Conservative Vector Fields
Contents
Path Independence
If a vector field F is the gradient of a scalar field G (i.e. if F is conservative), that is,
then by the multivariable chain rule, the derivative of the composition of G and r(t) is
which happens to be the integrand for the line integral of F on r(t). It follows, given a path C , that
In other words, the integral of F over C depends solely on the values of G at the points r(b) and r(a), and is thus independent of the path between them. For this reason, a line integral of a conservative vector field is called path independent.
Stokes' Theorem
Stokes' Theorem is effectively a generalization of Green's theorem to 3 dimensions, and the "curl" is a generalization of the quantity to 3 dimensions. An arbitrary oriented surface can be articulated into a family of infinitesimal surfaces, some parallel to the xy-plane, others parallel to the zx-plane, and the remainder parallel to the yz-plane. Let denote an arbitrary vector field.
Let be a surface that is parallel to the yz-plane with counter-clockwise oriented boundary . Green's theorem gives:
is positive if the normal direction to points in the positive x direction and is negative if otherwise. If the normal direction to points in the negative x direction, then is oriented clockwise instead of counter-clockwise in the yz-plane.
Repeating this argument for being parallel to the zx-plane and xy-plane respectively gives:
and
Treating as an ensemble of infinitesimal surfaces parallel to the yz-plane, zx-plane, or xy-plane gives:
This is Stokes' theorem, and is the "curl" of which generalizes the "circulation density" to 3 dimensions.
The direction of at is effectively an "axis of rotation" around which the counterclockwise circulation density in a plane whose normal is parallel to is . Out of all planes that pass through , the plane whose normal is parallel to has the largest counterclockwise circulation density at which is .
An arbitrary vector field that is differentiable everywhere is considered to be "irrotational" or "conservative" if everywhere, or equivalently that for all continuous closed curves
Conservative vector fields
A vector field for which at all points is an "conservative" vector field. can also be referred to as being "irrotational" since the gain around any closed curve is always 0.
A key property of a conservative vector field is that the gain of along a continuous curve is purely a function of the curve's end points. If and are two continuous curves which share the same starting point and end point , then . In other words, the gain is purely a function of and . This property can be derived from Stokes' theorem as follows:
Invert the orientation of to get and combine and to get a continuous closed curve , linking the curves together at the endpoints and . Let denote a surface for which is the counterclockwise oriented boundary.
Stokes' theorem states that . The gain around is the gain along minus the gain along : . Therefore:
Scalar Potential Function
If F is a conservative vector field (also called irrotational, curl-free, or potential), and its components have continuous partial derivatives, the potential of F with respect to a reference point is defined in terms of the line integral:
where C is a parametrized path from to
The fact that the line integral depends on the path C only through its terminal points and is, in essence, the path independence property of a conservative vector field. The fundamental theorem of line integrals implies that if V is defined in this way, then so that V is a scalar potential of the conservative vector field F. Scalar potential is not determined by the vector field alone: indeed, the gradient of a function is unaffected if a constant is added to it. If V is defined in terms of the line integral, the ambiguity of V reflects the freedom in the choice of the reference point
Resources
- Vector Calculus, Wikibooks: Calculus
Conservative Vector Fields
- Conservative Vector Fields Video by James Sousa, Math is Power 4U
- Conservative Vector Fields - The Definition and a Few Remarks Video by Patrick JMT
- Showing a Vector Field on R^2 is Conservative Video by Patrick JMT
Finding a Potential Function of a Conservative Vector Field
- Determining the Potential Function of a Conservative Vector Field Video by James Sousa, Math is Power 4U
- Finding a Potential for a Conservative Vector Field Video by Patrick JMT
- Finding a Potential for a Conservative Vector Field Ex 2 Video by Patrick JMT
- Potential Function of a Conservative Vector Field Video by Krista King
- Potential Function of a Conservative Vector Field in 3D Video by Krista King
The Fundamental Theorem of Line Integrals
- The Fundamental Theorem of Line Integrals Part 1 Video by James Sousa, Math is Power 4U
- The Fundamental Theorem of Line Integrals Part 2 Video by James Sousa, Math is Power 4U
- The Fundamental Theorem of Line Integrals on a Closed Path Video by James Sousa, Math is Power 4U
- Ex 1: Fundamental Theorem of Line Integrals in the Plane Video by James Sousa, Math is Power 4U
- Ex 2: Fundamental Theorem of Line Integrals in the Plane Video by James Sousa, Math is Power 4U
- Ex 3: Fundamental Theorem of Line Integrals in the Plane Video by James Sousa, Math is Power 4U
- Ex 4: Fundamental Theorem of Line Integrals in Space Video by James Sousa, Math is Power 4U
- The Fundamental Theorem for Line Integrals Video by Patrick JMT
- Potential Function of a Conservative Vector Field to Evaluate a Line Integral Video by Krista King
Licensing
Content obtained and/or adapted from:
- Vector calculus, Wikibooks: Calculus under a CC BY-SA license
- Scalar potential, Wikipedia under a CC BY-SA license