dc.description.abstract | We first review the way in which Hasselmann’s paradigm, introduced in 1976 and recently honored with the Nobel Prize, can, like many
key innovations in complexity science, be understood on several different levels. It can be seen as a way to add variability into the pioneering
energy balance models (EBMs) of Budyko and Sellers. On a more abstract level, however, it used the original stochastic mathematical model of
Brownian motion to provide a conceptual superstructure to link slow climate variability to fast weather fluctuations, in a context broader than
EBMs, and led Hasselmann to posit a need for negative feedback in climate modeling. Hasselmann’s paradigm has still much to offer us, but
naturally, since the 1970s, a number of newer developments have built on his pioneering ideas. One important one has been the development
of a rigorous mathematical hierarchy that embeds Hasselmann-type models in the more comprehensive Mori–Zwanzig generalized Langevin
equation (GLE) framework. Another has been the interest in stochastic EBMs with a memory that has slower decay and, thus, longer range
than the exponential form seen in his EBMs. In this paper, we argue that the Mori–Kubo overdamped GLE, as widely used in statistical
mechanics, suggests the form of a relatively simple stochastic EBM with memory for the global temperature anomaly. We also explore how
this EBM relates to Lovejoy et al.’s fractional energy balance equation. | en_US |