Guest post by Jens Raunsø Jensen
Preamble
Inspired by a statement by Dr. Kevin Trenberth in the e-mails referred to as Climategate 2.0 (#3946 discussed here), it is hoped that climate scientists will have “an open enough mind to even consider” that the global warming of the 20th century could have occurred mainly as abrupt changes in mean temperature linked with natural events. Observational data supports that claim, at variance with the AGW “consensus view”.
Summary
Abrupt or step changes in temperature regime has been the subject of many discussions on this and other blogs and in the peer reviewed literature. The issue is not only statistical. More importantly, any presence of major step changes in mean temperature regime may contradict the claims of the AGW theory and models, i.e. the claims of increasing and accelerating temperature and of human emissions of GHGs being the major cause for the relatively high temperatures in the second half of the 20th century.
In this post, 232 complete and unadjusted GHCN station records are analysed for step changes in the period 1960-2010, and it is argued that:
- Abrupt changes in temperature linked with natural climate events may be widely responsible for the “global warming” during the second half of the 20th century.
- 50% of sample stations have not experienced increased mean temperature (”warming”) for more than 18 years.
- 70% of Europe stations have not experienced warming for more than 20 years.
- The relative role of natural processes in global warming is very likely underestimated by IPCC.
- The global average temperature curve is ”apples and oranges” and is widely misinterpreted using linear trend and smoothing techniques as indicating a pattern of widespread uniformly increasing temperature.
Objective and methodology.
The post is in continuation to my earlier post on the subject (http://wattsupwiththat.com/2011/08/11/global-warming-%e2%80%93-step-changes-driven-by-enso/ ), now including a near-global station level analysis. The post is based on a ppt presentation including additional details given at a researcher’s workshop at University of Copenhagen, 15th November 2011 (http://www.danishwaterforum.dk/activities/Researchers_Day_Climate_Change_Impact_2011.html ).
The objective with this analysis has been (i) to examine the land-based temperature records at station and higher levels for the presence of step changes during the period 1960-2010, and (ii) to assess the implications for our assessment of global warming during that period. Please note that the objective has not been to dismiss a (likely) presence of an anthropogenic warming signal, or to establish a climate model, or to make projections for the future. The issue is step changes in observational data during 1960-2010.
I have used the documented Regime Shift Detection tool of Rodionov (2004, 2006; www.beringclimate.noaa.gov/ ). The results are considered to be statistically robust (ref. the ppt presentation for details on parameter settings and a verification of the assumptions of constant variance and a likely negligible influence of autocorrelation).
The station level data is from GHCN (“after combine”, http://data.giss.nasa.gov/gistemp/station_data/ ) and include ALL stations with a complete record in the period 1960-2010 in broadly defined sampling regions (ref. Fig. 1).
A total of 232 stations were identified, with 54% located in Europe and Russia. The sampling criteria result in wide differences between the “regions” in terms of station number, density and distribution. Also, the “regions” are more or less homogeneous climatologically. However, this is not of material importance for the following discussion and conclusions.
Fig. 1. Distribution of sample stations according to sampling criteria.
Results
Significant step changes are widely found in the T-records and representative examples for 3 “regions” are shown in Fig. 2a-c. The temperature increase in the steps is typically of a size which is comparable to the often quoted global warming during the 20th century.
Fig. 2a. Alaska T-anomaly (n=9). Step, 1977; T-change = 1.5 oC; significance 0.000001
Fig. 2b. Fichtelberg, Europe. Step, 1988; T-change = 1.0 oC; significance 0.00009
Fig. 2c. Malacca, South-East Asia. Steps: 1978, 1990 and 1998; T-change = 0.4+0.3+0.4 = 1.1 oC; significance, 0.0004, 0.0007 and 0.003.
Warming during 1960-2010 was clearly a non-linear process at station level, with the step pattern differing among the “regions”. The global average T-anomaly curve, constructed by averaging across station-level T-anomaly curves, is therefore highly deceptive in propagating a message of near-linearly increasing temperatures, contrary to the actual processes at station level. Thus, the global T-anomaly curve is inherently “apples and oranges” and can not be used to identify a meaningful global AGW trend if the step changes are neglected. Then, the apparent AGW trend will in reality mainly capture the aggregated effect of the sudden step changes (as e.g. in Foster and Rahmstorf, 2011).
The steps are concentrated in few short periods. Disregarding 39 steps after 2005 (considered highly uncertain and “in progress”; 2/3 ups and 1/3 downs), it is found that:
- The steps occur predominantly (58%) in three 3-year periods: 1977/79, 1987/89 and 1997/99 (Fig. 3).
- 72% of all stations, and more than 50% of stations in each “region” (except Arctic), have one or more steps during these periods (e.g. 89%, 56% and 93% of Europe, Russia and South-East Asia stations, respectively; Fig. 4).
- 78% of Europe stations have a step change in 1987/89, during which the major part of the entire warming of the 2nd half of the 20th century apparently took place.
- 2 or 3 steps are common in South-East Asia (especially 1987/89 and 1997/99), but one step only is common in records from Alaska (1977/79), Europe (1987/89) and Russia (1987/89).
Fig. 3. Distribution of step changes by year of change.
Fig. 4. Percent of stations with one or more steps in indicated 3 periods.
Similar step changes are identified in national average records (ref. link to presentation above): US contiguous 48 states (GISS): 1986 and 1998; Australia (BOM): 1979 and 2002; and Denmark (DMI): 1988. The steps in the Global T-records are: Crutem3gl: 1977, 1987 and 1998; GISS L/O: 1977, 1987 and 1998; and Hadcrut3: 1977, 1990 and 1997.
The steps are statistically highly significant. But are they supported by a probable physical cause? The answer must be yes for the majority of steps. The steps occur in a temporal and spatial pattern coinciding with well-documented events and regime changes in the ocean-atmosphere system:
- 1976/77: the great pacific shift from a “cold” to a “warm” mode (e.g. Trenberth, 1990; Hartmann and Wendler, 2005).
- 1987/89 and 1997/99: the two clearly most intense El Niños of the period, 1986/88 and 1997/98, with the intensity here defined as event-accumulated nino3.4 anomalies (NOAA’s ONI index); there were two less intense events in 1982 and 1991, the impact of which was probably occluded by the major volcanoes El Chichon and Mt. Pinatubo.
- A regime shift in NH SST in 1988/89 (Yasunaka and Hanawa, 2005).
- A new regime of constant temperature after the 1997/98 El Niño, i.e. the now widely accepted “hiatus” in global warming.
- Documented step changes and regime shifts in marine ecosystems, e.g. the late 1980s in Europe and in the Japan/East Sea.
- The short-term regionally diverse global impact of ENSO events is generally well-known.
The empirical evidence, from this station level analysis and other sources, is unequivocal: the step changes in mean temperature are likely real and associated with natural events. The physical mechanisms remain to be understood, and this is certainly not to claim, that ENSO events are the only elements of the natural cause-effect chain.
It is therefore concluded, that the major part of the temperature change (global warming) in the 2nd half of the 20th century occurred as abrupt changes in mean temperature associated with natural events in the ocean-atmosphere system. Still, a warming/cooling trend – albeit relatively small compared with the step changes – could of course be hidden by the regime change model. But it seems inconceivable, that steadily increasing CO2 levels could be responsible for the major sudden changes observed as e.g. in Alaska in 1977, Europe in 1988 and South-East Asia in 1998. In principle, the natural events and step changes could have been amplified by human caused warming, but this is currently pure speculation.
Implications when accepting the presence of steps
“Increasing temperature and accelerated warming” : this study does not support general statements like that. The bulk of the “global warming” has likely taken place in abrupt steps, and 50% of the stations analysed has not experienced any significant warming for more than 18 years (Fig. 5). In Europe, 70% of the stations have not experienced significant change in mean temperature for more than 20 years.
In South-East Asia, the median value is 13 years as many stations here also experienced a step change in 1997/98 (Fig. 4).
Fig. 5. Years of constant T-mean prior to 2010. Box-Whisker plot, 1st and 3rd quartiles. (note: uncertain up and down step changes during 2006-2010 are disregarded).
Challenging the IPCC consensus view, i.e.: “Most of the observed increase in global average temperature since the mid-20th century is very likely due to the observed increase in anthropogenic greenhouse-gas concentrations”. However, the finding above, that abrupt changes linked with natural processes likely account for most of the increase in temperature during 1960-2010, contradicts the IPCC claim regarding the relative importance of natural and human causes. Thus, when IPCC (AR4) can only reproduce the T-curve by including GHG effects, then logically
- either the IPCC GCM models do not adequately model the natural processes of high significance for the temperature variations (there is still low confidence in the projection of changes in the ENSO variability and frequency of El Niños, ref. the recent SREX-SPM IPCC report),
- or/and the IPCC has overestimated the climate sensitivity to CO2 changes by eg. attributing natural temperature increases to CO2-induced feed-back processes.
In either case, the relative importance of natural processes for the T-changes has likely been underestimated by IPCC.
Conclusion
This study has established that step changes in land-based temperature records during 1960-2010 are common and very likely real and linked with natural climate events. The step changes are statistically highly significant and with a systematic yet regionally diverse pattern of occurrence coinciding with major climate events and regime shifts. This finding has far reaching consequences for our analysis of climate records and for our assessment of global warming.
Thus, although many different statistical models can be applied to explore the pattern of T-change, the presence of step changes invalidates the widely used statistical techniques of linear trend and smoothing as means of identifying the pattern of temperature variation during 1960-2010.
Furthermore, the step changes account for the main part of the temperature changes during the 2nd half of the 20th century. The logical consequence is that natural processes have been the major cause for the temperature change during this period, leaving a secondary role to other causes such as the anthropogenic greenhouse effect.
The steps occur with an 11-year cycle after solar minima. This is to be expected as the rise to the max reinforces the background warming, while the fall to the min tends to oppose it producing a flat trend as happened in the last decade too. Expect the next step soon unless the solar max is weak.
There may not be a negative step. Just because the system warms with a stepwise process does not in any way mean that it cools with an inverse process.
Pamela Gray says:
January 5, 2012 at 7:22 pm
R Gates, the very fact that you keep referring to rather strong solar influences on these ups and downs of temperatures, and that you appear to be able to “see” it in these swings, makes me question your contention that CO2 has an effect as well.
_______
The two are hardly mutually exclusive, and certainly sometimes work in the same direction, and sometimes work in opposition. CO2 and all greenhouse gases certainly have an effect on climate. To deny this effect is to deny some very basic physics. The only real issue in my mind is the extent to which the 40% increase in CO2, and similar increases in N2O and methane, will have on the climate, and ultimately what effect a doubling of CO2 will have, as that is apparently where we are heading. Anyone who claims they know for certain what effect this will have, after all fast and slower earth system feedbacks are considered, is lying. No one knows for certain, though better and better estimates with higher degrees of confidence will be coming out in the months and years ahead.
R gates,
I would remind you of a mathematical fact that I’m sure you know.
A linear increase of the form T(n) = T(n-1) + C, where “C” is a constant,
Is a reducing NOT a constant RATE of change.
In other words, the annual increase is becoming less and less important for each passing year.
To have a constant RATE of increase would require T(n) = T(n-1)*(1+r)
Where “r” is a value less that one (for example 0.02 ot 2% p.a.).
Even if you ignore the cyclical compoent of the global temperature (cycle length abot 60 years) and the fact that the cycle seems to have peaked and is now heading down once again.
Then the linear component is somwhere in the nature of 0.7 degrees p.a. or about 2% p.a. (expressed in degrees absolute).
This rate of increase is therefore declining on a compound basis, year by year.
But, as somebody with a sould grasp of science, I’m sure that you were well aware of that already.
Ops = there I go again.
Last line should read “sound” rather than “sould”.
I repeat:
“But, as somebody with a sound grasp of science, I’m sure that you were well aware of that already”
thepompousgit says:
January 5, 2012 at 4:28 pm
R. Gates said @ur momisugly January 5, 2012 at 3:18 pm
“Though we’ve not yet found the perfect unification in the laws of quantum effects and gravity, we certainly will someday as such a unification certainly does exist, and it will be as consistent as the very existence of stars, galaxies, and all the rest of the wonderful things that make up this universe.”
R Gates, you seems to know more about these things than Stephen Hawking. When did you receive your Nobel prize in Physics?
_________
My confidence is based on a philosophical perspective more than having a PhD in quantum physics. A ten dimensional model of the universe (with six that are wrapped up) solves many issues and can unite the quantum level and gravity. Hawking, whom I admire very much, is a giant in the field, but younger minds and newer ideas will move this field forward rapidly in the next few years and a truly unified theory is far closer than most might realize. What will blow most peoples mind’s will be the implications, especially regarding the multiverse we live in. Expect evidence of that coming in the next few years…
Leif Svalgaard says:
January 5, 2012 at 10:31 am
Henry Galt says:
January 5, 2012 at 9:38 am
Leif – we emerge from a “little” ice age.
Right, it is called Global Warming
Right, but not ‘anthropogenic global warming’
We are just near the peak of the curve. It’s generally downhill for the next 500 years. Unless the next 50 take us into the overdue glaciation. Unless we are at the end of the ice age and the earth returns to it’s favoured equilibrium around 8C warmer than now.
Place your bets.
http://www.apegga.com/members/Publications/peggs/Web11_02/kyoto_pt.htm
We published this in 2002:
Although the radiosonde record lacks the dense spatial coverage from satellites, it does extend back to 1957, a period that includes the recent rapid rise in atmospheric CO2 concentration. The radiosonde record shows no linear warming trend in global average temperature prior or subsequent to a dramatic shift in 1976-77. That warming, known as the Great Pacific Climate Shift of 1976-1977, is not attributable to human causes but is a natural shift in the Pacific that occurs every 20 to 30 years.
Suppose there are both step-wise changes and a small linear trend. Since the linear trend is smaller than the step-changes, the trend would be hidden by the steps being just a little bit bigger (or smaller).
Conclusion is that you can’t rule out a linear trend unless you can quantify the size of the steps from another data source.
R. Gates said: “Simply put, the greenhouse forcings from the 40% additional CO2, and similar increases in NH2 and N2O are always present and collectively they present that linear rising “baseline” trend that FR2011 found, and around which natural variations from solar, oceans, volcanic can only vary up or down for shorter perids, but they can’t and don’t affect the long-term upward forcing.”
I see. So you’re justifying an assumption with another set of assumptions based on the faulty assumption that H2o feedback must be positive. Brilliant.
“A physicist” wrote:
“The tool that Jensen (the Regime Shift Detection tool) is using tests the null hypothesis that the data points are: (1) normal, (2) stationary, and (3) independent.”
If that is the case (and I have no reason to doubt this information), the use of significance measures is not informative at all. The p-value just gives the probability that this data series (or more extremely differing ones) occurs when we assume that the null hypothesis is true, that is, that the data is (1) normal, (2), stationary, and (3) independent. So here, when we see p = .0000001, we know that it is very unlikely that these data occur if the null hypothesis is correct. Interesting, but that tells us *nothing* about how well the step function fits. In fact, it tells us nothing at all about the step function. What would be much more informative here is the likelihood ratio of p(data|step function) / p(data|null hypothesis).
Cheers, Jan
This seems like a silly post. The temperature is not going up steadily, it has odd unpredictable jumps now and then. Its still going up, and the best candidate to explain it is CO2.
Its as though the author has looked at the motion of a surfer, and tried to explain it while ignoring the wave the surfer is on.
Rex
No, its based on evaluation of all of the NZ temperature records over the full period of measurement. Thats several hundred individual stations, scores of which were active during the 1950’s period.
Excellent work. But, as others have commented – why is this happening?
Yeah, thanks clipe and Lucy, that is the one I found but I thought It was about temperature versus sensor change.
Crispin in Waterloo says: January 5, 2012 at 6:51 am “we are surrounded by climate change carpetbaggers”.
Yes, and there is the possibility that carpetbaggers are paying people to ignore step responses like you have shown and to substitute blame-mankind explanations.
I do not know if that carpetbagger description can be applied to the people connected with this paper. It’s long, but if you ever had doubts about a European-led one world Government, read this:
http://www.newgrowthpath.eu/wp-content/uploads/2011/06/A_New_Growth_Path_for_Europe__Final_Report.pdf
Henry@tallbloke
I have been wanting to ask you:
Do you know if anyone ever measured the change in humidity over the years?
After looking at the daily average readings from about 20 weather stations all over the world I am finding a change of about -0.02%RH per annum, global average.
http://www.letterdash.com/HenryP/henrys-pool-table-on-global-warming
So, if this estimate is reasonably correct, (like I found my estimate of average temp. increase of o.014 degrees C per annum also reasonably correct), then the average global humidity is now about o.75% RH lower than it was 37 years ago.
If I am not mistaken (at 15 degrees C) that translates again to a loss of about 0.1% in absolute humidity.
Note how that compares with the increase in CO2. (0.01% increase over the last 50 years)
Thanks JRJ for a thought-provoking follow-up to your earlier post on step changes. Judging by the way you’ve brought the trolls out after their Christmas/New Year hibernation, there would seem to be something here worth looking at.
That ‘Great Pacific Shift’ of 1976/77 continues ti intrigue me. Those of us who were in the UK in the summer of ’76 will remember it as a blisteringly, most un-Britishly hot summer, when we had to learn to complain about the heat rather than the rain [grin]. Do we know what happened around then on the planetary or solar scale, since it seems to have upped Earth’s overall energy level so noticeably? Presumably, what goes up will come down at some point, and it would be nice to have some idea what precursor(s) to look for.
“No more stupid than saying that carbon dioxide back radiates when in practice if you look at the spectrum from the surface of the earth there is no back radiation to be seen!”
It’s literally insane to deny the existence of something that’s been known for decades. Do a web search for “infrared sky spectrum”.
Amazing that not a single commenter appears to have realised that “abrupt changes in mean temperature” are expected, predicted and observed in response to smooth changes in climate forcings. The temperature history of the Earth does not merely show such changes; it’s dominated by them. Some people call them “tipping points”.
Alan Statham says:
January 5, 2012 at 6:17 am
This is laughable. Your starting premise – “any presence of major step changes in mean temperature regime may contradict the claims of the AGW theory and models” – is wrong. You’ve used an arbitrary subset of the available data….
Like “The last 2000 years” or “the last 30 years” or “the last 150 years”? The whole damn scientific discipline has been predicated on arbitrary data choices.
AusieDan says:
January 5, 2012 at 9:57 pm
R gates,
I would remind you of a mathematical fact that I’m sure you know.
A linear increase of the form T(n) = T(n-1) + C, where “C” is a constant,
Is a reducing NOT a constant RATE of change.
In other words, the annual increase is becoming less and less important for each passing year.
To have a constant RATE of increase would require T(n) = T(n-1)*(1+r)
Where “r” is a value less that one (for example 0.02 ot 2% p.a.).
Even if you ignore the cyclical compoent of the global temperature (cycle length abot 60 years) and the fact that the cycle seems to have peaked and is now heading down once again.
Then the linear component is somwhere in the nature of 0.7 degrees p.a. or about 2% p.a. (expressed in degrees absolute).
This rate of increase is therefore declining on a compound basis, year by year.
But, as somebody with a sould grasp of science, I’m sure that you were well aware of that already.
~~~~~~~~~
You make a good point related to the characterization of the underlying linear rise in temperature found by FR2011. The rate of increase is linear over the period they looked at and was in the range of 0.014 to .018 K per year. So it is not put in percentage terms, but a simple linear rate over this period, which obviously would be a smaller percentage as temperatures increase. More interesting to me is the question as to whether this underlying rise is truly linear, as the period studied is far too short to really know. If it is being caused by increases in greenhouse gases, then this increase over a longer time frame surely is not actually linear, as certainly it didn’t start out at the current rate with the very first increases in anthropogenic greenhouse gases back in the 1750’s.
There is nothing unusual happening to weather or climate in the last 50 or 100 years or 1000 or 100,000 years – it has all happened before, over and over again.
Attempts to state otherwise have relied on faulty, false and/or fraudulent analyses.
Here, I think, is the bigger picture.
The “mainstream argument” of the climate skeptics is:
There is no real evidence of positive feedback,
AND
there is real evidence of negative feedback,
SO
the probability is “climate sensitivity” is ~1 degree C or LESS
which is OK (we said this in 2002*),
IF
one accepts the mainstream argument;
BUT
there is perhaps a much bigger problem with the mainstream argument:
Atmospheric CO2 LAGS temperature at all measured time scales**,
SO
the hypothesis that CO2 is a significant driver of global temperature apparently assumes that the future is causing the past. This assumption should cause some concern, in my opinion.
The popular counterarguments are:
a) This lag of CO2 after temperature is a “feedback effect”,
OR
b) The Principle of Uniformity of Nature has recently been rescinded;
OR
c) Occam’s Razor can safely be disregarded in this instance;
OR
d) This lag is clear evidence that time machines really do exist.
All four counterarguments a) to d) are supported by equal amounts of compelling evidence. 🙂
Earth has seen no significant global warming for a decade or so. Score one for the skeptics.
In fact, not one of the IPCC’s scary global warming and extreme weather predictions has materialized – a perfect track record – of false alarms.
By the way, in 2003 I wrote that global cooling would soon recur. Faites vos jeux!
_______________________________________________________________
*
http://www.apegga.com/members/Publications/peggs/Web11_02/kyoto_pt.htm
**
http://icecap.us/images/uploads/CO2vsTMacRae.pdf
John Brookes says
The temperature is not going up steadily, it has odd unpredictable jumps now and then. Its still going up, and the best candidate to explain it is CO2.
Henry @ur momisugly John
John, my data set (after statistical analysis of 20 weather stations) shows that maxima, means (=average temps) and minima have risen at a ratio of 7:3:1
http://www.letterdash.com/HenryP/henrys-pool-table-on-global-warming
If more CO2 or more GHG were to be blamed for the warming, should that ratio not be the other way around?
tallbloke says:
January 5, 2012 at 11:42 pm
We are just near the peak of the curve. It’s generally downhill for the next 500 years. Unless the next 50 take us into the overdue glaciation. Unless we are at the end of the ice age and the earth returns to it’s favoured equilibrium around 8C warmer than now.
Place your bets.
_____
“Peak of the curve”? No evidence of such.
“Downhill next 500 years.” No evidence of such.
“..next 50 take us into overdue glaciation…” Definitely no evidence of such.
“…end of the Ice Age…” Not by natural variability or Milankovitch cycles or continental configuration, so if we are, it will come through sensitivity to anthropogenic greenhouse gas forcing being much much higher than anyone really can see right now. If this is the case, it will still take quite a while to melt all that continental ice in Greenland and Antarctica.