I’ve been hearing cries desperate for some
serious stats, so here you are, we can look to the numbers for help….
Systems that have an internal feedback
mechanism can often principally behave in a non-linear fashion. Given the
complex nature of climate on earth, one can come to expect such actions.
Abrupt shifts on climate conditions were
first discovered at high latitudes in the Northern Hemisphere when
investigating Greenland ice cores. On
long timescales of roughly 100,000 years the seemingly fast changing
glacial-interglacial cycles, and on the relatively shorter time scale of
approximately 2,000 years the occurrence of Dansgard-Oeschger events (rapid
warming followed by gradual cooling) are
striking evidence for such non-linear behaviour.
Nevertheless it is common practice to
publish linear trends from many global data sets without considering their
relevance. The classical example is the often cited (IPCC, 2007) global warming
trend of 0.05°C/decade for air temperature during the last 150 years.
Using a structural test based on the F statistics
(not important for us but it’s a test of data with an F distribution under a
null hypothesis) Stips and Lilover were able to
test for ‘break points’. They show that
most analysed global climate time series contain
statistical significant changes (breaks in the mean or in the slope of linear
regression). Thus revealing the existence of break points for most investigated
parameters of relatively recent climate science. Breakpoints which are detected
at a comparable time in many different regional and global climate variables
are a strong indication for the existence of a regime shift in the state of the
climate, and so could be very telling.
Fig. 1 Time series of global annual air temperature
anomalies. The straight bold black line is the trend from the linear
regression, which does not provide a satisfactory fit to the data. The test for
breakpoints in the trend finds a significant breakpoint at 1976. The very
different slope of the regression lines (approximate factor 10 different)
for the data before 1976 and after 1976 (green lines) is clearly visible.
Looking above the time series of global
land air temperatures plotted in figure 1 together with the calculated linear
trend of -0.05k/decade (black solid straight line) which is statistically significant.
The inadequacy of the above linear trend model over such a long period is
obvious when looking at the difference of the observed 2009 mean temperature to
that estimated from the calculated linear trend. The trend calculation gives an
underestimation of about 48% (~0.36°C to low, compared to a total change of
0.75°C). The most significant breakpoint
occurred in 1976, possibly signaling a significant shift on our climate given
its magnitude. A keynote of this is that the trends prior to and post 1976 were
found to vary by a factor of 10 (see the green lines). The trend is
0.024k/decade before 1976 and 0.218k/decade thereafter, which is actually about
4 times the mentioned overall IPCC trend! Thus there is a high degree of
uncertainty if one were to extend this time series onto the future.
A similar inspection of several other global
atmospheric and oceanographic data time series provides reasonable doubt
concerning the validity of the linear model for century long time series. It
should be clear that when applying any statistical method to real world data
the underlying process dynamics have to be considered, in order to avoid
misinterpretation of the statistical results.
In summary the statistical tests reveal a
significant linear trend and significant break points in the mean as well as
the trend of temperature data. Therefore based only on the statistical results
we cannot decide if the analysed data represent a linear or non-linear system
process. Any projection of future global air temperature from past records will
depend strongly on our decision of the underlying process model, as displayed
by the enormous difference between trends calculated with and without
consideration of breakpoints.
Reconstructed prehistoric climate indices provide clear evidence for the
non-linear behaviour of the climate system and for the existence of abrupt
changes (tipping points). Therefore calculation of linear trends can only be
justified for sufficiently short intervals. The final conformation for the real
process dynamics has to come from an accurate and complete geophysical
description of the climate system, a difficult and complex task still to be
accomplished.
To answer the question posed for the paper,
and from the above, the existence of the major late seventies breakpoint could
be considered as a sign for a state change in global air temperature pointing
to a change in the climate system – it’s quite likely the earth did pass a
tipping point.
This paper appears in: Baltic International Symposium (BALTIC), 2012 IEEE/OES, Issue
Reference List
Bai, J. and Perron, P. (1994). “Least
Squares Estimation of a shift in Linear Processes”, Journal of Time Series Analysis, 15, 453-472.
Bai, J. and Perron, P. (1998). :Estimating
and Testing Linear Models with Multiple Structural Changes”, Econometrica, 66,
47-78.
IPCC, “Summary for `Policymakers. In:
Climate Change 2007: The Physical Science Basis. Contribution of Working Group
1 to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change”,
[Solomon, S., D. Qin, M. Manning, Z. Chen, M. Marquis, K.B. Averyt, M. Tignor
and H.L. Miller (eds.)]. Cambridge
University Press, Cambridge, United Kingdom and New Yprk, NY, USA, 2007.
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