R: Operative Environmental Temperature of a Lizard

Tb_lizard {TrenchR}

R Documentation

Operative Environmental Temperature of a Lizard

Description

The function estimates body temperature (C, operative environmental temperature) of a lizard based on Campbell and Norman (1998). The function was designed for Sceloporus lizards and described in Buckley (2008).

Usage

Tb_lizard(
  T_a,
  T_g,
  u,
  svl,
  m,
  psi,
  rho_s,
  elev,
  doy,
  sun = TRUE,
  surface = TRUE,
  a_s = 0.9,
  a_l = 0.965,
  epsilon_s = 0.965,
  F_d = 0.8,
  F_r = 0.5,
  F_a = 0.5,
  F_g = 0.5
)

Arguments

`T_a`	`numeric` air temperature (C).
`T_g`	`numeric` surface temperature (C).
`u`	`numeric` wind speed (m s^-1).
`svl`	`numeric` lizard snout vent length (mm).
`m`	`numeric` lizard mass (g); note that it can be estimated as in `mass_from_length`: 3.55 x 10^-5 x length³
`psi`	`numeric` solar zenith angle (degrees).
`rho_s`	`numeric` surface albedo (proportion). ~ 0.25 for grass, ~ 0.1 for dark soil, > 0.75 for fresh snow (Campbell and Norman 1998).
`elev`	`numeric` elevation (m).
`doy`	`numeric` day of year (1-366).
`sun`	`logical` indicates whether lizard is in sun (`TRUE`) or shade (`FALSE`).
`surface`	`logical` indicates whether lizard is on ground surface (`TRUE`) or above the surface (`FALSE`, e.g. in a tree).
`a_s`	`numeric` lizard solar absorptivity (proportion), `a_s = 0.9` (Gates 1980) (Table 11.4).
`a_l`	`numeric` lizard thermal absorptivity (proportion), `a_l = 0.965` (Bartlett and Gates 1967).
`epsilon_s`	`numeric` surface emissivity of lizards (proportion), `epsilon_s = 0.965` (Bartlett and Gates 1967).
`F_d`	`numeric` the view factor between the surface of the lizard and diffuse solar radiation (proportion). i.e., the portion of the lizard surface that is exposed to diffuse solar radiation (Bartlett and Gates 1967).
`F_r`	`numeric` the view factor between the surface of the lizard and reflected solar radiation (proportion).
`F_a`	`numeric` the view factor between the surface of the lizard and atmospheric radiation (proportion).
`F_g`	`numeric` the view factor between the surface of the lizard and ground thermal radiation (proportion).

Details

The proportion of radiation that is direct is determined following Sears et al. (2011).

Boundary conductance uses a factor of 1.4 to account for increased convection (Mitchell 1976).

Value

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

References

Bartlett PN, Gates DM (1967). “The energy budget of a lizard on a tree trunk.” Ecology, 48, 316-322.

Buckley LB (2008). “Linking traits to energetics and population dynamics to predict lizard ranges in changing environments.” American Naturalist, 171(1), E1 - E19. doi: 10.1086/523949, https://pubmed.ncbi.nlm.nih.gov/18171140/.

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

Gates DM (1980). Biophysical Ecology. Springer-Verlag, New York, NY, USA.

Mitchell JW (1976). “Heat transfer from spheres and other animal forms.” Biophysical Journal, 16(6), 561-569. ISSN 0006-3495, doi: 10.1016/S0006-3495(76)85711-6.

Sears MW, Raskin E, Angilletta Jr. MJ (2011). “The World Is not Flat: Defining Relevant Thermal Landscapes in the Context of Climate Change.” Integrative and Comparative Biology, 51(5), 666-675. ISSN 1540-7063, doi: 10.1093/icb/icr111, https://academic.oup.com/icb/article-pdf/51/5/666/1757893/icr111.pdf.

Examples

  Tb_lizard(T_a       = 25, 
            T_g       = 30, 
            u         = 0.1, 
            svl       = 60, 
            m         = 10, 
            psi       = 34, 
            rho_s     = 0.24, 
            elev      = 500, 
            doy       = 200, 
            sun       = TRUE, 
            surface   = TRUE, 
            a_s   = 0.9, 
            a_l   = 0.965, 
            epsilon_s = 0.965, 
            F_d       = 0.8, 
            F_r       = 0.5, 
            F_a       = 0.5, 
            F_g       = 0.5)

[Package TrenchR version 1.1.1 Index]