Determinant line bundle: Difference between revisions

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Construction for vector bundles

In differential geometry, the determinant line bundle is a construction, which assigns every vector bundle over paracompact spaces a line bundle. Its name comes from using the determinant on their classifying spaces. Determinant line bundles naturally arise in four-dimensional spin^c structures and are therefore of central importance for Seiberg–Witten theory.

Let $X {\displaystyle X} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/68baa052181f707c662844a465bfeeb135e82bab" aria-hidden="true" alt="{\displaystyle X}" width="852.5" height="936.9">$ be a paracompact space, then there is a bijection $[ X , BO ⁡ ( n ) ] → ≅ Vect R n ⁡ ( X ) , [ f ] ↦ f ∗ γ R n {\displaystyle [X,\operatorname {BO} (n)]\xrightarrow {\cong } \operatorname {Vect} _{\mathbb {R} }^{n}(X),[f]\mapsto f^{*}\gamma _{\mathbb {R} }^{n}} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/0f6413142ce7b27e7a587b83a7e8df24b79b5182" aria-hidden="true" alt="{\displaystyle [X,\operatorname {BO} (n)]\xrightarrow {\cong } \operatorname {Vect} _{\mathbb {R} }^{n}(X),[f]\mapsto f^{*}\gamma _{\mathbb {R} }^{n}}" width="15929" height="1798">$ with the real universal vector bundle $γ R n {\displaystyle \gamma _{\mathbb {R} }^{n}} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/9ce36290f23537f596f945bacab1bd9709a27e26" aria-hidden="true" alt="{\displaystyle \gamma _{\mathbb {R} }^{n}}" width="1129.4" height="1223.9">$ .^[1] The real determinant $det : O ⁡ ( n ) → O ⁡ ( 1 ) {\displaystyle \det \colon \operatorname {O} (n)\rightarrow \operatorname {O} (1)} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/1aff695ff3bdfb5f26c810ab2b1d154935ae5fe4" aria-hidden="true" alt="{\displaystyle \det \colon \operatorname {O} (n)\rightarrow \operatorname {O} (1)}" width="7607.7" height="1223.9">$ is a group homomorphism and hence induces a continuous map $B det : BO ⁡ ( n ) → BO ⁡ ( 1 ) ≅ R P ∞ {\displaystyle {\mathcal {B}}\det \colon \operatorname {BO} (n)\rightarrow \operatorname {BO} (1)\cong \mathbb {R} P^{\infty }} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/0503baeb4407ff02f0d1438955a18954a88d2fde" aria-hidden="true" alt="{\displaystyle {\mathcal {B}}\det \colon \operatorname {BO} (n)\rightarrow \operatorname {BO} (1)\cong \mathbb {R} P^{\infty }}" width="13504.2" height="1223.9">$ on the classifying space for O(n). Hence there is a postcomposition:

det : Vect R n ⁡ ( X ) ≅ [ X , BO ⁡ ( n ) ] → B det ∗ [ X , BO ⁡ ( 1 ) ] ≅ Vect R 1 ⁡ ( X ) . {\displaystyle \det \colon \operatorname {Vect} _{\mathbb {R} }^{n}(X)\cong [X,\operatorname {BO} (n)]\xrightarrow {{\mathcal {B}}\det _{*}} [X,\operatorname {BO} (1)]\cong \operatorname {Vect} _{\mathbb {R} }^{1}(X).} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/cde350f7f360b3fa8f9bcab44933b25313b6639f" aria-hidden="true" alt="{\displaystyle \det \colon \operatorname {Vect} _{\mathbb {R} }^{n}(X)\cong [X,\operatorname {BO} (n)]\xrightarrow {{\mathcal {B}}\det _{*}} [X,\operatorname {BO} (1)]\cong \operatorname {Vect} _{\mathbb {R} }^{1}(X).}" width="25770.6" height="1798">

Let $X {\displaystyle X} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/68baa052181f707c662844a465bfeeb135e82bab" aria-hidden="true" alt="{\displaystyle X}" width="852.5" height="936.9">$ be a paracompact space, then there is a bijection $[ X , BU ⁡ ( n ) ] → ≅ Vect C n ⁡ ( X ) , [ f ] ↦ f ∗ γ C n {\displaystyle [X,\operatorname {BU} (n)]\xrightarrow {\cong } \operatorname {Vect} _{\mathbb {C} }^{n}(X),[f]\mapsto f^{*}\gamma _{\mathbb {C} }^{n}} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/6de069028c1b556bb2c09f6777d48e9a2fb8fedb" aria-hidden="true" alt="{\displaystyle [X,\operatorname {BU} (n)]\xrightarrow {\cong } \operatorname {Vect} _{\mathbb {C} }^{n}(X),[f]\mapsto f^{*}\gamma _{\mathbb {C} }^{n}}" width="15901" height="1798">$ with the complex universal vector bundle $γ C n {\displaystyle \gamma _{\mathbb {C} }^{n}} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/de11956f1015c388c5e001e4feb045b9c56e1512" aria-hidden="true" alt="{\displaystyle \gamma _{\mathbb {C} }^{n}}" width="1129.4" height="1223.9">$ .^[1] The complex determinant $det : U ⁡ ( n ) → U ⁡ ( 1 ) {\displaystyle \det \colon \operatorname {U} (n)\rightarrow \operatorname {U} (1)} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/d35f84f0c8f5f49c4b83321f72518c41a8b25f7a" aria-hidden="true" alt="{\displaystyle \det \colon \operatorname {U} (n)\rightarrow \operatorname {U} (1)}" width="7551.7" height="1223.9">$ is a group homomorphism and hence induces a continuous map $B det : BU ⁡ ( n ) → BU ⁡ ( 1 ) ≅ C P ∞ {\displaystyle {\mathcal {B}}\det \colon \operatorname {BU} (n)\rightarrow \operatorname {BU} (1)\cong \mathbb {C} P^{\infty }} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/f3cf3f67f9706cb5d59328f7272111cffef1daff" aria-hidden="true" alt="{\displaystyle {\mathcal {B}}\det \colon \operatorname {BU} (n)\rightarrow \operatorname {BU} (1)\cong \mathbb {C} P^{\infty }}" width="13448.2" height="1223.9">$ on the classifying space for U(n). Hence there is a postcomposition:

det : Vect C n ⁡ ( X ) ≅ [ X , BU ⁡ ( n ) ] → B det ∗ [ X , BU ⁡ ( 1 ) ] ≅ Vect C 1 ⁡ ( X ) . {\displaystyle \det \colon \operatorname {Vect} _{\mathbb {C} }^{n}(X)\cong [X,\operatorname {BU} (n)]\xrightarrow {{\mathcal {B}}\det _{*}} [X,\operatorname {BU} (1)]\cong \operatorname {Vect} _{\mathbb {C} }^{1}(X).} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/9494fbcb8bd345773f1702bb8fe11a68ddaa6e3e" aria-hidden="true" alt="{\displaystyle \det \colon \operatorname {Vect} _{\mathbb {C} }^{n}(X)\cong [X,\operatorname {BU} (n)]\xrightarrow {{\mathcal {B}}\det _{*}} [X,\operatorname {BU} (1)]\cong \operatorname {Vect} _{\mathbb {C} }^{1}(X).}" width="25714.6" height="1869.7">

Alternatively, the determinant line bundle can be defined as the last non-trivial exterior product. Let $E ↠ X {\displaystyle E\twoheadrightarrow X} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/47d55f89f438dec08139bdeb86a96d608a645169" aria-hidden="true" alt="{\displaystyle E\twoheadrightarrow X}" width="3173.1" height="936.9">$ be a vector bundle, then:^[2]

det ( E ) := Λ rk ⁡ ( E ) ( E ) . {\displaystyle \det(E):=\Lambda ^{\operatorname {rk} (E)}(E).} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/2dddbfc8be96b081468f2f982cd0f08e23fdebab" aria-hidden="true" alt="{\displaystyle \det(E):=\Lambda ^{\operatorname {rk} (E)}(E).}" width="8905.7" height="1439.2">

Proof: Assume

E ↠ Y {\displaystyle E\twoheadrightarrow Y} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/819e5e03919af4f81d0ad4fafb43271780a10ce3" aria-hidden="true" alt="{\displaystyle E\twoheadrightarrow Y}" width="3084.1" height="936.9">

is a real vector bundle and let

g : Y → BO ⁡ ( n ) {\displaystyle g\colon Y\rightarrow \operatorname {BO} (n)} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/2bc8cfa440b462cfe742167e80b917d501c76364" aria-hidden="true" alt="{\displaystyle g\colon Y\rightarrow \operatorname {BO} (n)}" width="6111.7" height="1223.9">

be its classifying map with

E = g ∗ γ R n {\displaystyle E=g^{*}\gamma _{\mathbb {R} }^{n}} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/b1ffd3e6e07fc6bdc834590088f73fe1c97c0234" aria-hidden="true" alt="{\displaystyle E=g^{*}\gamma _{\mathbb {R} }^{n}}" width="4163.3" height="1295.7">

, then:

det ( f ∗ E ) ≅ det ( f ∗ g ∗ γ R n ) ≅ det ( ( g ∘ f ) ∗ γ R n ) ≅ ( B det ∘ g ∘ f ) ∗ γ R 1 ≅ f ∗ ( B det ∘ g ) ∗ γ R 1 ≅ f ∗ det ( g ∗ γ R n ) ≅ f ∗ det ( E ) . {\displaystyle \det(f^{*}E)\cong \det(f^{*}g^{*}\gamma _{\mathbb {R} }^{n})\cong \det((g\circ f)^{*}\gamma _{\mathbb {R} }^{n})\cong ({\mathcal {B}}\det \circ g\circ f)^{*}\gamma _{\mathbb {R} }^{1}\cong f^{*}({\mathcal {B}}\det \circ g)^{*}\gamma _{\mathbb {R} }^{1}\cong f^{*}\det(g^{*}\gamma _{\mathbb {R} }^{n})\cong f^{*}\det(E).} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/7990828351a08751a79b31d5885417054aac41b2" aria-hidden="true" alt="{\displaystyle \det(f^{*}E)\cong \det(f^{*}g^{*}\gamma _{\mathbb {R} }^{n})\cong \det((g\circ f)^{*}\gamma _{\mathbb {R} }^{n})\cong ({\mathcal {B}}\det \circ g\circ f)^{*}\gamma _{\mathbb {R} }^{1}\cong f^{*}({\mathcal {B}}\det \circ g)^{*}\gamma _{\mathbb {R} }^{1}\cong f^{*}\det(g^{*}\gamma _{\mathbb {R} }^{n})\cong f^{*}\det(E).}" width="47531.4" height="1367.4">

For complex vector bundles, the proof is completely analogous.

For vector bundles $E , F ↠ X {\displaystyle E,F\twoheadrightarrow X} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/28835f5836fc0e8b2083a90498557d02e0929b68" aria-hidden="true" alt="{\displaystyle E,F\twoheadrightarrow X}" width="4367.7" height="1080.4">$ (with the same fields as fibers), one has:

$det ( E ⊗ F ) ≅ det ( E ) rk ⁡ ( F ) ⊗ det ( F ) rk ⁡ ( E ) . {\displaystyle \det(E\otimes F)\cong \det(E)^{\operatorname {rk} (F)}\otimes \det(F)^{\operatorname {rk} (E)}.} <img decoding="async" src="https://wikimedia.org/api/rest_v1/media/math/render/svg/bcd032b4bab87aeee0f5b99c87a4bd4f69802a1e" aria-hidden="true" alt="{\displaystyle \det(E\otimes F)\cong \det(E)^{\operatorname {rk} (F)}\otimes \det(F)^{\operatorname {rk} (E)}.}" width="17269.7" height="1439.2">$

Bott, Raoul; Tu, Loring W. (1982). Differential Forms in Algebraic Topology. Springer. doi:10.1007/978-1-4757-3951-0. ISBN 978-1-4757-3951-0.
Freed, Daniel (1987-03-10). “On determinant line bundles” (PDF).
Nicolaescu, Liviu I. (2000), Notes on Seiberg-Witten theory (PDF), Graduate Studies in Mathematics, vol. 28, Providence, RI: American Mathematical Society, doi:10.1090/gsm/028, ISBN 978-0-8218-2145-9, MR 1787219
Hatcher, Allen (2003). “Vector Bundles & K-Theory”.

^ ^a ^b Hatcher 2017, Theorem 1.16.
^ Nicolaescu 2000, Exercise 1.1.4.
^ ^a ^b Hatcher 2017, Proposition 3.10.
^ Hatcher 2017, Proposition 3.11.
^ Bott & Tu 1982, Proposition 11.4.

[:0-1] Hatcher 2017, Theorem 1.16.

[2] Nicolaescu 2000, Exercise 1.1.4.

[:1-3] Hatcher 2017, Proposition 3.10.

[4] Hatcher 2017, Proposition 3.11.

[5] Bott & Tu 1982, Proposition 11.4.

[1]

[2]

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 {{Short description|Construction for vector bundles}}
-In [[differential geometry]], the ”’determinant line bundle”’ is a construction, which assigns every [[vector bundle]] over [[Paracompact space|paracompact spaces]] a [[line bundle]]. Its name comes from using the [[determinant]] on their [[Classifying space|classifying spaces]]. Determinant line bundles naturally arise in four-dimensional [[Spinc structure|spinᶜ structures]] and are therefore of central importance for [[Seiberg–Witten theory]].
+In [[differential geometry]], the ”’determinant line bundle”’ is a construction, which assigns every [[vector bundle]] over [[Paracompact space|paracompact spaces]] a [[line bundle]]. Its name comes from using the [[determinant]] on their [[Classifying space|classifying spaces]]. Determinant line bundles naturally arise in four-dimensional [[Spinc structure| structures]] and are therefore of central importance for [[Seiberg–Witten theory]].
 == Definition ==

Latest revision as of 09:14, 26 November 2025

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