Rouse number: Difference between revisions
m remove unused bgcolor in wikitable |
|||
| (11 intermediate revisions by 11 users not shown) | |||
| Line 1: | Line 1: | ||
{{Short description|Non-dimensional number in fluid dynamics}} |
|||
The '''Rouse number''' is a [[dimensionless number|non-dimensional number]] in [[fluid dynamics]] which is used to define a concentration profile of [[suspended sediment]] and which also determines how [[sediment]] will be transported in a flowing fluid. It is a ratio between the sediment [[terminal velocity|fall velocity]] <math>w_s</math> and the upwards velocity on the grain as a product of the [[von Kármán constant]] <math>\kappa</math> and the [[shear velocity]] <math>u_*</math>. |
The '''Rouse number''' ('''P''' or '''Z''') is a [[dimensionless number|non-dimensional number]] in [[fluid dynamics]] which is used to define a concentration profile of [[suspended sediment]] and which also determines how [[sediment]] will be transported in a flowing fluid. It is a ratio between the sediment [[terminal velocity|fall velocity]] <math>w_s</math> and the upwards velocity on the grain as a product of the [[von Kármán constant]] <math>\kappa</math> and the [[shear velocity]] <math>u_*</math>. |
||
:<math>P=\frac{w_s}{\kappa u_*}</math> |
:<math>\mathrm{P} = \frac{w_s}{\kappa u_*}</math> |
||
Occasionally the factor β is included before the |
Occasionally the factor β is included before the von Kármán constant in the equation, which is a constant which correlates eddy viscosity to eddy diffusivity. |
||
This is generally taken to be equal to 1, and therefore is ignored in actual calculation. However, it should not be ignored when considering the full equation. |
This is generally taken to be equal to 1, and therefore is ignored in actual calculation. However, it should not be ignored when considering the full equation. |
||
:<math>P=\frac{w_s}{ |
:<math>\mathrm{P} = \frac{\beta w_s}{ \kappa u_*}</math> |
||
It is named after the [[United States|America]]n fluid dynamicist [[Hunter Rouse]]. It is a characteristic scale parameter in the [[Rouse Profile]] of suspended sediment concentration with depth in a flowing fluid. The concentration of suspended sediment with depth goes as the power of the negative Rouse number. It also is used to determine how the particles will move in the fluid. The required Rouse numbers for transport as [[bed load]], [[suspended load]], and [[wash load]], are given below. |
It is named after the [[United States|America]]n fluid dynamicist [[Hunter Rouse]]. It is a characteristic scale parameter in the [[Rouse Profile]] of suspended sediment concentration with depth in a flowing fluid. The concentration of suspended sediment with depth goes as the power of the negative Rouse number. It also is used to determine how the particles will move in the fluid. The required Rouse numbers for transport as [[bed load]], [[suspended load]], and [[wash load]], are given below. |
||
{| class="wikitable" |
{| class="wikitable" |
||
|- bgcolor="#efefef" |
|||
!Mode of Transport |
!Mode of Transport |
||
!Rouse Number |
!Rouse Number |
||
| Line 34: | Line 34: | ||
==References== |
==References== |
||
* Whipple, K. X (2004), 12.163 Course Notes, MIT Open Courseware. |
* Whipple, K. X (2004), 12.163 Course Notes, MIT Open Courseware. [https://ocw.mit.edu/courses/earth-atmospheric-and-planetary-sciences/12-163-surface-processes-and-landscape-evolution-fall-2004/lecture-notes/4_sediment_transport_edited.pdf] |
||
{{NonDimFluMech}} |
{{NonDimFluMech}} |
||
| Line 40: | Line 40: | ||
{{DEFAULTSORT:Rouse Number}} |
{{DEFAULTSORT:Rouse Number}} |
||
[[Category:Dimensionless numbers]] |
[[Category:Dimensionless numbers]] |
||
[[Category:Fluid |
[[Category:Fluid dynamics]] |
||
[[Category:Geology]] |
|||
[[Category:Geomorphology]] |
|||
[[Category:Sedimentology]] |
[[Category:Sedimentology]] |
||
| ⚫ | |||
{{fluiddynamics-stub}} |
{{fluiddynamics-stub}} |
||
| ⚫ | |||
[[fa:عدد روس]] |
|||
[[fr:Nombre de Rouse]] |
|||
[[ru:Число Роуза]] |
|||
Latest revision as of 07:37, 5 August 2024
The Rouse number (P or Z) is a non-dimensional number in fluid dynamics which is used to define a concentration profile of suspended sediment and which also determines how sediment will be transported in a flowing fluid. It is a ratio between the sediment fall velocity and the upwards velocity on the grain as a product of the von Kármán constant and the shear velocity .
Occasionally the factor β is included before the von Kármán constant in the equation, which is a constant which correlates eddy viscosity to eddy diffusivity. This is generally taken to be equal to 1, and therefore is ignored in actual calculation. However, it should not be ignored when considering the full equation.
It is named after the American fluid dynamicist Hunter Rouse. It is a characteristic scale parameter in the Rouse Profile of suspended sediment concentration with depth in a flowing fluid. The concentration of suspended sediment with depth goes as the power of the negative Rouse number. It also is used to determine how the particles will move in the fluid. The required Rouse numbers for transport as bed load, suspended load, and wash load, are given below.
| Mode of Transport | Rouse Number |
|---|---|
| Bed load | >2.5 |
| Suspended load: 50% Suspended | >1.2, <2.5 |
| Suspended load: 100% Suspended | >0.8, <1.2 |
| Wash load | <0.8 |
See also
[edit]References
[edit]- Whipple, K. X (2004), 12.163 Course Notes, MIT Open Courseware. [1]
 | This sedimentology article is a stub. You can help Wikipedia by expanding it. |
 | This fluid dynamics–related article is a stub. You can help Wikipedia by expanding it. |