scholarly journals The half-order energy balance equation – Part 1: The homogeneous HEBE and long memories

2021 ◽  
Vol 12 (2) ◽  
pp. 469-487 ◽  
Author(s):  
Shaun Lovejoy
Keyword(s):  
Heat Flux ◽  
Energy Balance ◽  
Heat Equation ◽  
Surface Temperature ◽  
Continuum Mechanics ◽  
Balance Equation ◽  
Energy Balance Equation ◽  
The Earth ◽  
Order Energy ◽  
The Continuum

Abstract. The original Budyko–Sellers type of 1D energy balance models (EBMs) consider the Earth system averaged over long times and apply the continuum mechanics heat equation. When these and the more phenomenological box models are extended to include time-varying anomalies, they have a key weakness: neither model explicitly nor realistically treats the conductive–radiative surface boundary condition that is necessary for a correct treatment of energy storage. In this first of a two-part series, I apply standard Laplace and Fourier techniques to the continuum mechanics heat equation, solving it with the correct radiative–conductive boundary conditions and obtaining an equation directly for the surface temperature anomalies in terms of the anomalous forcing. Although classical, this equation is half-ordered and not integer-ordered: the half-order energy balance equation (HEBE). A quite general consequence is that although Newton's law of cooling holds, the heat flux across surfaces is proportional to a half-ordered (not first-ordered) time derivative of the surface temperature. This implies that the surface heat flux has a long memory, that it depends on the entire previous history of the forcing, and that the temperature–heat flux relationship is no longer instantaneous. I then consider the case in which the Earth is periodically forced. The classical case is diurnal heat forcing; I extend this to annual conductive–radiative forcing and show that the surface thermal impedance is a complex valued quantity equal to the (complex) climate sensitivity. Using a simple semi-empirical model of the forcing, I show how the HEBE can account for the phase lag between the summer maximum forcing and maximum surface temperature Earth response. In Part 2, I extend all these results to spatially inhomogeneous forcing and to the full horizontally inhomogeneous problem with spatially varying specific heats, diffusivities, advection velocities, and climate sensitivities. I consider the consequences for macroweather (monthly, seasonal, interannual) forecasting and climate projections.

scholarly journals The Half-order Energy Balance Equation, Part 1: The homogeneous HEBE and long memories

2020 ◽  
Author(s):  
Shaun Lovejoy
Keyword(s):  
Heat Flux ◽  
Energy Balance ◽  
Heat Equation ◽  
Surface Temperature ◽  
Continuum Mechanics ◽  
Balance Equation ◽  
Energy Balance Equation ◽  
Surface Boundary ◽  
The Earth ◽  
The Continuum

Abstract. The original Budyko–Sellers type 1-D energy balance models (EBMs) consider the Earth system averaged over long times and applies the continuum mechanics heat equation. When these and the more phenomenological zero (horizontal) – dimensional box models are extended to include time varying anomalies, they have a key weakness: neither model explicitly nor realistically treats the surface radiative – conductive surface boundary condition that is necessary for a correct treatment of energy storage. In this first of a two part series, we apply standard Laplace and Fourier techniques to the continuum mechanics heat equation, solving it with the correct radiative – conductive BC's obtaining an equation directly for the surface temperature anomalies in terms of the anomalous forcing. Although classical, this equation is half – not integer – ordered: the Half - ordered Energy Balance Equation (HEBE). A quite general consequence is that although Newton's law of cooling holds, that the heat flux across surfaces is proportional to a half (not first) ordered derivative of the surface temperature. This implies that the surface heat flux has a long memory, that it depends on the entire previous history of the forcing, the relationship is no longer instantaneous. We then consider the case where the Earth is periodically forced. The classical case is diurnal heat forcing; we extend this to annual conductive – radiative forcing and show that the surface thermal impedance is a complex valued quantity equal to the (complex) climate sensitivity. Using a simple semi-empirical model, we show how this can account for the phase lag between the summer maximum forcing and maximum surface temperature Earth response. In part II, we extend all these results to spatially inhomogeneous forcing and to the full horizontally inhomogeneous problem with spatially varying specific heats, diffusivities, advection velocities, climate sensitivities. We consider the consequences for macroweather forecasting and climate projections.

Budyko-Sellers 2.0: the classical and fractional heat equations, and the fractional energy balance equation

2021 ◽  
Author(s):  
Shaun Lovejoy
Keyword(s):  
Energy Balance ◽  
Heat Equation ◽  
Surface Temperature ◽  
Continuum Mechanics ◽  
Balance Equation ◽  
Energy Balance Equation ◽  
Forced Response ◽  
Climate Projections ◽  
Surface Boundary ◽  
Seasonal Forecasts

<p>The highly successful Budyko-Sellers energy balance models are based on the classical continuum mechanics heat equation in two spatial dimensions. When extended to the third dimension using the correct conductive-radiative surface boundary conditions, we show that surface temperature anomalies obey the (nonclassical) Half-order energy balance equation (HEBE, with exponent H = ½) implying heat is stored in the subsurface with long memory. </p><p> </p><p>Empirically, we find that both internal variability and the forced response to external variability are compatible with H ≈ 0.4.  Although already close to the HEBE and classical continuum mechanics, we argue that an even more realistic “effective media” macroweather model is a generalization: the fractional heat equation (FHE) for long-time (e.g. monthly scale anomalies).  This model retains standard diffusive and advective heat transport but generalize the (temporal) storage term.  A consequence of the FHE is that the surface temperature obeys the Fractional EBE (FEBE), generalizing the HEBE to 0< H ≤1.  We show how the resulting FEBE can be been used for monthly and seasonal forecasts as well as for multidecadal climate projections.  We argue that it can also be used for understanding and modelling past climates.</p>

A Mathematical Model for Frost Formation on Ground Aircraft

2011 ◽  
Vol 141 ◽  
pp. 147-151
Author(s):  
Li Wen Wang ◽  
Dan Dan Xu ◽  
Zhi Wei Xing
Keyword(s):  
Mathematical Model ◽  
Growth Rate ◽  
Energy Balance ◽  
Relative Humidity ◽  
Surface Temperature ◽  
Balance Equation ◽  
Atmospheric Temperature ◽  
Energy Balance Equation ◽  
Frost Formation ◽  
The Mathematical Model

A mathematical model is developed to describe frost formation on ground aircraft. The mathematical model was based on frost formation physics together with the mass and energy balance equation developed by Mason. It can be used to forecast the frost formation on ground aircraft. Particular attention is paid to the study of the effects of the important factors, such as surface temperature, atmospheric temperature and relative humidity on the frost growth rate over ground aircraft.

SURFTEMP: Simulation of Soil Surface Temperature Using the Energy Balance Equation

1991 ◽  
Vol 20 (1) ◽  
pp. 11-15
Author(s):  
S.D. Wullschleger ◽  
J.E. Cahoon ◽  
J.A. Ferguson ◽  
D.M. Oosterhuis
Keyword(s):  
Energy Balance ◽  
Surface Temperature ◽  
Balance Equation ◽  
Soil Surface ◽  
Energy Balance Equation ◽  
Soil Surface Temperature

scholarly journals Analysis of Spurious Surface Temperature at the Atmosphere–Land Interface and a New Method to Solve the Surface Energy Balance Equation

2009 ◽  
Vol 10 (3) ◽  
pp. 833-844 ◽  
Author(s):  
Hirofumi Tomita
Keyword(s):  
Energy Balance ◽  
Surface Energy ◽  
Surface Temperature ◽  
Balance Equation ◽  
Surface Energy Balance ◽  
Energy Balance Equation ◽  
New Method ◽  
Spurious Mode ◽  
Newton Raphson ◽  
Raphson Method

Abstract Solving the surface energy balance equation is the most important task when combining an atmospheric model and a land surface model. However, while the surface energy balance equation determines the interface temperature between the models, this temperature is often oscillatory and without physical significance. This paper discusses the spurious mode of surface temperature. The energy balance equation is solved by the linearization around the surface temperature in most models. When this conventional scheme is used, oscillation of surface temperature occurs, caused by the exclusion or poor consideration of the surface temperature dependence of the turbulent transfer coefficient at the surface. By more strictly solving the surface energy balance equation, no spurious mode appears. However, it is often difficult to obtain such a solution because the equation is highly nonlinear. Indeed, the Newton–Raphson method at times cannot find the convergence solution. To overcome this difficulty, a new method based on a modified Newton–Raphson method is proposed to solve the surface energy balance equation. As confirmed by conducting a long-term climate simulation, the new method can robustly obtain the true solution with reasonable computational efficiency.

Sign in / Sign up

Export Citation Format

Share Document