Long-range persistence in global surface temperatures explained by linear multibox energy balance models
Permanent link
https://hdl.handle.net/10037/13160Date
2017-09-15Type
Journal articleTidsskriftartikkel
Peer reviewed
Abstract
The temporal fluctuations in global mean surface temperature are an example of a geophysical quantity that
can be described using the notions of long-range persistence and scale invariance/scaling, but this description
has suffered from lack of a generally accepted physical explanation. Processes with these statistical signatures
can arise from nonlinear effects, for instance, through cascade-like energy transfer in turbulent fluids, but they
can also be produced by linear models with scale-invariant impulse–response functions. This paper demonstrates
that, on time scales from months to centuries, the scale-invariant impulse–response function of global
surface temperature can be explained by simple linear multibox energy balance models. This explanation
describes both the scale invariance of the internal variability and the lack of a characteristic time scale of the
response to external forcings. With parameters estimated from observational data, the climate response is
approximately scaling in these models, even if the response function is not chosen to be scaling a priori. It is
also demonstrated that the differences in scaling exponents for temperatures over land and for sea surface
temperatures can be reproduced by a version of the multibox energy balance model with two distinct
surface boxes.
Description
Source at: http://doi.org/10.1175/JCLI-D-16-0877.1