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Lecture 7: Non-conservative Fields and The Del Operator mathematical vector fields, like (y 3, x) from Lecture 3, are non conservative so is magnetic field.

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Presentation on theme: "Lecture 7: Non-conservative Fields and The Del Operator mathematical vector fields, like (y 3, x) from Lecture 3, are non conservative so is magnetic field."— Presentation transcript:

1 Lecture 7: Non-conservative Fields and The Del Operator mathematical vector fields, like (y 3, x) from Lecture 3, are non conservative so is magnetic field “closed-loop” integral is non-zero We will learn later that multi-valued scalar potentials can be used for such fields. Wire carrying current I out of the paper

2 Non Conservative Fields INTEGRATING FACTOR Turns a non-conservative vector field into a conservative vector field. Example is inexact because if it were exact and hence These equations cannot be made consistent for any arbitrary functions C and D.

3 Integrability Condition General differential is integrable if partially differentiate w.r.t. y partially differentiate w.r.t. x equal for all well- behaved functions Or integrability condition In previous example Since these are NOT the same, not integrable

4 Example Integrating Factor often, inexact differentials can be made exact with an integrating factor Example Now are now equal defines a potential, or state, function

5 Conservative Fields In a Conservative Vector Field Which gives an easy way of evaluating line integrals: regardless of path, it is difference of potentials at points 1 and 2. Obvious provided potential is single-valued at the start and end point of the closed loop.

6 Del

7 Grad “Vector operator acts on a scalar field to generate a vector field” Example

8 Div “Vector operator acts on a vector field to generate a scalar field” Example

9 Curl “Vector operator acts on a vector field to generate a vector field” Example

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