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In algebra, a simplicial commutative ring is a commutative monoid in the category of simplicial abelian groups, or, equivalently, a simplicial object in the category of commutative rings. If A is a simplicial commutative ring, then it can be shown that ${\displaystyle {\pi }_{0}A}$ is a commutative ring and ${\displaystyle {\pi }_{i}A}$ are modules over that ring (in fact, ${\displaystyle {\pi }_{*}A}$ is a graded ring.)

A topology-counterpart of this notion is a commutative ring spectrum.

Graded ring structure

Let A be a simplicial commutative ring. Then the ring structure of A gives ${\displaystyle {\pi }_{*}A={\oplus }_{i\ge 0}{\pi }_{i}A}$ a structure of graded-commutative graded ring as follows.

By the Dold–Kan correspondence, ${\displaystyle {\pi }_{*}A}$ is the homology of the chain complex corresponding to A; in particular, it is a graded abelian group. Next, to multiply two elements, writing ${\displaystyle S^1}$ for the circle, let ${\displaystyle x:(S^1{)}^{\wedge i}\to A,y:(S^1{)}^{\wedge j}\to A}$ be two maps. Then the composition

${\displaystyle (S^1{)}^{\wedge i}\times (S^1{)}^{\wedge j}\to A\times A\to A}$,

the second map the multiplication of A, induces ${\displaystyle (S^1{)}^{\wedge i}\wedge (S^1{)}^{\wedge j}\to A}$. This in turn gives an element in ${\displaystyle {\pi }_{i+j}A}$. We have thus defined the graded multiplication ${\displaystyle {\pi }_{i}A\times {\pi }_{j}A\to {\pi }_{i+j}A}$. It is associative since the smash product is. It is graded-commutative (i.e., ${\displaystyle xy=(-1{)}^{\left|x\right|\left|y\right|}yx}$) since the involution ${\displaystyle S^1\wedge S^1\to S^1\wedge S^1}$ introduces minus sign.

Spec

By definition, the category of affine derived schemes is the opposite category of the category of simplicial commutative rings; an object corresponding to A will be denoted by ${\displaystyle \mathrm{Spec}A}$.

References

• http://mathoverflow.net/questions/118500/what-is-a-simplicial-commutative-ring-from-the-point-of-view-of-homotopy-theory/
• http://mathoverflow.net/questions/45273/what-facts-in-commutative-algebra-fail-miserably-for-simplicial-commutative-ring
• A. Mathew, Simplicial commutative rings, I.
• B. Toën, Simplicial presheaves and derived algebraic geometry

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