Tuesday, November 11, 2014

New paper finds natural climate change is up to 50 times more variable than climate models predict

A new paper published in PNAS finds Earth's climate was much more variable over the past 7,000 years than previously thought:
"The consequence: either the analysed climate archives supply inaccurate temperature signals, or the tested models underestimate the regional climate fluctuations in the Earth's recent history. 
"on a millennial time scale, conventional climate models underestimated the variations of sea surface temperatures reconstructed from climate archives by a factor of 50." 
"Fundamentally, there are only two explanations," says Thomas Laepple. "Either the climate archives do not provide reliable temperature data, or the climate models underestimate the variability of the climate. Or both may be true to some extent." The results are based on a number of independent climate archives, as well as instrumental records, and hold up whilst applying a wide range of correction methods, which leads Laepple to believe that the problem lies more with the models. 
"We seem to have to revise upward predictions of how much climate can regionally vary,"
A larger role for natural variability as strongly suggested by this study necessarily means a smaller role for CO2 radiative forcing of climate. 


How variable are ocean temperatures?

New study shows significant differences between climate archives and climate models

 IMAGE: This image shows scientists analyzing a sediment core.
Click here for more information.
Potsdam/Bremerhaven, 10 November 2014. 

The earth's climate appears to have been more variable over the past 7,000 years than often thought. This is the conclusion of a new study forthcoming online this week in the U.S. scientific journal "Proceedings of the National Academy of Sciences" (PNAS)

In the study, scientists from the Potsdam-based Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, and Harvard University show that sea surface temperatures reconstructed from climate archives vary to a much greater extent on long time scales than simulated by climate models. The consequence: either the analysed climate archives supply inaccurate temperature signals, or the tested models underestimate the regional climate fluctuations in the Earth's recent history.

In order to reconstruct climate history, it is necessary to study natural climate archives since, in terms of the Earth's history, humankind has only very recently begun measuring the planet. There have been instrumental measurements of ocean temperatures for only around 150 years now. For periods prior to that, scientists have to rely on "proxies", i.e. indicators enabling indirect conclusions to be drawn about climate data from earlier times. Such climate archives generally refer to spatially limited areas and differ in their temporal resolution. They may also include significant "background noise".

"In our study we weren't interested in how warm the climate might have been at time X in a specific region. We wanted to retrospectively analyse how much the regional climate temporally varies over decades to millennia," explains Dr. Thomas Laepple from the Alfred Wegener Institute. "One of our biggest challenges was to make it possible to compare various measured data and climate archives from a wide variety of regions and filter out the natural noise that can greatly distort the signal of climate archives."

Laepple and his colleague Peter Huybers from Harvard University compared data from temperature measurements, corals and sediment cores originating from many different marine regions of the world. Climate data from modern corals date back no more than 400 years. They allow conclusions to be made about temperature changes over decades or centuries. Marine sediments may contain much older data, but generally only achieve a centennial or millennial resolution. Using different calibration and filtering processes, the two researchers succeeded in combining a wide variety of available data from temperature measurements and climate archives in such a way that they were able to compare the reconstructed sea surface temperature variations at different locations around the globe on different time scales over a period of 7,000 years.

"We initially determined that the natural variations of ocean temperatures are surprisingly large - and the longer the periods we analysed, the greater the variations," was the initial conclusion of the two scientists. Then, in a second step, they studied around 20 climate models in over 100 test runs to ascertain how well the models can simulate these temperature variations. The result: measured and climate archive data closely correspond to model runs for periods of years. Toward longer timescales, however, discrepancies grow - most significantly in tropical marine regions. On a millennial time scale, conventional climate models underestimated the variations of sea surface temperatures reconstructed from climate archives by a factor of 50.

"Fundamentally, there are only two explanations," says Thomas Laepple. "Either the climate archives do not provide reliable temperature data, or the climate models underestimate the variability of the climate. Or both may be true to some extent." The results are based on a number of independent climate archives, as well as instrumental records, and hold up whilst applying a wide range of correction methods, which leads Laepple to believe that the problem lies more with the models.

"We seem to have to revise upward predictions of how much climate can regionally vary," suggests Thomas Laepple, based on his findings. "Given the huge amount of greenhouse gases released into the atmosphere, we can be sure that it is getting warmer globally. But the range of changes we are headed for could well be larger than we have generally expected." This has to do with the fact that the natural variations in combination with the warming trend always point in both directions: over a period of decades or a hundred years temperatures in a particular region may rise to a lesser or greater degree than present-day climate models generally forecast.

Since this is a central issue for the forecasting of future climatic conditions on the Earth, for about a year now the physicist in Potsdam has been heading an interdisciplinary research group that focuses specifically on this topic. It is called "ECUS - Estimating climate variability by quantifying proxy uncertainty and synthesizing information across archives".

According to Laepple: "We are in the middle of an experiment that we cannot reverse, but which we still don't understand well enough to make clear statements at the regional level on longer time scales. Unfortunately, we will just have to continue to live with this uncertainty for some time."
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Authors and title: Thomas Laepple und Peter Huybers: Ocean surface temperature variability: Large model-data differences at decadal and longer periods. DOI: 10.1073/pnas.1412077111 (Link: http://www.pnas.org/cgi/doi/10.1073/pnas.1412077111 or in the online early edition unter http://www.pnas.org/content/early/recent)

Ocean surface temperature variability: Large model–data differences at decadal and longer periods

  1. Peter Huybersb
  1. Edited by Mark H. Thiemens, University of California, San Diego, La Jolla, CA, and approved September 23, 2014 (received for review July 14, 2014)

Significance

Determining magnitudes of sea surface temperature variability is important for attributing past and predicting future changes in climate, and generally requires the use of proxies to constrain multidecadal and longer timescales of variability. We report a multiproxy estimate of sea surface temperature variability that is consistent between proxy types and with instrumental estimates but strongly diverges from climate model simulations toward longer timescales. At millennial timescales, model−data discrepancies reach two orders of magnitude in the tropics, indicating substantial problems with models or proxies, or both, and highlighting a need to better determine the variability of sea surface temperatures.

Abstract

The variability of sea surface temperatures (SSTs) at multidecadal and longer timescales is poorly constrained, primarily because instrumental records are short and proxy records are noisy. Through applying a new noise filtering technique to a global network of late Holocene SST proxies, we estimate SST variability between annual and millennial timescales. Filtered estimates of SST variability obtained from coral, foraminifer, and alkenone records are shown to be consistent with one another and with instrumental records in the frequency bands at which they overlap. General circulation models, however, simulate SST variability that is systematically smaller than instrumental and proxy-based estimates. Discrepancies in variability are largest at low latitudes and increase with timescale, reaching two orders of magnitude for tropical variability at millennial timescales. This result implies major deficiencies in observational estimates or model simulations, or both, and has implications for the attribution of past variations and prediction of future change.

5 comments:

  1. The temperature projections of the IPCC forecasts have no foundation in empirical science being derived from inherently useless and specifically structurally flawed models. They provide no basis for the discussion of future climate trends As a foundation for Governmental climate and energy policy their forecasts are already seen to be grossly in error and are therefore worse than useless.
    We cannot begin to estimate what contribution anthropogenic CO2 might make to warming temperatures until we know where we stand in relation to the natural cycles.A new forecasting paradigm based on the natural long term variations in the temperature record needs to be adopted. See

    http://climatesense-norpag.blogspot.com/2014/07/climate-forecasting-meth...

    This post provides forecasts of the probable 650 years of coming cooling based on the 60 and 1000 year natural periodicities ( Figs 5 and 15 in the link) clearly seen in the temperature data and using the 10 Be and neutron record as the most useful proxy for solar “activity” on recent millennial time scales . We are just past the peak of the latest 1000 year cycle The simplest working hypothesis is that we are about to repeat the general temperature trends from 1000 AD on. I suggest all readers check the data in the link and form their own opinions.

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  2. The money quote for me is found in the Conclusions:

    "Insomuch as models underestimate natural SST variability, tests for anthropogenic effects will tend to be biased positive."

    So very solid support for the idea that the models underestimate natural variation.

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  3. Substantially the same paper with free access from the EGU 2012 Conference.

    How variable is the Holocene? (2012)
    Laepple, T.; Huybers, P.

    http://meetingorganizer.copernicus.org/EGU2012/EGU2012-9080.pdf


    "Determining the magnitude of natural climate variability is necessary for predicting the plausible range of future climates. While the instrumental record is too short to determine slow climate variations, climate archives of the Holocene can provide information about the variability on decadal to millenial timescales in interglacial boundary conditions. We present a global comparison of marine temperature variability derived from instrumental data, corals and sediment cores and a range of general circulation model (GCM) simulations. The results indicate that current models systematically underestimate the variance in regional ocean temperature variability during the mid-late Holocene, with the discrepancy increasing from decadal to millennial timescales to more than an order of magnitude. The possibility that the greater variability results from noise in temperature proxies is rejected after analysis of the covariability between instrumental temperature records and coral, alkenone, and Mg/Ca proxies of temperature. The balance of evidence indicates that internal climate variability is much larger than simulated by GCMs on decadal and longer timescales, though the sensitivity of the climate system and magnitude of external forcing could also be greater at multi-decadal and longer timescales than presently accounted for in GCMs. In either case, these results suggest that model simulations are biased toward showing a too stable climate. "

    http://adsabs.harvard.edu/abs/2012EGUGA..14.9080L

    Geophysical Research Abstracts
    Vol. 14, EGU2012-9080, 2012
    EGU General Assembly 2012

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  4. Apologies. Just the abstract of the Conference article;

    ReplyDelete