Equilibrium Concentrations and Transport Rates

In order to close the system of equations describing the sediment transport, bed change, and bed sorting equations, the fractional equilibrium depth-averaged total-load concentration (C_tk*) must be estimated from an empirical formula. The depth-averaged equilibrium concentration is defined as

${\displaystyle C_{tk*}={\frac {q_{tk*}}{Uh}}}$

(1)

where q_tk* is the total-load transport for the k^th sediment size class estimated from an empirical formula. For convenience, C_tk* is written in general form as

${\displaystyle C_{tk*}=p_{1k}C_{tk}^{*}}$

(2)

where p_idis the fraction of the sediment size (k) in the first (top) bed layer, and C_tk^* is the potential equilibrium total-load concentration. The potential concentration (C_tk^*) can be interpreted as the equilibrium concentration for uniform sediment of size d_k. The above equation is essential for the coupling of sediment transport, bed change, and bed sorting equations.

Lund-CIRP

Camenen and Larson (2005, 2007, and 2008) developed a general sediment transport formula for bed and suspended load under combined waves and currents. These are refered to as the Lund-CIRP transport formulas. The general transport formulas can be used for both symmetric and asymmetric waves but for simplicity the waves are assumed to be symmetric. The current-related bed- and suspended transport rate wave stirring s given by

${\displaystyle {\frac {q_{b}}{\sqrt {(s-1)gd_{50}^{3}}}}=f_{b}\rho _{s}{\sqrt {\theta _{c}}}\theta _{cw,m}\exp {{\biggl (}-4.5{\frac {\theta _{cr}}{\theta _{cw}}}}{\biggr )}}$

(3)

${\displaystyle {\frac {q_{s*}}{\sqrt {(s-1)gd_{50}^{3}}}}=f_{s}\rho _{s}c_{R}U{\frac {\epsilon }{\omega _{s}}}\left[1-exp\left(-{\frac {\omega _{s}h}{\epsilon }}\right)\right]}$

(4)

where:

q_b* = equilibrium bed-load transport rate [kg/m/s]

q_s* = equilibrium suspended-load transport rate [kg/m/s]

${\displaystyle \Theta _{c}}$ = Shields parameters due to currents [-]

${\displaystyle \Theta _{cw,m}}$ = mean Shields parameters due to waves and currents [-]

${\displaystyle \Theta _{cw}}$= maximum Shields parameters due to waves and currents [-]

${\displaystyle \Theta _{cr}}$ = critical Shields parameter [-]

${\displaystyle \epsilon }$ = vertical sediment diffusivity [m²/s]

c_R = reference bed concentration [kg/m³]

f_b= bed-load scaling factor (default 1.0) [-]

f_s = suspended-load scaling factor (default 1.0) [-].

The critical Shields parameter is calculated using Equation (2-100). The mean and maximum Shields parameters are calculated as

${\displaystyle \Theta _{cw,m}={\sqrt {\Theta _{c}^{2}+\Theta _{w,m}^{2}+2\Theta _{c}\Theta _{w,m}cos\varphi }}}$

(5)

${\displaystyle \Theta _{cw}={\sqrt {\Theta _{c}^{2}+\Theta _{w}^{2}+2\Theta _{c}\Theta _{w}cos\varphi }}}$

(6)

The mean wave Shields parameter is calculated as ${\displaystyle \Theta _{w,m}=\Theta _{w}/2}$assuming a sinusoidal wave. The Shields parameters for currents and waves are given by

${\displaystyle \Theta _{c|w}={\frac {\tau _{cw}}{g(\rho _{s}-\rho )d}}}$

(7)

in which the subscript c|w indicates either the current- (c) or wave-related (w) component. The current-related shear stress (${\displaystyle \tau _{c}}$) is calculated with Equation (2-11). The wave-related bed shear stress is calculated with Equation (2-12) and the wave friction factor (f_w) of Swart (1974) given by Equation (2-15).

The total bed roughness is assumed to be a linear summation of the grain-related roughness (k_sg), form-drag (ripple) roughness (k_sr), and sediment-related roughness (k_ss):

${\displaystyle k_{s,c|w}=k_{sg}+k_{sr,c|w}+k_{ss,c|w}}$

(8)

Here, the grain-related roughness is estimated as k_sg = 2d₅₀ The ripple roughness (k_sr) is calculated as (Soulsby 1997)

${\displaystyle k_{sr,c|w}=7.5{\frac {H_{r,c|w}^{2}}{L_{r,c|w}}}}$

(9)

where H_r and L_r are the ripple height and length, respectively.

The current- and wave-related sediment roughnesses are estimated as

${\displaystyle k_{ss,c|w}=5d_{50}\Theta _{c|w}}$

(10)

The above equation must be solved simultaneously with the expressions for the bottom shear stress because the roughness depends on the stress.

The reference concentration is given by

${\displaystyle c_{R}=A_{cR}\exp {{\biggl (}-4.5{\frac {\theta _{cr}}{\theta _{cw}}}}{\biggr )}}$

(11)

where the coefficient ${\displaystyle A_{cR}}$ is determined by the following relationship:

${\displaystyle A_{cR}=0.0035\exp {{\bigl (}-0.3d_{*}}{\bigr )}}$

(12)

The vertical sediment diffusivity is calculated as

${\displaystyle \epsilon =h\left({\frac {D_{e}}{\rho }}\right)^{1/3}}$

(13)

where D_e is the total effective dissipation given by

${\displaystyle D_{e}=k_{b}^{3}D_{br}+k_{c}^{3}D_{c}+k_{w}^{3}D_{w}}$

(14)

in which k_b, k_c, and k_w are coefficients; D_br is the wave breaking dissipation (from the wave model); and D_c and D_w are the bottom friction dissipation due to currents and waves, respectively. The dissipation from bottom friction due to current (D_c) and the dissipation from bottom friction due to waves (D_w) are expressed as

${\displaystyle D_{c|w}=\tau _{c|w}u_{*c|w}}$

(15)

The coefficient k_b=0.017 (Camenen and Larson 2008), and k_c and k_w are a function of the Schmidt number:

${\displaystyle k_{c|w}={\frac {\kappa }{6}}\sigma _{*c|w}}$

(16)

where ${\displaystyle \sigma _{c|w}}$is either the current- or wave-related Schmidt number calculated from the following relationships (Camenen and Larson 2008):

${\displaystyle \sigma _{c|w}=\left\{{\begin{aligned}&a_{c|w}+b_{c|w}sin^{2}\left({\frac {\pi }{2}}{\frac {\omega _{s}}{u_{*c|w}}}\right)for{\frac {\omega _{s}}{u_{*c|w}}}\leq 1\\&1+(a_{c|w}+b_{c|w}-1)sin^{2}\left({\frac {\pi }{2}}{\frac {u_{*c|w}}{\omega _{s}}}\right)for{\frac {\omega _{s}}{u_{*c|w}}}>1\end{aligned}}\right.}$

(17)

with the coefficients a_c = 0.4, b_c = 3.5, a_w =0.15, and b_w = 1.5.

For multiple-sized (non-uniform) sediments, the fractional equilibrium sediment transport rates are calculated as (Wu and Lin 2011)

${\displaystyle {\frac {q_{bk*}}{\sqrt {(s-1)gd_{k}^{3}}}}=f_{b}\zeta _{k}^{-1}p_{1k}\rho _{s}12{\sqrt {\Theta _{c}}}\Theta _{cw,m}\ exp\left(-4.5{\frac {\Theta _{crk}}{\Theta _{cw}}}\right)}$

(18)

${\displaystyle {\frac {q_{sk*}}{\sqrt {(s-1)gd_{k}^{3}}}}=f_{s}\zeta _{k}^{-1}p_{1k}\rho _{s}c_{Rk}U{\frac {\epsilon _{k}}{\omega _{sk}}}\left[1-exp\left(-{\frac {\omega _{sk}h}{\epsilon _{k}}}\right)\right]}$

(19)

where:

k = subscript indicating the sediment size class

${\displaystyle \zeta _{k}}$ = hiding and exposure function [-]

r_sk = fraction of suspended load for each size class defined by Equation (2-51) [-]

p_1k = fraction of the k^th sediment size in the first layer [-].

The availability of sediment fractions is included through p_1k, while hiding and exposure of grain sizes are accounted for by directly multiplying the transport rates.

van Rijn

The van Rijn (1984ab) transport equations are used with the recalibrated coefficients of van Rijn (2007ab) are given by

${\displaystyle q_{b*}=f_{b}\rho _{s}0.015Uh{\biggl (}{\frac {U_{e}-U_{cr}}{\sqrt {(s-1)gd_{50}}}}{\biggr )}^{1.5}{\biggl (}{\frac {d_{50}}{h}}{\biggr )}^{1.2}}$

(20)

${\displaystyle q_{s*}=f_{s}\rho _{s}0.012Ud_{50}{\biggl (}{\frac {U_{e}-U_{cr}}{\sqrt {(s-1)gd_{50}}}}{\biggr )}^{2.4}d_{*}^{-0.6}}$

(21)

where:

${\displaystyle U_{cr}}$ = the critical depth-averaged velocity for incipient motion [m/s],

${\displaystyle U_{e}}$ = effective depth averaged velocity [m/s]

The effective depth-averaged velocity is calculated as ${\displaystyle U_{e}=U+\gamma u_{w}}$ with ${\displaystyle \gamma }$= 0.4 for random waves and ${\displaystyle \gamma }$ = 0.8 for regular waves. The bottom wave orbital velocity based on linear wave theory is u_w. For random waves, u_w = u_ws where u_ws is based on the significant wave height and peak wave period (see Equation 2-24). The critical depth-averaged velocity is

estimated as ${\displaystyle U_{cr}=\beta _{c}U_{crc}+(1-\beta _{c})u_{crw}{\text{ where }}\beta _{c}=U/(U+u_{w})}$ is a blending factor. The critical depth-averaged current velocity (U_crc) is given by Equation (2-102), and the critical bottom-wave-orbital velocity amplitude (u_crw) is given by Equation (2-103).

According to van Rijn (2007a), the bed-load transport formula predicts transport rates by a factor of 2 for velocities higher than 0.6 m/s, but under predicts transport rates by a factor of 2 to 3 for velocities close to the initiation of motion.

The van Rijn formulas (1984a,b; 2007a,b) were originally proposed for well-sorted sediments. The sediment availability is included by multiplication of transport rates with the fraction of the sediment size class in the upper bed layer. The hiding and exposure are considered by a correction factor which multiples to the critical velocity. When applied to multiple-sized sediments, the fractional equilibrium transport rates are calculated as

${\displaystyle q_{bk*}=f_{b}\rho _{s}p_{1k}0.015Uh\left({\frac {U_{e}-\zeta _{k}^{1/2}U_{crk}}{\sqrt {(s-1)gd_{k}}}}\right)^{1.5}\left({\frac {d_{k}}{h}}\right)^{1.2}}$

(22)

${\displaystyle q_{sk*}=f_{s}\rho _{s}p_{1k}0.012Uh\left({\frac {U_{e}-\zeta _{k}^{1/2}U_{crk}}{\sqrt {(s-1)gd_{k}}}}\right)^{2.4}\left({\frac {d_{k}}{h}}\right)d_{*k}^{-0.6}}$

(23)

The availability of sediment fractions is included through p_1k, while hiding and exposure of grain sizes are accounted for by multiplying the critical velocity (U_crk) by a correction function (${\displaystyle \zeta _{k}^{1/2}}$).

Watanabe

The equilibrium total load sediment transport rate of Watanabe (1987) is given by

${\displaystyle q_{t}=A_{w}{\biggl [}{\frac {(\tau _{b,max}-\tau _{cr})U}{\rho g}}{\biggr ]}}$

(13)

where ${\displaystyle \tau _{b,max}}$ is the maximum shear stress, ${\displaystyle \tau _{cr}}$ is the critical shear stress of incipient motion, and ${\displaystyle A}$ is an empirical coefficient typically ranging from 0.1 to 2.

The critical shear stress is determined using

${\displaystyle \tau _{cr}=(\rho _{s}-\rho )gd\phi _{cr}}$

(14)

In the case of currents only the bed shear stress is determined as ${\displaystyle \tau _{c}={\frac {1}{8}}\rho gf_{c}U_{c}^{2}}$ where ${\displaystyle f_{c}}$ is the current friction factor. The friction factor is calculated as ${\displaystyle f_{c}=0.24log^{-2}(12h/k_{sd})}$ where ${\displaystyle k_{sd}}$ is the Nikuradse equivalent sand roughness obtained from ${\displaystyle k_{sd}=2.5d_{50}}$.

If waves are present, the maximum bed shear stress ${\displaystyle \tau _{b,max}}$ is calculated based on Soulsby (1997)

${\displaystyle \tau _{max}={\sqrt {(\tau _{m}+\tau _{w}\cos {\phi })^{2}+(\tau _{w}\sin {\phi })^{2}}}}$

(15)

where ${\displaystyle \tau _{m}}$ is the mean shear stress by waves and current over a wave cycle, math> \tau_w </math> is the mean wave bed shear stress, and ${\displaystyle \phi }$ is the angle between the waves and the current. The mean wave and current bed shear stress is

${\displaystyle \tau _{m}=\tau _{c}{\biggl [}1+1.2{\biggl (}{\frac {\tau _{w}}{\tau _{c}+\tau _{c}}}{\biggr )}^{3.2}{\biggr ]}}$

(16)

The wave bed shear stress is given by ${\displaystyle \tau _{w}={\frac {1}{2}}\rho gf_{w}U_{w}^{2}}$ where ${\displaystyle f_{w}}$ is the wave friction factor, and ${\displaystyle U_{w}}$ is the wave orbital velocity amplitude based on the significant wave height.

The wave friction factor is calculated as (Nielsen 1992) ${\displaystyle f_{w}=\exp {5.5R^{-0.2}-6.3}}$ where ${\displaystyle R}$ is the relative roughness defined as ${\displaystyle R=A_{w}/k_{sd}}$ and ${\displaystyle A_{w}}$ is semi-orbital excursion ${\displaystyle A_{w}=U_{w}T/(2\pi )}$.

Soulsby-van Rijn

Soulsby (1997) proposed the following equation for the total load sediment transport rate under currents and waves

${\displaystyle q_{t}=A_{s}U{\biggl [}{\biggl (}U^{2}+0.018{\frac {U_{rms}^{2}}{C_{d}}}{\biggr )}^{0.5}-U_{cr}{\biggr ]}^{2.4}}$

(20)

where ${\displaystyle U_{rms}}$ is the root-mean-squared wave orbital velocity, and ${\displaystyle C_{d}}$ is the drag coefficient due to currents alone and the coefficient ${\displaystyle A_{s}=A_{sb}+A_{ss}}$. The coefficients ${\displaystyle A_{sb}}$ and ${\displaystyle A_{ss}}$ are related to the bed and suspended transport loads respectively and are given by

${\displaystyle A_{sb}={\frac {0.005h(d_{50}/h)^{1.2}}{[(s-1)gd_{50}]^{1.2}}}}$

(21)

${\displaystyle A_{s}={\frac {0.012d_{50}D_{*}^{-0.6}}{[(s-1)gd_{50}]^{1.2}}}}$

(22)

The current drag coefficient is calcualted as

${\displaystyle C_{d}={\biggl [}{\frac {0.4}{\ln {(h/z_{0})}-1}}{\biggr ]}^{2}}$

(23)

with a constant bed roughness length ${\displaystyle z_{0}}$ set to 0.006 m.

Symbol	Description	Units
${\displaystyle q_{bc}}$	Bed load transport rate	m3/s
${\displaystyle s}$	Relative density	-
${\displaystyle \theta _{c}}$	Shields parameter due to currents	-
${\displaystyle \theta _{cw}}$	Shields parameter due to waves and currents	-
${\displaystyle \theta _{cw}}$	Critical shields parameter	-
${\displaystyle a_{c}}$	Empirical coefficient	-
${\displaystyle b_{c}}$	Empirical coefficient	-
${\displaystyle U_{c}}$	Current magnitude	m/s

References

• Camenen, B., and Larson, M. (2005). "A bed load sediment transport formula for the nearshore," Estuarine, Coastal and Shelf Science, 63, 249-260.
• Camenen, B., and Larson, M. (2007). "A unified sediment transport formulation for coastal inlet applications", ERDC/CHL-TR-06-7, US Army Engineer Research and Development Center, Coastal and Hydraulics Laboratory, Vicksburg, MS.
• Camenen, B., and Larson, M., (2008). "A General Formula for Non-Cohesive Suspended Sediment Transport," Journal of Coastal Research, 24(3), 615-627.
• Soulsby, D.H. (1997). "Dynamics of marine sands. A manual for practical applications," Thomas Telford Publications, London, England, 249 p.
• van Rijn, L. C. (1984a). "Sediment transport. Part I: Bed load transport", Journal of Hydraulic Engineering, 110(10), 1431–1456.
• van Rijn, L. C. (1984b). "Sediment transport. Part II: Suspended loadtransport", Journal of Hydraulic Engineering, 110(11), 1613–1641.
• van Rijn, L.C., (2007a). "Unified View of Sediment Transport by Currents and Waves. I: Initiation of Motion, Bed Roughness, and Bed-load Transport", Journal of Hydraulic Engineering, 133(6), 649-667.
• van Rijn, L.C., (2007b). "Unified View of Sediment Transport by Currents and Waves. II: Suspended Transport", Journal of Hydraulic Engineering, 133(6), 668-689.
• Watanabe, A. (1987). "3-dimensional numerical model of beach evolution," Proceedings Coastal Sediments '87, ASCE, 802-817.

Documentation Portal