Volatilization

Pesticide in the dissolved phase is available for volatilization. The amount of pesticide removed from the water via volatilization is:

pstvol,wtr=vvdepthFdpstrchwtrTTpst_{vol,wtr}=\frac{v_v}{depth}*F_d*pst_{rchwtr}*TT 7:4.1.8

where pstvol,wtrpst_{vol,wtr} is the amount of pesticide removed via volatilization (mg pst), vvv_v is the volatilization mass-transfer coefficient (m/day), depthdepth is the flow depth (m), FdF_d is the fraction of total pesticide in the dissolved phase, pstrchwtrpst_{rchwtr} is the amount of pesticide in the water (mg pst), and TTTT is the flow travel time (days).

The volatilization mass-transfer coefficient can be calculated based on Whitman’s two-film or two-resistance theory (Whitman, 1923; Lewis and Whitman, 1924 as described in Chapra, 1997). While the main body of the gas and liquid phases are assumed to be well-mixed and homogenous, the two-film theory assumes that a substance moving between the two phases encounters maximum resistance in two laminar boundary layers where transfer is a function of molecular diffusion. In this type of system the transfer coefficient or velocity is:

vv=KlHeHe+RTK(Kl/Kg)v_v=K_l*\frac{H_e}{H_e+R*T_K*(K_l/K_g)} 7:4.1.9

where vvv_v is the volatilization mass-transfer coefficient (m/day), KlK_l is the mass-transfer velocity in the liquid laminar layer (m/day), KgK_g is the mass-transfer velocity in the gaseous laminar layer (m/day), HeH_e is Henry’s constant (atm m3^3 mole1^{-1}), RR is the universal gas constant (8.2061058.206*10^{-5} atm m3^3 (K mole)1^{-1}), and TKT_K is the temperature (K).

For rivers where liquid flow is turbulent, the transfer coefficients are estimated using the surface renewal theory (Higbie, 1935; Danckwerts, 1951; as described by Chapra, 1997). The surface renewal model visualizes the system as consisting of parcels of water that are brought to the surface for a period of time. The fluid elements are assumed to reach and leave the air/water interface randomly, i.e. the exposure of the fluid elements to air is described by a statistical distribution. The transfer velocities for the liquid and gaseous phases are calculated:

Kl=rlDlK_l=\sqrt{r_l*D_l} Kg=rgDgK_g=\sqrt{r_g*D_g} 7:4.1.10

where KlK_l is the mass-transfer velocity in the liquid laminar layer (m/day), KgK_g is the mass-transfer velocity in the gaseous laminar layer (m/day), DlD_l is the liquid molecular diffusion coefficient (m2^2/day), DgD_g is the gas molecular diffusion coefficient (m2^2/day), rlr_l is the liquid surface renewal rate (1/day), and rgr_g is the gaseous surface renewal rate (1/day).

O’Connor and Dobbins (1958) defined the surface renewal rate as the ratio of the average stream velocity to depth.

rl=86400vcdepthr_l=\frac{86400*v_c}{depth} 7:4.1.11

where rlr_l is the liquid surface renewal rate (1/day), vcv_c is the average stream velocity (m/s) and depthdepth is the depth of flow (m).

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