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Lecture 11: Stokes Theorem

Lecture 11: Stokes Theorem. Consider a surface S , embedded in a vector field Assume it is bounded by a rim (not necessarily planar) For each small loop For whole loop (given that all interior boundaries cancel in the normal way).

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Lecture 11: Stokes Theorem

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  1. Lecture 11: Stokes Theorem • Consider a surface S, embedded in a vector field • Assume it is bounded by a rim (not necessarily planar) • For each small loop • For whole loop (given that all interior boundaries cancel in the normal way) OUTER RIM SURFACE INTEGRAL OVER ANY SURFACE WHICH SPANS RIM

  2. Consequences • Curl is incompressible • Consider two surfaces (S1 + S2) with same rim must be the the same for both surfaces (by Stokes Theorem) • For closed surface formed by • Also for a conservative field using the divergence theorem by Stokes Theorem CONSERVATIVE = IRROTATIONAL • These are examples (see Lecture 12) of second-order differential operators in vector calculus

  3. Example • So this is a conservative field, so we should be able to find a potential  • All can be made consistent if

  4. Another Example z (0,0,1) C2 quarter circle C1 C3 y (0,1,0) x • Check via direct integration

  5. Physical Example • Magnetic Field due to a steady current I • “Ampere’s Law” • Since • obeys a continuity equation with no sources or sinks (see Lecture 13) applying Stoke’s Theorem units: A m-2 Differential form of Ampere’s Law

  6. Now make the wire ‘fat’ (of radius a), carrying a total current I • Inside the wire • Outside the wire • Inside, has a similar field to in solid-body rotation, where z axis along the wire, r is radial distance from the z axis |B| a r

  7. Outside wire: z component from loops in the xy plane • z component is zero, because • and x and y components are also zero in the yz and xz planes • Therefore R2 d R1 • Note that region where field is conservative ( ) is not simply connected: loop cannot be shrunk to zero without going inside wire (where field is not conservative).

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