A Spatiotemporal Stochastic Model for Tropical Precipitation and Water Vapor Dynamics

Abstract: A linear stochastic model is presented for the dynamics of water vapor and tropical convection. Despite its linear formulation, the model reproduces a wide variety of observational statistics from disparate perspectives, including (i) a cloud cluster area distribution with an approximate power law; (ii) a power spectrum of spatiotemporal red noise, as in the “background spectrum” of tropical convection; and (iii) a suite of statistics that resemble the statistical physics concepts of critical phenomena and pha… Show more

“…The value of is defined as the expected value of σ ( x , y , t ), in the stationary state, and it can be calculated analytically (see supporting information) as where Var( q i j ) is the variance of the water q ( x , y , t ) at lattice site ( x , y ) = ( i , j ). Note that Var( q i j ) was previously presented by Hottovy and Stechmann [], and here, in addition, we establish asymptotically that it depends on model parameters D and b as (see supporting information for derivation assuming Δ x is small). Moreover, depends on and τ in the same way that it depends on F .…”

“…The four parameters b , τ , D , and F are constants. The model in can be related to atmospheric fluid dynamics, as described by Hottovy and Stechmann [] and in the Supporting Information. In brief, the premise of the model is that boundary layer clouds can be understood in idealized form as resulting from the stochastic diffusion of total water.…”

“…For selecting values of the model parameters ( b , τ , D , and F ), a method is used similar to Hottovy and Stechmann [], except now applied to the case of shallow convection. Specifically, the model parameters b and τ are related to the scales of spatial and temporal variability in the model [ Hottovy and Stechmann , ], and their values are chosen to be b = 25 km 2 h −1 and τ = 100 h ≈4 days to give a power spectrum consistent with observational data analyses of the variance of boundary layer water vapor [ Comstock et al , ], which roughly shows a “red” power spectrum, with largest variance on large scales and smaller variance on smaller scales. Furthermore, this value of τ ≈4 days is also the same value estimated by Bretherton et al [] for the dilution timescale due to entrainment.…”

“…A cloud indicator variable σ ( x , y , t ) is defined based on whether or not q ( x , y , t ) is above the saturation threshold q = 0 [ Hottovy and Stechmann , ]: …”

“…To aid the interpretation of the model parameters, note that b , D , and F are analogous to the three parameters of the well‐known Ising model for ferromagnetism [ Yeomans , ]: spatial interaction coefficient, J , temperature, T , and external magnetic field strength, H , respectively [ Hottovy and Stechmann , ]. The parameter τ has no analog in the classic time‐independent Ising model.…”

Cloud regimes as phase transitions

“…The value of is defined as the expected value of σ ( x , y , t ), in the stationary state, and it can be calculated analytically (see supporting information) as where Var( q i j ) is the variance of the water q ( x , y , t ) at lattice site ( x , y ) = ( i , j ). Note that Var( q i j ) was previously presented by Hottovy and Stechmann [], and here, in addition, we establish asymptotically that it depends on model parameters D and b as (see supporting information for derivation assuming Δ x is small). Moreover, depends on and τ in the same way that it depends on F .…”

“…The four parameters b , τ , D , and F are constants. The model in can be related to atmospheric fluid dynamics, as described by Hottovy and Stechmann [] and in the Supporting Information. In brief, the premise of the model is that boundary layer clouds can be understood in idealized form as resulting from the stochastic diffusion of total water.…”

“…For selecting values of the model parameters ( b , τ , D , and F ), a method is used similar to Hottovy and Stechmann [], except now applied to the case of shallow convection. Specifically, the model parameters b and τ are related to the scales of spatial and temporal variability in the model [ Hottovy and Stechmann , ], and their values are chosen to be b = 25 km 2 h −1 and τ = 100 h ≈4 days to give a power spectrum consistent with observational data analyses of the variance of boundary layer water vapor [ Comstock et al , ], which roughly shows a “red” power spectrum, with largest variance on large scales and smaller variance on smaller scales. Furthermore, this value of τ ≈4 days is also the same value estimated by Bretherton et al [] for the dilution timescale due to entrainment.…”

“…A cloud indicator variable σ ( x , y , t ) is defined based on whether or not q ( x , y , t ) is above the saturation threshold q = 0 [ Hottovy and Stechmann , ]: …”

“…To aid the interpretation of the model parameters, note that b , D , and F are analogous to the three parameters of the well‐known Ising model for ferromagnetism [ Yeomans , ]: spatial interaction coefficient, J , temperature, T , and external magnetic field strength, H , respectively [ Hottovy and Stechmann , ]. The parameter τ has no analog in the classic time‐independent Ising model.…”

Cloud regimes as phase transitions

Long temporal autocorrelations in tropical precipitation data and spike train prototypes

Geographical differences in the tropical precipitation‐moisture relationship and rain intensity onset