Abstract
The representation of ocean heat uptake in Simple Climate Models used for policy advice on climate change mitigation strategies is often based on variants of the one-dimensional Vertical Advection/Diffusion equation (VAD) for some averaged form of potential temperature. In such models, the effective advection and turbulent diffusion are usually tuned to emulate the behaviour of a given target climate model. However, because the statistical nature of such a “behavioural” calibration usually obscures the exact dependence of the effective diffusion and advection on the actual physical processes responsible for ocean heat uptake, it is difficult to understand its limitations and how to go about improving VADs. This paper proposes a physical calibration of the VAD that aims to provide explicit traceability of effective diffusion and advection to the processes responsible for ocean heat uptake. This construction relies on the coarse-graining of the full three-dimensional advection diffusion for potential temperature using potential temperature coordinates. The main advantage of this formulation is that the temporal evolution of the reference temperature profile is entirely due to the competition between effective diffusivity that is always positive definite, and the water mass transformation taking place at the surface, as in classical water mass analyses literature. These quantities are evaluated in numerical simulations of present day climate and global warming experiments. In this framework, the heat uptake in the global warming experiment is attributed to the increase of surface heat flux at low latitudes, its decrease at high latitudes and to the redistribution of heat toward cold temperatures made by diffusive flux.
Highlights
Ocean heat uptake is of great importance in climate change predictions: 90 % of the anthropogenic increase in heat stored in the climate system ends up in the oceans (Levitus et al 2012), contributing to sea level rise via thermal expansion
To analyse the processes controlling ocean heat uptake, we study the heat balance in temperature coordinates first in a control run of the HiGEM model that we compare to a warming climate run where the pre-industrial CO2 has been doubled
It is based on the UK MetOffice coupled atmosphere ocean general circulation model (AOGCM) HadGEM1, but has a higher spatial resolution, of 0.83◦ lat. × 1.25◦ lon. (N144) in the atmosphere and 1∕3◦ × 1∕3◦ with 40 levels in the ocean
Summary
Ocean heat uptake is of great importance in climate change predictions: 90 % of the anthropogenic increase in heat stored in the climate system ends up in the oceans (Levitus et al 2012), contributing to sea level rise via thermal expansion. SCMs are used for instance to evaluate the amount of CO2 that can be released in the atmosphere before reaching the 2 ◦C limit (Meinshausen et al 2009) and play an important role in policy making decisions about global warming mitigation strategies To reconcile these two approaches, Huber et al (2015) proposed to calibrate the VAD equation (i.e. the set-up of vertical velocity w and diffusive coefficient K) using a physical approach rather than the behavorial approach used in previous studies such as Raper et al (2001). We have identified the two following points: (1) the possibility to justify the VAD model from horizontally-averaging the three-dimensional advection/ diffusion equation for heat is far from obvious; (2) the occasional up-gradient nature of the horizontally-averaged heat flux complicates the construction of a one-dimensional VAD model because it does not act to reduce the vertical temperature gradient as is expected physically.
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