Polyvector field

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In differential geometry, a field in mathematics, a multivector field, polyvector field of degree , or -vector field, on a smooth manifold , is a generalization of the notion of a vector field on a manifold.

Definition

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A multivector field of degree   is a global section   of the kth exterior power   of the tangent bundle, i.e.   assigns to each point   it assigns a  -vector in  .

The set of all multivector fields of degree   on   is denoted by   or by  .

Particular cases

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  • If   one has  ;
  • If  , one has  , i.e. one recovers the notion of vector field;
  • If  , one has  , since  .

Algebraic structures

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The set   of multivector fields is an  -vector space for every  , so that   is a graded vector space.

Furthermore, there is a wedge product

 

which for   and   recovers the standard action of smooth functions on vector fields. Such product is associative and graded commutative, making   into a graded commutative algebra.

Similarly, the Lie bracket of vector fields extends to the so-called Schouten-Nijenhuis bracket

 

which is  -bilinear, graded skew-symmetric and satisfies the graded version of the Jacobi identity. Furthermore, it satisfies a graded version of the Leibniz identity, i.e. it is compatible with the wedge product, making the triple   into a Gerstenhaber algebra.

Comparison with differential forms

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Since the tangent bundle is dual to the cotangent bundle, multivector fields of degree   are dual to  -forms, and both are subsumed in the general concept of a tensor field, which is a section of some tensor bundle, often consisting of exterior powers of the tangent and cotangent bundles. A  -tensor field is a differential  -form, a  -tensor field is a vector field, and a  -tensor field is  -vector field.

While differential forms are widely studied as such in differential geometry and differential topology, multivector fields are often encountered as tensor fields of type  , except in the context of the geometric algebra (see also Clifford algebra).[1][2][3]

See also

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References

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  1. ^ Doran, Chris (Chris J. L.) (2007). Geometric algebra for physicists. Lasenby, A. N. (Anthony N.), 1954- (1st pbk. ed. with corr ed.). Cambridge: Cambridge University Press. ISBN 9780521715959. OCLC 213362465.
  2. ^ Artin, Emil, 1898-1962. (1988) [1957]. Geometric algebra. New York: Interscience Publishers. ISBN 9781118164518. OCLC 757486966.{{cite book}}: CS1 maint: multiple names: authors list (link) CS1 maint: numeric names: authors list (link)
  3. ^ Snygg, John. (2012). A new approach to differential geometry using Clifford's geometric algebra. New York: Springer Science+Business Media, LLC. ISBN 9780817682835. OCLC 769755408.