In physics and mathematics, the Clebsch representation of an arbitrary three-dimensional vector field
φ + ψ
where the scalar fields
are known as Clebsch potentials[3] or Monge potentials,[4] named after Alfred Clebsch (1833–1872) and Gaspard Monge (1746–1818), and
is the gradient operator.
In fluid dynamics and plasma physics, the Clebsch representation provides a means to overcome the difficulties to describe an inviscid flow with non-zero vorticity – in the Eulerian reference frame – using Lagrangian mechanics and Hamiltonian mechanics.
[5][6][7] At the critical point of such functionals the result is the Euler equations, a set of equations describing the fluid flow.
Note that the mentioned difficulties do not arise when describing the flow through a variational principle in the Lagrangian reference frame.
In case of surface gravity waves, the Clebsch representation leads to a rotational-flow form of Luke's variational principle.
[8] For the Clebsch representation to be possible, the vector field
has (locally) to be bounded, continuous and sufficiently smooth.
For global applicability
has to decay fast enough towards infinity.
[9] The Clebsch decomposition is not unique, and (two) additional constraints are necessary to uniquely define the Clebsch potentials.
is in general not solenoidal, the Clebsch representation does not in general satisfy the Helmholtz decomposition.
is equal to[2]
φ + ψ
with the last step due to the vector calculus identity
is perpendicular to both
while further the vorticity does not depend on