algebra Algebra is a branch of mathematics that deals with abstract systems, known as algebraic structures, and the manipulation of expressions within those systems. It is a generalization of arithmetic that introduces variables and algebraic ope ...

, a λ-ring or lambda ring is a

commutative ring In mathematics, a commutative ring is a Ring (mathematics), ring in which the multiplication operation is commutative. The study of commutative rings is called commutative algebra. Complementarily, noncommutative algebra is the study of ring prope ...

together with some operations λ^''n'' on it that behave like the

exterior power In mathematics, the exterior algebra or Grassmann algebra of a vector space V is an associative algebra that contains V, which has a product, called exterior product or wedge product and denoted with \wedge, such that v\wedge v=0 for every vector ...

s of

vector space In mathematics and physics, a vector space (also called a linear space) is a set (mathematics), set whose elements, often called vector (mathematics and physics), ''vectors'', can be added together and multiplied ("scaled") by numbers called sc ...

s. Many rings considered in K-theory carry a natural λ-ring structure. λ-rings also provide a powerful formalism for studying an action of the

symmetric function In mathematics, a function of n variables is symmetric if its value is the same no matter the order of its arguments. For example, a function f\left(x_1,x_2\right) of two arguments is a symmetric function if and only if f\left(x_1,x_2\right) = f\ ...

s on the ring of polynomials, recovering and extending many classical results (). λ-rings were introduced by . For more about λ-rings see , , and .

Motivation

If ''V'' and ''W'' are finite- dimensional vector spaces over a field ''k'', then we can form the

direct sum The direct sum is an operation between structures in abstract algebra, a branch of mathematics. It is defined differently but analogously for different kinds of structures. As an example, the direct sum of two abelian groups A and B is anothe ...

''V'' ⊕ ''W'', the

tensor product In mathematics, the tensor product V \otimes W of two vector spaces V and W (over the same field) is a vector space to which is associated a bilinear map V\times W \rightarrow V\otimes W that maps a pair (v,w),\ v\in V, w\in W to an element of ...

''V'' ⊗ ''W'', and the ''n''-th

of ''V'', Λ^''n''(''V''). All of these are again finite-dimensional vector spaces over ''k''. The same three operations of direct sum, tensor product and exterior power are also available when working with ''k''-linear representations of a

finite group In abstract algebra, a finite group is a group whose underlying set is finite. Finite groups often arise when considering symmetry of mathematical or physical objects, when those objects admit just a finite number of structure-preserving tra ...

, when working with

vector bundle In mathematics, a vector bundle is a topological construction that makes precise the idea of a family of vector spaces parameterized by another space X (for example X could be a topological space, a manifold, or an algebraic variety): to eve ...

s over some

topological space In mathematics, a topological space is, roughly speaking, a Geometry, geometrical space in which Closeness (mathematics), closeness is defined but cannot necessarily be measured by a numeric Distance (mathematics), distance. More specifically, a to ...

, and in more general situations. λ-rings are designed to abstract the common algebraic properties of these three operations, where we also allow for formal inverses with respect to the direct sum operation. (These formal inverses also appear in

Grothendieck group In mathematics, the Grothendieck group, or group of differences, of a commutative monoid is a certain abelian group. This abelian group is constructed from in the most universal way, in the sense that any abelian group containing a group homomorp ...

s, which is why the underlying additive groups of most λ-rings are Grothendieck groups.) The addition in the ring corresponds to the direct sum, the multiplication in the ring corresponds to the tensor product, and the λ-operations to the exterior powers. For example, the

isomorphism In mathematics, an isomorphism is a structure-preserving mapping or morphism between two structures of the same type that can be reversed by an inverse mapping. Two mathematical structures are isomorphic if an isomorphism exists between the ...

\Lambda^2(V\oplus W)\cong \Lambda^2(V)\oplus\left(\Lambda^1(V)\otimes\Lambda^1(W)\right)\oplus\Lambda^2(W)

corresponds to the formula :

\lambda^2(x+y)=\lambda^2(x)+\lambda^1(x)\lambda^1(y)+\lambda^2(y)

valid in all λ-rings, and the isomorphism :

\Lambda^1(V\otimes W)\cong \Lambda^1(V)\otimes\Lambda^1(W)

corresponds to the formula :

\lambda^1(xy)=\lambda^1(x)\lambda^1(y)

valid in all λ-rings. Analogous but (much) more complicated formulas govern the higher order λ-operators.

Motivation with Vector Bundles

If we have a

short exact sequence In mathematics, an exact sequence is a sequence of morphisms between objects (for example, Group (mathematics), groups, Ring (mathematics), rings, Module (mathematics), modules, and, more generally, objects of an abelian category) such that the Im ...

of vector bundles over a smooth scheme

X

$0 \to \mathcal'' \to \mathcal \to \mathcal' \to 0,$

then locally, for a small enough open neighborhood

U

we have the isomorphism :

\bigwedge^n \mathcal, _U \cong \bigoplus_ \bigwedge^i \mathcal', _U \otimes\bigwedge^j\mathcal'', _U

Now, in the

K(X)

X

(which is actually a ring), we get this local equation globally for free, from the defining

equivalence relation In mathematics, an equivalence relation is a binary relation that is reflexive, symmetric, and transitive. The equipollence relation between line segments in geometry is a common example of an equivalence relation. A simpler example is equ ...

s. So :

\end

demonstrating the basic relation in a λ-ring, that :

\lambda^n(x+y) = \sum_\lambda^i(x)\lambda^j(y).

Definition

A λ-ring is a commutative ring ''R'' together with operations λ^''n'' : ''R'' → ''R'' for every non-negative

integer An integer is the number zero (0), a positive natural number (1, 2, 3, ...), or the negation of a positive natural number (−1, −2, −3, ...). The negations or additive inverses of the positive natural numbers are referred to as negative in ...

''n''. These operations are required to have the following properties valid for all ''x'', ''y'' in ''R'' and all ''n, m'' ≥ 0: *λ⁰(''x'') = 1 *λ¹(''x'') = x *λ^''n''(1) = 0 if ''n'' ≥ 2 *λ^''n''(''x'' + ''y'') = Σ_{''i''+''j''=''n''} λ^''i''(''x'') λ^''j''(''y'') *λ^''n''(''xy'') = ''P''_''n''(λ¹(''x''), ..., λ^''n''(''x''), λ¹(''y''), ..., λ^''n''(''y'')) *λ^''n''(λ^''m''(''x'')) = ''P''_''n'',''m''(λ¹(''x''), ..., λ^''mn''(''x'')) where ''P''_''n'' and ''P_n,m'' are certain universal polynomials with integer coefficients that describe the behavior of exterior powers on tensor products and under composition. These polynomials can be defined as follows. Let ''e''₁, ..., ''e''_''mn'' be the

elementary symmetric polynomial In mathematics, specifically in commutative algebra, the elementary symmetric polynomials are one type of basic building block for symmetric polynomials, in the sense that any symmetric polynomial can be expressed as a polynomial in elementary sy ...

s in the variables ''X''₁, ..., ''X''_''mn''. Then ''P''_''n'',''m'' is the unique polynomial in ''nm'' variables with integer coefficients such that ''P_n,m''(''e''₁, ..., ''e''_''mn'') is the coefficient of ''t''^''n'' in the expression :

\prod_ (1+tX_X_\cdots X_)

(Such a polynomial exists, because the expression is symmetric in the ''X_i'' and the elementary symmetric polynomials generate all symmetric polynomials.) Now let ''e''₁, ..., ''e''_''n'' be the elementary symmetric polynomials in the variables ''X''₁, ..., ''X''_''n'' and ''f''₁, ..., ''f''_''n'' be the elementary symmetric polynomials in the variables ''Y''₁, ..., ''Y''_''n''. Then ''P''_''n'' is the unique polynomial in 2''n'' variables with integer coefficients such that is the coefficient of ''t''^''n'' in the expression :

\prod_^n (1+tX_iY_j)

Variations

The λ-rings defined above are called "special λ-rings" by some authors, who use the term "λ-ring" for a more general concept where the conditions on λ^''n''(1), λ^''n''(''xy'') and λ^''m''(λ^''n''(''x'')) are dropped.

Examples

*The ring Z of

s, with the

binomial coefficient In mathematics, the binomial coefficients are the positive integers that occur as coefficients in the binomial theorem. Commonly, a binomial coefficient is indexed by a pair of integers and is written \tbinom. It is the coefficient of the t ...

\lambda^n(x)=

as operations (which are also defined for negative ''x'') is a λ-ring. In fact, this is the only λ-structure on Z. This example is closely related to the case of finite-dimensional vector spaces mentioned in the Motivation section above, identifying each vector space with its dimension and remembering that

\dim(\Lambda^n(k^x ))=

. *More generally, any binomial ring becomes a λ-ring if we define the λ-operations to be the binomial coefficients, λ^''n''(''x'') = (). In these λ-rings, all Adams operations are the identity. *The K-theory K(''X'') of a

''X'' is a λ-ring, with the lambda operations induced by taking exterior powers of a vector bundle. *Given a group ''G'' and a base field ''k'', the representation ring ''R''(''G'') is a λ-ring; the λ-operations are induced by the exterior powers of ''k''-linear representations of the group ''G''. *The ring Λ_Z of symmetric functions is a λ-ring. On the integer coefficients the λ-operations are defined by binomial coefficients as above, and if ''e''₁, ''e''₂, ... denote the elementary symmetric functions, we set λ^''n''(''e''₁) = ''e''_''n''. Using the axioms for the λ-operations, and the fact that the functions ''e''_''k'' are algebraically independent and generate the ring Λ_Z, this definition can be extended in a unique fashion so as to turn Λ_Z into a λ-ring. In fact, this is the free λ-ring on one generator, the generator being ''e''₁. ().

Further properties and definitions

Every λ-ring has characteristic 0 and contains the λ-ring Z as a λ-subring. Many notions of

commutative algebra Commutative algebra, first known as ideal theory, is the branch of algebra that studies commutative rings, their ideal (ring theory), ideals, and module (mathematics), modules over such rings. Both algebraic geometry and algebraic number theo ...

can be extended to λ-rings. For example, a λ-homomorphism between λ-rings ''R'' and ''S'' is a

ring homomorphism In mathematics, a ring homomorphism is a structure-preserving function between two rings. More explicitly, if ''R'' and ''S'' are rings, then a ring homomorphism is a function that preserves addition, multiplication and multiplicative identity ...

''f : R → S'' such that ''f''(λ^''n''(''x'')) = λ^''n''(''f''(''x'')) for all ''x'' in ''R'' and all ''n'' ≥ 0. A λ-ideal in the λ-ring ''R'' is an ideal ''I'' in ''R'' such that λ^''n''(''x'') ϵ ''I'' for all ''x'' in ''R'' and all ''n'' ≥ 1. If ''x'' is an element of a λ-ring and ''m'' a non-negative integer such that λ^''m''(''x'') ≠ 0 and λ^''n''(''x'') = 0 for all ''n'' > ''m'', we write dim(''x'') = ''m'' and call the element ''x'' finite-dimensional. Not all elements need to be finite-dimensional. We have dim(''x''+''y'') ≤ dim(''x'') + dim(''y'') and the product of elements is .

References

* *Expo 0 and V of * * * * * * * {{DEFAULTSORT:Lambda-ring Ring theory K-theory