Shear velocity, also called friction velocity, is a form by which a

shear stress Shear stress (often denoted by , Greek alphabet, Greek: tau) is the component of stress (physics), stress coplanar with a material cross section. It arises from the shear force, the component of force vector parallel to the material cross secti ...

may be re-written in units of

velocity Velocity is a measurement of speed in a certain direction of motion. It is a fundamental concept in kinematics, the branch of classical mechanics that describes the motion of physical objects. Velocity is a vector (geometry), vector Physical q ...

. It is useful as a method in

fluid mechanics Fluid mechanics is the branch of physics concerned with the mechanics of fluids (liquids, gases, and plasma (physics), plasmas) and the forces on them. Originally applied to water (hydromechanics), it found applications in a wide range of discipl ...

to compare true velocities, such as the velocity of a flow in a stream, to a velocity that relates shear between layers of flow. Shear velocity is used to describe shear-related motion in moving fluids. It is used to describe: *

Diffusion Diffusion is the net movement of anything (for example, atoms, ions, molecules, energy) generally from a region of higher concentration to a region of lower concentration. Diffusion is driven by a gradient in Gibbs free energy or chemical p ...

and dispersion of particles, tracers, and contaminants in fluid flows * The velocity profile near the boundary of a flow (see Law of the wall) * Transport of sediment in a channel Shear velocity also helps in thinking about the rate of shear and dispersion in a flow. Shear velocity scales well to rates of dispersion and bedload sediment transport. A general rule is that the shear velocity is between 5% and 10% of the mean flow velocity. For river base case, the shear velocity can be calculated by Manning's equation. :

u^*=\langle u\rangle\frac(gR_h^)^

* ''n'' is the Gauckler–Manning coefficient. Units for values of n are often left off, however it is not dimensionless, having units of: (T/ ^1/3 s/ t^1/3 s/ ^1/3. * ''R_h'' is the hydraulic radius (L; ft, m); * the role of a is a dimension correction factor. Thus a= 1 m^1/3/s = 1.49 ft^1/3/s. Instead of finding

n

and

R_h

for the specific river of interest, the range of possible values can be examined; for most rivers,

u^*

is between 5% and 10% of

\langle u\rangle

: For general case :

u_=\sqrt

where ''τ'' is the shear stress in an arbitrary layer of fluid and ''ρ'' is the

density Density (volumetric mass density or specific mass) is the ratio of a substance's mass to its volume. The symbol most often used for density is ''ρ'' (the lower case Greek letter rho), although the Latin letter ''D'' (or ''d'') can also be u ...

of the fluid. Typically, for sediment transport applications, the shear velocity is evaluated at the lower boundary of an open channel: :

u_=\sqrt

where ''τ_b'' is the shear stress given at the boundary. Shear velocity is linked to the Darcy friction factor by equating wall shear stress, giving: :

u_=\sqrt

where is the friction factor. Shear velocity can also be defined in terms of the local velocity and shear stress fields (as opposed to whole-channel values, as given above).

Friction velocity in turbulence

The friction velocity is often used as a scaling parameter for the fluctuating component of velocity in turbulent flows. One method of obtaining the shear velocity is through non-dimensionalization of the turbulent equations of motion. For example, in a fully developed turbulent channel flow or turbulent boundary layer, the streamwise momentum equation in the very near wall region reduces to: :

0=-\frac(\overline)

. By integrating in the ''y''-direction once, then non-dimensionalizing with an unknown velocity scale ''u''_∗ and viscous length scale , the equation reduces down to: :

\frac = \nu\frac - \overline

or :

\frac = \frac + \overline

. Since the right hand side is in non-dimensional variables, they must be of order 1. This results in the left hand side also being of order one, which in turn give us a velocity scale for the turbulent fluctuations (as seen above): :

u_ = \sqrt

. Here, ''τ_w'' refers to the local shear stress at the wall.

Planetary boundary layer

Within the lowest portion of the planetary boundary layer a semi-empirical log wind profile is commonly used to describe the vertical distribution of horizontal mean wind speeds. The simplified equation that describe it is

u(z) = \frac \left ln \left(\frac \right)\right /math>

where \kappa is the Von Kármán constant (~0.41), d is the zero plane displacement (in metres).

The zero-plane displacement (d) is the height in meters above the ground at which zero wind speed is achieved as a result of flow obstacles such as trees or buildings.  It can be approximated as

²/₃ to ³/₄ of the average height of the obstacles.Holmes JD. Wind Loading of Structures. 3rd ed. Boca Raton, Florida: CRC Press; 2015. For example, if estimating winds over a forest canopy of height 30 m, the zero-plane displacement could be estimated as d = 20 m. Thus, you can extract the friction velocity by knowing the wind velocity at two levels (z).

u_* = \frac

Due to the limitation of observation instruments and the theory of mean values, the levels (z) should be chosen where there is enough difference between the measurement readings. If one has more than two readings, the measurements can be fit to the above equation to determine the shear velocity. The friction velocity can also be found from measurements obtained with a sonic anemoter, which allows to get rid of the log wind profile. In this case, the friction velocity is given by

^2 = - \overline

where

u

is the total horizontal wind speed, and

w

is the vertical wind speed. Note that in planetary boundary layer studies the viscosity of air is not considered for the computation friction velocity since

\nu\frac << - \overline

at these scales.

References

* {{DEFAULTSORT:Shear Velocity Fluid mechanics Geophysics Geomorphology Sedimentology