By Dr. David Whitehouse The GWPF (video follows)
Warming Interruptus
What is the reason for the lack of warming observed at the surface of the Earth since about 1997? Many causes have been proposed, and with increasing frequency, but most only rep- resent partial explanations. There are clearly more putative causes than can possibly be the case.
The pause has given climate science several things. It has provided a reassessment of the importance of natural climatic variability and its relationship to human influences on the climate. It has also shed light on the role of so-called sceptics as well as the successes and failures of climate communication.
Here are the current explanations for what has been called the biggest problem in climate science.
There is no pause
Some argue that the pause does not exist and that the warming trend seen to commence around 1980 has continued linearly with predictable variance around the mean. Of course it is possible to draw a straight line through most sets of data and attempt to justify it. However the length of the pause – 17 years – means that it cannot reasonably be regarded as part of a linear trend since 1980, so this explanation no longer works.¹
Low solar activity
Placing the role of solar activity in recent climate has been problematical. It is obvious that that periods of low solar activity in the past have coincided with cooler climatic conditions. Examples include the Dalton solar minimum around 1800 and the Maunder minimum in the 17th century (now shown to undoubtedly be a global event). Prior to about 1960 solar ac- tivity played a major role in the Earth’s climate, but in recent decades the IPCC has declared that it plays only a minor part, being dwarfed by human influences on the climate. So what is to be made of the recent decline in solar activity from the relatively high levels in the late 20th century? Some believe that the sun is entering a lengthy period of low activity as it has done in the past. Curiously, the commencement of that low activity coincides with the pause in global surface temperature. There are indications that almost all climate models underplay the effect of solar activity. Some have asked how, if the slight increase in total solar irradiance over the past 30 years cannot cause the warming, it can have contributed to the pause. This effect is likely to be relatively short lived. ²
As one paper on the subject put it:
The purpose of this communication is to demonstrate that the reduced rate in the global temperature rise complies with expectations related to the decaying level of solar activ- ity according to the relation published in an earlier analysis Without the reduction in the solar activity-related contributions the global temperatures would have increased steadily from 1980 to present.
The IPCC Fifth Assessment report estimates that despite the decline in solar output since 2000, total warming influences have increased faster since 1998 than over 1951–1998 or 1971–1998.
The heat is in the oceans
The most cited explanation for the pause is that the warming has gone into the oceans, and indeed the oceans are expected to absorb far more energy from the greenhouse effect than the land. But while the oceans have warmed in the past few decades, the extent to which this is due to mankind is debateable and the ocean heat content data is not behaving as some expected.
The best data we have is from the ARGO project. It goes back ten years and shows no warming in the uppermost layers of the oceans, and only modest warming down to 1800 m. If more heat is there it must be at deeper levels, where it is far harder to detect, and where it may well be locked out of the way for a thousand years. ³
Pacific decadal oscillation/Atlantic multidecadal oscillation
The Pacific decadal oscillation (PDO) switches from warm to cool every 30 years or so. It went positive in 1976–98 and has been mostly negative since about 2000. Given the Pacific’s pos- tulated influence on global climate this might indicate that the pause will continue until the PDO changes again, which will be in 15–20 years. A similar effect has also been suggested for the 60–70-year Atlantic multidecadal oscillation. (4)
Stratospheric water vapour
A very interesting paper suggests that natural variations in stratospheric water vapour could be responsible for about a third of the 1980–98 warming phase. Lead author Susan Solomon, of the US National Oceanic and Atmospheric Administration, said:
Current climate models do a remarkable job on water vapour near the surface. But this is different – it’s a thin wedge of the upper atmosphere that packs a wallop from one decade to the next in a way we didn’t expect.
Solomon and her co-authors concluded that decreases in stratospheric water vapor concentrations acted to slow the rate of increase in global surface temperature over 2000–9 by about 25% compared to the warming that would have occurred due only to carbon dioxide and other greenhouse gases.
More limited data suggest that stratospheric water vapour probably increased between 1980 and 2000, which would have enhanced the decadal rate of surface warming during the 1990s by about 30% compared to estimates neglecting this change. (5) However, the IPCC Fifth Assessment report shows very little warming from stratospheric water vapour over 1980– 2000 and no cooling from it over 2000–2010.
Chinese coal
Kaufman et al. (2012) suggest that the increased burning of coal in China is producing aerosols that are cooling the world. Others suggest this conclusion uses computer model data that has been cherrypicked to give the required result. It also does not include the latest solar data. (6,7) Moreover, the IPCC Fifth Assessment report does not support this finding.
The Pacific and the La Niñas
Some scientists suggest that recent cooling in the eastern equatorial Pacific reconciles cli- mate simulations and observations. Although they consider only 8.2% of the global surface they maintain that their computer model reproduces the annual-mean global temperature remarkably well for 1970–2012, a period that includes the current hiatus and a period of ac- celerated global warming. They postulate that the pause is part of natural climate variability, tied to a La-Niña-like decadal cooling. Although similar decadal hiatus events may occur in the future, they say, the multidecadal warming trend is very likely to continue due to man’s influence on the climate. (8)
Stadium waves
In this idea the extent of sea ice in the Eurasian Arctic enhances or dampens the long-term trend in rising temperature. Such changes introduce a low-frequency climate signal, which propagates across the Northern Hemisphere through a network of synchronised climate in- dices. The tempo of its propagation is rationalised in terms of the multidecadal component of Atlantic Ocean variability – the Atlantic multidecadal oscillation. The authors of the stadium wave paper say, ‘the Eurasian Arctic Shelf-Sea Region, where sea ice is uniquely exposed to open ocean in the Northern Hemisphere, emerges as a strong contender for generating and sustaining propagation of the hemispheric signal’. This explanation suggests that the pause should end in the 2030s. (9)
Arctic stations
Could it be that the pause is an artefact of poor spatial sampling? This is the suggestion from Cowtan and Way (2013). They compare different ways of accounting for the lack of weather- station data in various regions of the globe, principally the Arctic. They maintain that when the data are infilled the pause goes away and that the warming rate is similar to that seen in the 1990s.
The problem with this approach is that it involves creating a hybrid dataset using different infilling techniques for different regions, leaving it open to suggestions of cherrypicking. (10,11)
Pacific trade winds
According to some scientists a key component of the pause has been identified as the cool eastern-Pacific sea-surface temperature, even though it is not clear how this ocean has re- mained cool despite the long-term warming effect on the climate due to human activity. It is contended that there has been a strengthening in Pacific trade winds over the past two decades that has not been factored into climate models and that when these changes are made the effect is sufficient to account for the cooling of the tropical Pacific and a substan- tial slowdown in surface warming through increased subsurface ocean heat uptake. The sci- entists who suggest this have used model-based ocean temperature ‘reanalyses’, not mea- surements, and the mechanism involved implies the heat uptake in the top few hundred metres of the ocean should have increased during the pause, but measurements suggest otherwise. (12)
Note also that a few years ago other scientists were suggesting the opposite: that weak trade winds were responsible for the pause. (13)
Volcanoes
Since Mt Pinatubo in 1991 there have been no volcanic eruptions sufficiently large to obvi- ously reduce global temperatures. However, it has been argued that there has been a num- ber of smaller eruptions, the cumulative effect of which might partly account for the pause. This is the argument of Santer et al. (2014). However, these authors estimate this is likely to have caused only a 15% reduction in the temperature trend since 1998, only a fraction of the actual reduction. (14,15)
A coincidence!
It has been suggested that the computer climate predictions are running too warm because they are not properly accounting for volcanic aerosols, aerosols in general, solar activity and the effects of El Niños. In a recent Nature commentary, Schmidt et al. suggest that, taking these climatic influences together, they can completely explain the pause. The problem with this approach is that other influences are ignored and a non-unique combination of factors has been cherrypicked to provide the explanation. (16)
Notes
1 http://www.lse.ac.uk/GranthamInstitute/Media/Commentary/2012/october/myth-that-global-warming-stopped-in-mid-1990s.aspx
2 http://www.scirp.org/journal/PaperInformation.aspx?PaperID=41752
3 http://onlinelibrary.wiley.com/store/10.1002/2013EF000165/asset/eft24.pdf
4 http://www.pnas.org/content/110/6/2058.full.pdf
5 http://www.thegwpf.org/water-vapour-and-the-recent-global-temperature-hiatus/
6 http://wattsupwiththat.files.wordpress.com/2011/07/pnas-201102467.pdf
7 http://www.cawcr.gov.au/staff/jma/Decadal.trends.Meehl.JClim.2013.pdf
8 http://www.nature.com/nature/journal/vaop/ncurrent/full/nature12534.html
9 http://judithcurry.com/2013/10/10/the-stadium-wave/
10 http://www.thegwpf.org/pause/. 11http://onlinelibrary.wiley.com/doi/10.1002/qj.2297/abstract. 12http://www.thegwpf.org/pacific-pause/
13 http://www.nature.com/nature/journal/v441/n7089/abs/nature04744.html
14 http://www.thegwpf.org/volcanoes-20-year-pause/
15 http://www.nature.com/ngeo/journal/v7/n3/full/ngeo2098.html.
16 http://www.nature.com/ngeo/journal/v7/n3/full/ngeo2105.html
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“jai mitchell says:
March 27, 2014 at 3:32 pm
…is still very high and is being measured to increase.”
Too funny!
“The amount of extra heat going into the ocean will not now go back into the atmosphere and warm it. It will stay in the ocean. However, the extra amount of heat going into the ocean shows that the amount of extra heat being taken up by the entire earth (air land AND oceans) is still very high and is being measured to increase.”
Last interglacial period was had average ocean temperature a couple of degrees warmer than our current average ocean temperature. And during this time there was not billions of people nor were burning coal.
One can assume that ocean will warm during interglacial periods [and tend to cool in glacial periods] and it has nothing to do with CO2 levels [other than CO2 levels also tend to rise during interglacial periods- there is correlation rather than causation].
But if increased levels of present CO2 do increase ocean average temperature it will require thousands year to increase the average ocean temperatures which are around 3 C by couple degrees. Or in terms of next couple centuries warming the ocean is essential not having much effect upon Earth’s average temperature.
Mechanisms which cause ocean water to mix can seen as short term cooling and long term warming. If ocean were to be completely mixed, average global temperature would be lowered
significantly.
It seems to me that possible some mechanism of mixing oceans is a factor in causing or related the various cooling periods during our interglacial period. Therefore the latest cool period, known as Little Ice Age may have involved more mixing of the ocean, the warming of 20 century
can less ocean mixing and thereby slight increases in average air temperature. And in short term [centuries] CO2 level could nothing to do with the warming after the Little Ice Age [after 1850].. And instead average surface temperature could be controlled cycles of increased or decreased amounts of ocean mixing.
Or climate and global is in fact all about earth’s ocean and little to do with the atmosphere. Atmosphere is weather, and oceans are climate.
Steven Mosher says:
March 27, 2014 at 12:02 am
1. they use a technique suggested by skeptics
2. they do essentially the same thing that Jeff ID, Ryan ODonnel and Steve Mcintyre did in their antartic paper.
3. Their prediction for unsampled areas was VALIDATED using out of sample data.
4. I’ve checked their work against another satillite data set which supports their work
5. Cosimo’s recently published trends in arctic surface temperature from AVHRR shows the same or even more warming
Are you “cherry picking” your very own “skeptics” to ridicule out of spite, your alarmist palls have made an incredible amount of progress into fantasy land, there’s no reverse psychology allowed! Man made global warming alarmists are wrong it’s a fact.
By the way learn to spell “satillite” correctly. ffs.
Since the bulk of the reported warming is an artifact of corrupted records and station output (UHI), the Pause is really just business as usual that hasn’t been overwritten with fudged data.
Joachim Seifert says
http://wattsupwiththat.com/2014/03/26/warming-interrruptus-causes-for-the-pause/#comment-1599850
e.g.
Spectral analysis of reconstructed temperature for the last 1420 years and instrumentally measured for the last 140 years global dT shows that dominant period for its variations for the last 1000 years lies in the 50-60 years interval. Modelling of roughly 60-years cyclic dT changes suggest that the observed rise of dT will flatten in the next 5-10 years, and that we might expect a lowering of dT by nearly 1-0.15°C to the end of the 2020s.
Henry says
Lower anomalies a bit confusing there for me. How much is it in T?
Time also disputed. I believe it might be until the end of the 2030s
My very own findings
http://blogs.24.com/henryp/2013/02/21/henrys-pool-tables-on-global-warmingcooling/
seem to suggest a longer cycle time , at least looking at energy allowed through the atmosphere
(maxima)
My results suggest that earth is most likely on an 87 or 88 year A-C wave, the so-called Gleissberg solar/weather cycle, with ca. 44 years of warming followed by 44 years of cooling.
http://blogs.24.com/henryp/2012/10/02/best-sine-wave-fit-for-the-drop-in-global-maximum-temperatures/
Indeed, I hope that this is the best fit for my data, because any of the other best fits that I could think of, would have us end up in much more global cooling. Other investigations confirm the very existence of the Gleissberg solar/weather cycle.
http://www.nonlin-processes-geophys.net/17/585/2010/npg-17-585-2010.htmlhttp://www.nasa.gov/vision/earth/lookingatearth/nilef-20070319.html
this 88 year solar/weather cycle was already calculated from COSMOGENIC ISOTOPES as related in this study:
Persistence of the Gleissberg 88-year solar cycle over the last ˜12,000 years: Evidence from cosmogenic isotopes
Peristykh, Alexei N.; Damon, Paul E.
Journal of Geophysical Research (Space Physics), Volume 108, Issue A1, pp. SSH 1-1, CiteID 1003, DOI 10.1029/2002JA009390
Among other longer-than-22-year periods in Fourier spectra of various solar-terrestrial records, the 88-year cycle is unique, because it can be directly linked to the cyclic activity of sunspot formation. Variations of amplitude as well as of period of the Schwabe 11-year cycle of sunspot activity have actually been known for a long time and a ca. 80-year cycle was detected in those variations. Manifestations of such secular periodic processes were reported in a broad variety of solar, solar-terrestrial, and terrestrial climatic phenomena. Confirmation of the existence of the Gleissberg cycle in long solar-terrestrial records as well as the question of its stability is of great significance for solar dynamo theories. For that perspective, we examined the longest detailed cosmogenic isotope record—INTCAL98 calibration record of atmospheric 14C abundance. The most detailed precisely dated part of the record extends back to ˜11,854 years B.P. During this whole period, the Gleissberg cycle in 14C concentration has a period of 87.8 years and an average amplitude of ˜1‰ (in Δ14C units). Spectral analysis indicates in frequency domain by sidebands of the combination tones at periods of ≈91.5 ± 0.1 and ≈84.6 ± 0.1 years that the amplitude of the Gleissberg cycle appears to be modulated by other long-term quasiperiodic process of timescale ˜2000 years. This is confirmed directly in time domain by bandpass filtering and time-frequency analysis of the record. Also, there is additional evidence in the frequency domain for the modulation of the Gleissberg cycle by other millennial scale processes.
Note that the results of my plot suggest that this global cooling already started in 1995 as far as energy-in is concerned and will last until ca. 2038. Also, from the look at my tables, it looks earth’s energy stores are depleted now and average temperatures on earth will probably fall by as much as what the maxima are falling now. I estimate this is about -0.3K in the next 8 years and a further -0.2 or -0.3K from 2020 until 2038. By that time we will be back to where we were in 1950, more or less…
PS @Joachim Seifert
(belongs on the bottom of my previous comment)
I have no idea why Anthony rejects the older studies that were actually completely confirmed by my own studies, like this one here:
http://www.cyclesresearchinstitute.org/cycles-astronomy/arnold_theory_order.pdf
to quote from the above paper:
“A Weather Cycle as observed in the Nile Flood cycle, Max rain followed by Min rain, appears discernible with maximums at 1750, 1860, 1950 and minimums at 1670, 1800, 1900 and a minimum at 1990 predicted.
The range in meters between a plentiful flood and a drought flood seems minor in the numbers but real in consequence….
end quote
According to my table for maxima, I calculate the date where the sun decided to take a nap (that is just a figure of speech, in fact it is probably a “wake-up”), as being around 1995, and not 1990 as William Arnold predicted.
This is looking at energy-in. I think earth reached its maximum output (means) a few years later, around 1998/1999.
Anyway, either way, (a few years error is fine!), look again at my best sine wave plot for my data,
now see:
1900 minimum flooding – end of the warming
1950 maximum flooding – end of cooling
1995 minimum flooding – end of warming.
predicted 2035-2040 – maximum flooding – end of cooling.
There is a clear and pertinent correlation with the best fit sine wave that I proposed for the observed current drop in global maximum temperatures.
He (Arnold) further suggests that it is mainly the position of the two planets Saturn and Uranus that can be directly linked to the 22 year solar cycle. I looked at this again. At first the dates did not make sense.
Observe from my a-c curves:
1) change of sign: (from warming to cooling and vice versa)
1904, 1950, 1995, 2039
2) maximum speed of cooling or warming = turning points
1927, 1972, 2016
Then I put the dates of the various positions of Uranus and Saturn next to it:
1) we had/have Saturn synodical with Uranus (i.e. in line with each other)
1897, 1942, 1988, 2032
2) we had complete 180 degrees opposition between Saturn and Uranus
1919, 1965, 2009,
In all 7 of my own results & projections, there is an exact 7 or 8 years delay, before “the push/pull ” occurs, that switches the dynamo inside the sun, changing the sign….!!!! Conceivably the gravitational pull of these two planets has some special lob sided character, causing the actual switch. Perhaps Uranus’ apparent side ward motion (inclination of equator by 98 degrees) works like a push-pull trigger. Either way, there is a clear correlation. Other synodical cycles of planets probably have some interference as well either shortening or extending the normal cycle times a little bit. So it appears William Arnold’s report was right after all….(“On the Special Theory of Order”, 1985).
That the gravitational pull of the planets on the sun has influence on our weather here on earth brings us to an important point: what happens if for any reason the gravitation of our planets goes out of the current balance, for whatever reason?
Warming Interruptus!
Thanks for the good laugh, this pearl has potential to stick 🙂
Jai, thank you for the response. It makes no sense, but thank you.
First, I never questioned that water vapor and CO2 are greenhouse gases, so I’m not sure why you chose to speak to that instead of the question that I asked.
You said that the water in the deep ocean has retained heat equivalent to 25F of atmospheric warming. I asked for any reference that shows that CO2 is capable of trapping that much heat at today’s levels. If you’re saying that 90% of the heat was always expected to be sequestered in the ocean then prove that assertion with any citation.
If you’re not completely evading the question you have to admit that there’s a problem with finding that much extra heat anywhere. If you’re going to attribute it to CO2 then you have show radiative transfer calculations that show that GHG’s could have produced incredible surface/atmospheric warming, but that almost all of that heat (luckily) was mixed down to the deep ocean. If you can’t show that then you have another serious problem. Something created a whole bunch of extra heat and it wasn’t CO2. If that’s the case then we have a source of natural variability that utterly overwhelms GHG’s and makes any effort to reduce them irrelevant.
As you may have guessed, I’m skeptical about those measurements. Saying that the floats can measures temperature to an accuracy of .002C isn’t the issue. The problem is that you have to have adequate spatial coverage to know that the combined measurements retain that level of precision. I don’t believe that they do, but I’m willing to allow you that point for the sake of argument.
So, assuming that the data are correct, how does an additional 100PPM of CO2 retain that much heat? Cite something that shows that the heat distribution was well known and therefore no one worried that somehow a large part of the 25F would actually occur. If you can’t do that then explain why we should worry about CO2 at all when some other natural process is perfectly capable of creating heat that’s several orders of magnitude greater than the proposed effect of GHG’s.
(BTW, thanks so much for the information about China’s pollution problem. As long as we’re exchanging information that’s completely irrelevant to the discussion at hand, here’s a link to some well-known chess openings:
http://www.chess.com/openings/)