Complex-oriented cohomology theory

In algebraic topology, a complex-orientable cohomology theory is a multiplicative cohomology theory E such that the restriction map ${\displaystyle E^2(ℂ{𝐏}^{\mathrm{\infty }})\to E^2(ℂ{𝐏}^1)}$ is surjective. An element of ${\displaystyle E^2(ℂ{𝐏}^{\mathrm{\infty }})}$ that restricts to the canonical generator of the reduced theory ${\displaystyle {\tilde{E}}^2(ℂ{𝐏}^1)}$ is called a complex orientation. The notion is central to Quillen's work relating cohomology to formal group laws.Template:Citation needed

If E is an even-graded theory meaning ${\displaystyle {\pi }_{3}E={\pi }_{5}E=\cdots }$, then E is complex-orientable. This follows from the Atiyah–Hirzebruch spectral sequence.

Examples:

• An ordinary cohomology with any coefficient ring R is complex orientable, as ${\displaystyle {\mathrm{H}}^2(ℂ{𝐏}^{\mathrm{\infty }};R)\simeq {\mathrm{H}}^2(ℂ{𝐏}^1;R)}$.
• Complex K-theory, denoted KU, is complex-orientable, as it is even-graded. (Bott periodicity theorem)
• Complex cobordism, whose spectrum is denoted by MU, is complex-orientable.

A complex orientation, call it t, gives rise to a formal group law as follows: let m be the multiplication

${\displaystyle ℂ{𝐏}^{\mathrm{\infty }}\times ℂ{𝐏}^{\mathrm{\infty }}\to ℂ{𝐏}^{\mathrm{\infty }},([x],[y])\mapsto [xy]}$

where ${\displaystyle [x]}$ denotes a line passing through x in the underlying vector space ${\displaystyle ℂ[t]}$ of ${\displaystyle ℂ{𝐏}^{\mathrm{\infty }}}$. This is the map classifying the tensor product of the universal line bundle over ${\displaystyle ℂ{𝐏}^{\mathrm{\infty }}}$. Viewing

${\displaystyle E^{\ast }(ℂ{𝐏}^{\mathrm{\infty }})=\underleftarrow{\lim }{E}^{\ast }(ℂ{𝐏}^n)=\underleftarrow{\lim }R[t]/(t^{n+1})=R[[t]],R={\pi }_{\ast }E}$,

let ${\displaystyle f=m^{\ast }(t)}$ be the pullback of t along m. It lives in

${\displaystyle E^{\ast }(ℂ{𝐏}^{\mathrm{\infty }}\times ℂ{𝐏}^{\mathrm{\infty }})=\underleftarrow{\lim }{E}^{\ast }(ℂ{𝐏}^n\times ℂ{𝐏}^m)=\underleftarrow{\lim }R[x,y]/(x^{n+1},y^{m+1})=R[[x,y]]}$

and one can show, using properties of the tensor product of line bundles, it is a formal group law (e.g., satisfies associativity).

• Chromatic homotopy theory

• M. Hopkins, Complex oriented cohomology theory and the language of stacks
• J. Lurie, Chromatic Homotopy Theory (252x)

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