R: Operative Environmental Temperature of a Limpet

Tb_limpet {TrenchR}

R Documentation

Operative Environmental Temperature of a Limpet

Description

The function estimates body temperatures (C, operative environmental temperatures) of a limpet based on Denny and Harley (2006).

Usage

Tb_limpet(T_a, T_r, l, h, S, u, psi, c, position = "anterior")

Arguments

`T_a`	`numeric` air temperature (C).
`T_r`	`numeric` rock surface temperature (C) in the sunlight.
`l`	`numeric` limpet length (anterior/posterior axis, m).
`h`	`numeric` limpet height (dorsal/ventral axis, m).
`S`	`numeric` solar irradiance (W m^-2).
`u`	`numeric` wind speed (m s^-1).
`psi`	`numeric` solar zenith angle (degrees). Can be calculated from `zenith_angle` function.
`c`	`numeric` fraction of the sky covered by cloud (proportion).
`position`	`character` direction of the limpet that is facing upwind. Options are `"anterior"`, `"posterior"`, and `"broadside"`.

Details

The original equation uses a finite-difference approach where they divide the rock into series of chunks, and calculate the temperature at each node to derive the conductive heat. For simplification, here it takes the rock temperature as a parameter, and conductive heat is calculated as a product of the area, thermal conductivity of rock and the temperature difference between the rock and the body.

Limpets are simulated as cones following and using solar emissivity values from Campbell and Norman (1998).

The area of the limpet's shell (m²) is projected according to the direction at which sunlight strikes the organism (Pennell and Deignan 1989).

Air conductivity values (W m^-1 K^-1) are calculated following Denny and Harley (2006).

Value

numeric predicted body (operative environmental) temperature (C).

References

Campbell GS, Norman JM (1998). Introduction to environmental biophysics, 2nd ed. edition. Springer, New York. ISBN 0387949372.

Denny MW, Harley CDG (2006). “Hot limpets: predicting body temperature in a conductance-mediated thermal system.” Journal of Experimental Biology, 209(13), 2409-2419. ISSN 0022-0949, doi: 10.1242/jeb.02356.

Pennell S, Deignan J (1989). “Computing the Projected Area of a Cone.” SIAM Review, 31, 299-302. doi: 10.1137/1031052.

Other biophysical models: Grashof_number_Gates(), Grashof_number(), Nusselt_from_Grashof(), Nusselt_from_Reynolds(), Nusselt_number(), Prandtl_number(), Qconduction_animal(), Qconduction_substrate(), Qconvection(), Qemitted_thermal_radiation(), Qevaporation(), Qmetabolism_from_mass_temp(), Qmetabolism_from_mass(), Qnet_Gates(), Qradiation_absorbed(), Qthermal_radiation_absorbed(), Reynolds_number(), T_sky(), Tb_CampbellNorman(), Tb_Gates2(), Tb_Gates(), Tb_butterfly(), Tb_grasshopper(), Tb_limpetBH(), Tb_lizard_Fei(), Tb_lizard(), Tb_mussel(), Tb_salamander_humid(), Tb_snail(), Tbed_mussel(), Tsoil(), actual_vapor_pressure(), boundary_layer_resistance(), external_resistance_to_water_vapor_transfer(), free_or_forced_convection(), heat_transfer_coefficient_approximation(), heat_transfer_coefficient_simple(), heat_transfer_coefficient(), saturation_vapor_pressure(), saturation_water_vapor_pressure()

Examples

  Tb_limpet(T_a      = 25, 
            T_r      = 30, 
            l        = 0.0176, 
            h        = 0.0122, 
            S        = 1300, 
            u        = 1, 
            psi      = 30, 
            c        = 1, 
            position = "anterior")

[Package TrenchR version 1.1.1 Index]