the Mauna Loa record does accurately measure the background CO2 levels, despite the fact that it is on an active volcano. The samples that are identified as volcanic CO2 are not thrown away, however. They are used for analyses of the volcanic emission rates, such as this one (pdf).
3. The measurements from Mauna Loa are not representative of the rest of the world. Well, yes and no. The concentration of atmospheric CO2 varies by month, and also by latitude. Here is a “carpet diagram” of the changes by time and latitude.
Figure 3. A “carpet diagram” of CO2 distributions, by time and latitude.
Note that the swings are much greater in the Northern Hemisphere. Presumably, this is from the plants in the much larger land area of the Northern Hemisphere. However, the difference between the annual average of the Northern and Southern Hemispheres is small. In addition, there are smaller daily variations around the planet. An animation of these is visible here, with day by day variations available here.
Figure 4 shows is a typical day’s variations, picked at random:
Figure 4. Snapshot of the variations in tropospheric CO2. Note that the range is small, about ±1% of the average value.
In general, the different global records match quite closely. In addition to the Mauna Loa observatory, NOAA maintains CO2 measuring stations at Barrow, Alaska; American Samoa; and the South Pole. Here is a comparison of the four records (along with two methane records):
Figure 5. Comparison of the CO2 records from the four NOAA measuring sites.
As you can see, there is very little difference between the CO2 measurements at the four stations – two in the Northern Hemisphere, two in the Southern, two tropical, and two polar.
4. What about the Beck data, doesn’t it contradict the MLO data? In 2007, Ernst-Georg Beck published a paper called “180 Years Of Atmospheric CO2 Gas Analysis by Chemical Methods” (pdf). In it, he showed a variety of results from earlier analyses of the atmospheric CO2. In general, these were larger than either the ice core or the MLO data. So why don’t I believe them?
I do believe them … with a caveat. I think that the Beck data is accurate, but that it is not measuring the background CO2. CO2 measurements need to be done very carefully, in selected locations, to avoid contamination from a host of natural CO2 sources. These sources include industry, automobiles, fires, soil, plants, the list is long. To illustrate the problems, I have graphed the Beck data from his Figure 13, against the Law Dome ice core data and the MLO data.
Figure 6. CO2 data from a variety of sources. White crosses are MLO data. Three separate ice core records are shown. Photo is of Mauna Loa dusted with snow (yes, it snows in Hawaii.) PHOTO SOURCE
There are several things to note about this graph. First, there is good agreement between the Law Dome ice core data and the MLO data over the ~ two decade overlap. Second, there is good agreement between the three separate Law Dome ice core datasets. Third, both the ice cores and the MLO data do not vary much from year to year.
Now look at the various datasets cited by Beck. Many of them vary quite widely from one year to the next. The different datasets show very different values for either the same year or for nearby years. And they differ greatly from both the ice core and the MLO data.
Because of this, I conclude that the Beck data, while valuable for showing ground level CO2 variations at individual locations, do not reflect the background CO2 level of the planet. As such, they cannot be compared to the MLO data, to the ice core data, or to each other.
5. Keeling chose a bad location. I would say that Keeling picked a very good location. It not only allows us to measure the background CO2 in a very accurate manner, it provides invaluable information about the amount of CO2 coming from the volcano.
My conclusion? Most of the records in the field of climate science are short, spotty, and not very accurate. We have little global historical information on ocean temperatures, on land temperatures, on relative humidity, on atmospheric temperatures, on hurricane occurrence and strength, or on a host of other variables. By contrast, the Mauna Loa CO2 records are complete since 1959, are very accurate, and are verified by measurements in several other locations.
I’m about as skeptical as anyone I know. But I think that the Mauna Loa CO2 measurements are arguably the best dataset in the field of climate science. I wouldn’t waste time fighting to disprove them, there are lots of other datasets that deserve closer scrutiny.
[UPDATE] A reader below has added another question, viz:
6. What about Jaworoski’s claim that the ice core data has had its age “adjusted”?
Jaworoski argues that the age of the air in the ice cores has been “adjusted” to make it align with the modern data. He says, for example, that the Siple ice core data has been moved forwards exactly 83 years to make them match the Mauna Loa data.
Dating the ice core data is problematic. We can date the ice itself pretty accurately, through counting layers (like tree rings) and through studying various substances such as volcanic dust that is trapped in the ice. However, dating the air is harder.
The difficulty is that the air is not trapped in the ice immediately. The pores in the “firn”, the snow that falls annually on top of the ice are open. Air can flow in and out.
As more and more snow falls over the years, at some point the pores close off and the air is trapped. So how long does it take for the pores in the firn to seal off?
Unfortunately, as in so many areas of climate science, the answer is … “depends”. It depends inter alia on how much snow falls every year, how much of that snow sublimates (changes from a solid to a gas) every year, and even the shape and size of the individual snowflakes.
The end result of all of this is that we end up with two ages for any given thin slice of an ice core. These are the “ice age” (how old the ice itself is), and the “air age” (how old the air trapped in the ice is). The ice is always older than the air.
The main variable in that is thought to be the annual snowfall. Unfortunately, while we know the current rate of annual snowfall, we don’t know the historical rate, particularly tens of thousands of years ago. So we use the concentration of an isotope of oxygen called “d18O” to estimate the historical snowfall rate, and thence the firn closing rate, and from that the air age.
Sounds a bit sketchy? Well … it is, particularly as we go way back. However, for recent data, it is much more accurate.
So to bring this back to real data, in the ice core data I showed in Fig. 5, the air is calculated to be 30 years younger than the ice for cores DEO8 and DEO8-2, and 58 years younger for the DSS core. Is this correct? I don’t know, but I do know that there are sound scientific reasons for the “adjustment” that Jaworowski objects to .
Finally, the existence of a thirty to sixty year difference in air and ice age doesn’t make much difference in the pre-industrial levels of CO2. This is because prior to about 1800, the level is basically flat, so an error in the air age dating doesn’t change the CO2 values in any significant manner.
FURTHER INFORMATION:
Greenhouse Gas & Carbon Cycle Research Programs
Trends in Atmospheric Carbon Dioxide
How we measure background CO2 levels on Mauna Loa
I do believe them … with a caveat. I think that the Beck data is accurate, but that it is not measuring the background CO2. CO2 measurements need to be done very carefully, in selected locations, to avoid contamination from a host of natural CO2 sources.
While I also have no problem with the Mauna Loa data I found an interesting statement in a 1964 DARPA sponsored book on infrared technology.
CO2 levels within 100-200 meters above the ground are found to vary between 200-600 ppm. If this is true, it would explain the Beck results. Also, if it is true then it means that how infrared energy is absorbed according the the computer models is completely wrong.
Hu McCulloch says:
June 7, 2010 at 11:43 am
The Beck data shows values that differ by 30 ppmv in the same year. It shows values that jump by 50 ppmv from one year to the next. I see nothing like that in the MLO data.
While they have been naturally smoothed as you say, I have used the yearly values, not the 20 or 75 year smoothed values, to make the chart.
Willis Eschenbach says:
June 7, 2010 at 5:17 pm
” MLO only goes back to 1958, and the other comparable series are shorter yet. Beck shows a big rise in CO2 between 1930 and 1950 (http://www.biomind.de/realCO2/), but MLO tells us nothing about this period. ”
The Beck data shows values that differ by 30 ppmv in the same year. It shows values that jump by 50 ppmv from one year to the next. I see nothing like that in the MLO data.
” The Law Dome cores suggest flat CO2, but then they’ve been naturally smoothed by the firn factor (and then artifically smoothed on top of that).”
While they have been naturally smoothed as you say, I have used the yearly values, not the 20 or 75 year smoothed values, to make the chart.
Let us start the logic from the beginning:
Why are we interested in measuring global CO2 ?
Answer: Because some scientists got the idea that CO2 as a green house gas has the ability to delay heat from leaving the atmsphere to the point of leading to an overheating of the planet.
Where is CO2, and how is it distributed?
answer: there are many sources and sinks of CO2 and it is distributed all over the globe
What is the ideal way to measure CO2 cncentrations?
answer: satellites that would also give three dimensional measurements, down to the surface, since CO2 as a heavier than air gas concentrates lower than the average gases in the air.
How do we measure CO2?
answer: by 14 or so stations covering the latitudes in a limited longitude slice chosen for “purity” .
and at the moment in the troposphere by satellites.
Assuming that there is nothing wrong with the Keeling et al measurements, do you really believe these will give a reasonable estimate of amount of CO2 in the atmosphere?
To accept these measurements as global measurements, one has to swallow whole the ” well mixed” hypothesis.
Do you have an experimental proof of the “well mixed” hypothesis?
Experiments where a column of air has been sampled from ground level to troposphere and the ppms found constant?
I would like a link for that.
Missing this experiment, if I accept the Maona Loa as well measured, I am also allowed to accept Beck’s compilations as well measured and they strongly suggest that the “well mixed” hypothesis is wrong.
How would the CO2 from the WWII excess travel to Maona Loa? Look at the AIRS animations to see how the CO2 streams like everything in the atmosphere from west to east.
This is a video everybody who talks of well mixed should watch:
http://www.metacafe.com/watch/930860/see_how_co2_is_heavier_than_air/
With innumerable sources and sinks of CO2 on the surface continually acting do you still insist that the “pure” measurements are the way to measure the CO2 in the atmosphere?
Anna,
You say
” Why are we interested in measuring global CO2 ?
Answer: Because some scientists got the idea that CO2 as a green house gas has the ability to delay heat from leaving the atmsphere to the point of leading to an overheating of the planet.”
The origins of the MLO project is where I start to have problems. Given the prior state of knowledge (see Beck’s listing of the CO2 measurement programmes during C19th) it was obvious that CO2 was not well-mixed at all, and so a proposal to fund the whole MLO project, including its expensive logistic trail of samples, just would not have succeeded. But a cold-war observation system, designed to measure and detect C14 in the upper atmosphere, most definitely would have been funded.
So, we could postulate the start of MLO as a hugely well-funded cold-war observatory and logistic chain, set up to measure the changing levels of C14 fraction, as a means of detecting nuclear tests and estimating yields. So, one could say that the MLO project to measure ‘background CO2’ was partially motivated by a groupthink need to find other moral justifications for the work .. a ‘peaceful scientific use’ …. a ‘swords plus ploughshares’ thing, perhaps. And like all such projects with dual sources of funding, the confusion of ends and means inherent in dualities of this nature, produces complexity. A reading of the history of the MLO indicates that the CO2 measuring project was done on a shoesting, with all that implies.
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You can say THAT again!
Quite late to join the discussion (what a pity!), here a few remarks:
Willis used the older description of the Mauna Loa measurement and selection method, but a newer, more detailed one exists here, including extended calibration methods:
http://www.esrl.noaa.gov/gmd/ccgg/about/co2_measurements.html
The raw (hourly averaged + stdv), non-altered in any way data are available for four of the baseline stations at:
ftp://ftp.cmdl.noaa.gov/ccg/co2/in-situ/
where BRW = Barrow, MLO = Mauna Loa, SMO = Samoa and SPO = South Pole
These are calculated data, based on 2×20 minutes voltage readings of the outside air and 3×3 minutes readings of different calibration gases with known composition (see the first website about calibration).
For the (still) interested ones, there is no difference in form or average or trend if you include or exclude the outliers with the criteria used for all baseline stations. See my web page at: http://www.ferdinand-engelbeen.be/klimaat/co2_measurements.html
What I find astonishing about all of the above discussion of the volcano is: no-one has paused to think: did Keeling *know* about this? Did he perhaps have a very good scientific reason for choosing this site? Did he perhaps… think about it?
More: http://scienceblogs.com/stoat/2010/06/dumb_america.php
William M. Connolley says:
June 24, 2010 at 3:26 pm
What I find astonishing is that you didn’t notice that I said that Keeling thought about it and chose a good site, viz:
and
Then we have:
Jay Cech says:
June 5, 2010 at 8:40 am
and
HankHenry says:
June 5, 2010 at 6:42 am
So yes, I and others have said that Keeling had good reasons for picking the site.
PS – For those readers unacquainted with William Connolley and his work, there is a good overview here and here.
Ferdinand Engelbeen says:
June 20, 2010 at 12:19 pm
Many thanks, Ferdinand. A number of people had asked for the raw data (or complained that it was unavailable). Your link should set that to rest.
As to whether the outliers make any difference, please see Ferdinand’s web page here, which shows that they make no difference at all. As William Connolley says, Keeling knew what he was doing when he chose the site …
Willis Eschenbach says:
June 24, 2010 at 6:47 pm
As to whether the outliers make any difference, please see Ferdinand’s web page here, which shows that they make no difference at all. As William Connolley says, Keeling knew what he was doing when he chose the site …
Just finished a few graphs where the raw hourly data of two stations (Mauna Loa and Samoa) are compared with the “cleaned” daily averages of the same stations for the year 2008, according to the predefined rules for exclusion of outliers:
http://www.ferdinand-engelbeen.be/klimaat/klim_img/co2_raw_select_2008.jpg
The average for the raw data of Samoa in 2008 is 384.00 ppmv, for the selected daily average data it is 393.91. For Mauna Loa: raw 385.34, selected 385.49. Hardly a difference in a trend of 60+ ppmv since the measurements at the South Pole and Mauna Loa started…
I also have plotted the same data on full scale to show that the small local variations around the global trend are of little interest:
http://www.ferdinand-engelbeen.be/klimaat/klim_img/co2_raw_select_2008_fullscale.jpg
The full scale graph makes it clear that CO2 in the atmosphere, at least between MLO and SMO (but also at most other places on earth) is very well mixed…
Just a couple of Ferdinand quotes…
” The raw (hourly averaged + stdv), non-altered in any way data ”
” Just finished a few graphs where the raw hourly data ”
” The average for the raw data of Samoa in 2008 is 384.00 ppmv, for the selected daily average data it is 393.91. For Mauna Loa: raw 385.34, selected 385.49. ”
By slight of word, hourly averages become unaltered raw data.
Yet no raw data to see.
Very impressive Ferdinand, very impressive.
I love Willis’s comment,
” Many thanks, Ferdinand. A number of people had asked for the raw data (or complained that it was unavailable). Your link should set that to rest. ”
Complicite, never, perish the thought.
Derek says:
June 28, 2010 at 2:40 pm
Derek, I know, you never will be satisfied, until you have even the size of the shoes of the maintenance engineer at Mauna Loa, to be sure that he didn’t alter the data.
As said in a previous message: The hourly averages are from 2×20 minutes 10 second snapshot voltage readings of the instrument and several minutes of three different calibration gases. These are used to calculate the real CO2 level (accurate to about 0.1 ppmv) for each snapshot value over the 2×20 minutes in the past hour. The average and stdv of these values are presented as hourly values, which still are raw, unaltered, but averaged data.
As there is a maximum of a few tenths of a ppmv change over a day at Mauna Loa if background air is sampled, there is little need to put the many million individual snapshots on line, as the average and the stdv over the past hour shows all information needed. If there is local disturbance either from volcanic outgassing or depleted air from the valley, that will show up in the average and/or stdv. It is that simple.
But if anybody wants to control the calculations (as I did for a few days worth of data), simply ask for the original snapshot voltage data at Pieter Tans of NOAA, he is a very kind person and very willing to answer any questions.