Schmidt number

Surname

Schmidt number

{\ displaystyle {\ mathit {Sc}}}

dimension

dimensionless

definition

{\ displaystyle {\ mathit {Sc}} = {\ frac {\ nu} {D}}}

${\ displaystyle \ nu}$	kinematic viscosity
${\ displaystyle D}$	Diffusion coefficient

Named after

Ernst Schmidt

scope of application

diffusion

The Schmidt number (after Ernst Schmidt ) is a dimensionless number in physics. It describes the ratio of diffusive momentum transport to diffusive substance transport as the quotient of the kinematic viscosity of a fluid and the diffusion coefficient of a chemical substance contained in it: ${\ displaystyle {\ mathit {Sc}}}$ ${\ displaystyle {\ nu}}$ ${\ displaystyle D}$

{\ displaystyle {\ mathit {Sc}} = {\ frac {\ nu} {D}} = {\ frac {\ eta} {\ rho \ cdot D}}}

With

dynamic viscosity ${\ displaystyle \ eta}$
density ${\ displaystyle \ rho.}$

The Schmidt number is a clear measure of the ratio of the boundary layer thickness between the hydrodynamic boundary layer and the concentration boundary layer.

At high values ( ) the impulse transport is more pronounced than the mass transport. This applies e.g. B. for liquids ( ), but not for gases ( ). ${\ displaystyle {\ mathit {Sc}} \ gg 1}$ ${\ displaystyle {\ mathit {Sc}} \ approx 1000}$ ${\ displaystyle Sc \ approx 1}$

The Schmidt number is the quotient of the Péclet number , which compares advective with diffusive mass transport, and the Reynolds number , which compares advective with diffusive momentum transport: ${\ displaystyle Pe}$ ${\ displaystyle Re}$

{\ displaystyle {\ mathit {Sc}} = {\ frac {\ mathit {Pe}} {\ mathit {Re}}} = {\ frac {L \ cdot v} {D}} \ cdot {\ frac {\ nu} {d \ cdot v}}}

With

the speed ${\ displaystyle v}$
the characteristic length ${\ displaystyle L}$
the characteristic diameter ${\ displaystyle d.}$

In addition, the Schmidt number is the analogue of the Prandtl number used in heat transfer and is linked to this via the Lewis number : ${\ displaystyle {\ mathit {Pr}}}$ ${\ displaystyle {\ mathit {Le}}}$

{\ displaystyle {\ mathit {Sc}} = {\ mathit {Pr}} \ cdot {\ mathit {Le}} = {\ frac {\ nu} {a}} \ cdot {\ frac {a} {D} }}

with the thermal diffusivity . ${\ displaystyle a}$

Individual evidence

^ Josef Kunes: Dimensionless Physical Quantities in Science and Engineering . Elsevier, 2012, ISBN 0-12-391458-2 , pp. 263 ( limited preview in Google Book search).
↑ tec-science: Schmidt number. In: tec-science. May 9, 2020, accessed on June 25, 2020 (German).

[kunes-1] Josef Kunes: Dimensionless Physical Quantities in Science and Engineering . Elsevier, 2012, ISBN 0-12-391458-2 , pp. 263 ( limited preview in Google Book search).

[2] tec-science: Schmidt number. In: tec-science. May 9, 2020, accessed on June 25, 2020 (German).