Norman J. Page
Energy & Environment
(C )The Author(s) 2017
This paper argues that the methods used by the establishment climate science community are not fit for purpose and that a new forecasting paradigm should be adopted. Earth's climate is the result of resonances and beats between various quasi-cyclic processes of varying wavelengths. It is not possible to forecast the future unless we have a good understanding of where the earth is in time in relation to the current phases of those different interacting natural quasi periodicities. Evidence is presented specifying the timing and amplitude of the natural 60+/- year and, more importantly, 1,000 year periodicities (observed emergent behaviors) that are so obvious in the temperature record. Data related to the solar climate driver is discussed and the solar cycle 22 low in the neutron count (high solar activity) in 1991 is identified as a solar activity millennial peak and correlated with the millennial peak -inversion point - in the UAH temperature trend in about 2003. The cyclic trends are projected forward and predict a probable general temperature decline in the coming decades and centuries. Estimates of the timing and amplitude of the coming cooling are made. If the real climate outcomes follow a trend which approaches the near term forecasts of this working hypothesis, the divergence between the IPCC forecasts and those projected by this paper will be so large by 2021 as to make the current, supposedly actionable, level of confidence in the IPCC forecasts untenable.
Fig.3 Reconstruction of the extra-tropical NH mean temperature Christiansen and Ljungqvist 2012. (9) (The red line is the 50 year moving average.)
Any discussion or forecast of future cooling must be based on a wide knowledge of the most important reconstructions of past temperatures, after all, the hockey stick was instrumental in selling the CAGW meme to the grant awarders, politicians, NGOs and the general public.
Fig. 5 Hadcrut 4gl trends showing the millennial cycle temperature peak at about 2005.6
Fig.6 A comparison of the periodograms of (a) the Holocene sunspot activity with (b) time converted periodograms of the Miocene proxy data (19).
Kern 2012 (19) presents strong evidence for the influence of solar cycles during the Holocene and in a Late Miocene lake system. It is noteworthy that the Millennial periodicity is persistent and identifiable throughout the Holocene Figs. 2 and 6 and in the Miocene - 10.5 million years ago Fig.6. The prominent Millennial unnamed peak in Fig. 6a above is also seen in Scaffetta’s Fig. 10 in the C-14 data (20) and is correlated with the Eddy cycle with a suggested period of 900 to 1050 years.
Fig 7 Effect of revising the PAGES Arctic 2k database on the Arctic annual temperature reconstruction published recently by the PAGES 2k Consortium1(22)
The author would like to acknowledge all those in the climate science community who have contributed to the massive accumulation of the basic instrumental and proxy climate data that has taken place in the last thirty years, without which empirical climate science would have no foundation. I also appreciate the very apposite comments and suggestions made by one of the anonymous reviewers and the assistance of my wife Hilary in the adaptation of a number of the figures for the Journal publication.
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