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Modular representation theory
Modular representation theory
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Modular representation theory is a branch of mathematics, and is the part of representation theory that studies linear representations of finite groups over a field K of positive characteristic p, necessarily a prime number. As well as having applications to group theory, modular representations arise naturally in other branches of mathematics, such as algebraic geometry, coding theory[citation needed], combinatorics and number theory.

Within finite group theory, character-theoretic results proved by Richard Brauer using modular representation theory played an important role in early progress towards the classification of finite simple groups, especially for simple groups whose characterization was not amenable to purely group-theoretic methods because their Sylow 2-subgroups were too small in an appropriate sense. Also, a general result on embedding of elements of order 2 in finite groups called the Z* theorem, proved by George Glauberman using the theory developed by Brauer, was particularly useful in the classification program.

If the characteristic p of K does not divide the order |G|, then modular representations are completely reducible, as with ordinary (characteristic 0) representations, by virtue of Maschke's theorem. In the other case, when |G| ≡ 0 (mod p), the process of averaging over the group needed to prove Maschke's theorem breaks down, and representations need not be completely reducible. Much of the discussion below implicitly assumes that the field K is sufficiently large (for example, K algebraically closed suffices), otherwise some statements need refinement.

History

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The earliest work on representation theory over finite fields is by Dickson (1902) who showed that when p does not divide the order of the group, the representation theory is similar to that in characteristic 0. He also investigated modular invariants of some finite groups. The systematic study of modular representations, when the characteristic p divides the order of the group, was started by Brauer (1935) and was continued by him for the next few decades.

Example

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Finding a representation of the cyclic group of two elements over F2 is equivalent to the problem of finding matrices whose square is the identity matrix. Over every field of characteristic other than 2, there is always a basis such that the matrix can be written as a diagonal matrix with only 1 or −1 occurring on the diagonal, such as

Over F2, there are many other possible matrices, such as

Over an algebraically closed field of positive characteristic, the representation theory of a finite cyclic group is fully explained by the theory of the Jordan normal form. Non-diagonal Jordan forms occur when the characteristic divides the order of the group.

Ring theory interpretation

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Given a field K and a finite group G, the group algebra K[G] (which is the K-vector space with K-basis consisting of the elements of G, endowed with algebra multiplication by extending the multiplication of G by linearity) is an Artinian ring.

When the order of G is divisible by the characteristic of K, the group algebra is not semisimple, hence has non-zero Jacobson radical. In that case, there are finite-dimensional modules for the group algebra that are not projective modules. By contrast, in the characteristic 0 case every irreducible representation is a direct summand of the regular representation, hence is projective.

Brauer characters

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Modular representation theory was developed by Richard Brauer from about 1940 onwards to study in greater depth the relationships between the characteristic p representation theory, ordinary character theory and structure of G, especially as the latter relates to the embedding of, and relationships between, its p-subgroups. Such results can be applied in group theory to problems not directly phrased in terms of representations.

Brauer introduced the notion now known as the Brauer character. When K is algebraically closed of positive characteristic p, there is a bijection between roots of unity in K and complex roots of unity of order coprime to p. Once a choice of such a bijection is fixed, the Brauer character of a representation assigns to each group element of order coprime to p the sum of complex roots of unity corresponding to the eigenvalues (including multiplicities) of that element in the given representation.

The Brauer character of a representation determines its composition factors but not, in general, its equivalence type. The irreducible Brauer characters are those afforded by the simple modules. These are integral (though not necessarily non-negative) combinations of the restrictions to elements of order coprime to p of the ordinary irreducible characters. Conversely, the restriction to the elements of order coprime to p of each ordinary irreducible character is uniquely expressible as a non-negative integer combination of irreducible Brauer characters.

Reduction (mod p)

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In the theory initially developed by Brauer, the link between ordinary representation theory and modular representation theory is best exemplified by considering the group algebra of the group G over a complete discrete valuation ring R with residue field K of positive characteristic p and field of fractions F of characteristic 0, such as the p-adic integers. The structure of R[G] is closely related both to the structure of the group algebra K[G] and to the structure of the semisimple group algebra F[G], and there is much interplay between the module theory of the three algebras.

Each R[G]-module naturally gives rise to an F[G]-module, and, by a process often known informally as reduction (mod p), to a K[G]-module. On the other hand, since R is a principal ideal domain, each finite-dimensional F[G]-module arises by extension of scalars from an R[G]-module.[citation needed] In general, however, not all K[G]-modules arise as reductions (mod p) of R[G]-modules. Those that do are liftable.

Number of simple modules

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In ordinary representation theory, the number of simple modules k(G) is equal to the number of conjugacy classes of G. In the modular case, the number l(G) of simple modules is equal to the number of conjugacy classes whose elements have order coprime to the relevant prime p, the so-called p-regular classes.

Blocks and the structure of the group algebra

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In modular representation theory, while Maschke's theorem does not hold when the characteristic divides the group order, the group algebra may be decomposed as the direct sum of a maximal collection of two-sided ideals known as blocks. When the field F has characteristic 0, or characteristic coprime to the group order, there is still such a decomposition of the group algebra F[G] as a sum of blocks (one for each isomorphism type of simple module), but the situation is relatively transparent when F is sufficiently large: each block is a full matrix algebra over F, the endomorphism ring of the vector space underlying the associated simple module.

To obtain the blocks, the identity element of the group G is decomposed as a sum of primitive idempotents in Z(R[G]), the center of the group algebra over the valuation ring R of F. The block corresponding to the primitive idempotent e is the two-sided ideal e R[G]. For each indecomposable R[G]-module, there is only one such primitive idempotent that does not annihilate it, and the module is said to belong to (or to be in) the corresponding block (in which case, all its composition factors also belong to that block). In particular, each simple module belongs to a unique block. Each ordinary irreducible character may also be assigned to a unique block according to its decomposition as a sum of irreducible Brauer characters. The block containing the trivial module is known as the principal block.

Projective modules

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In ordinary representation theory, every indecomposable module is irreducible, and so every module is projective. However, the simple modules with characteristic dividing the group order are rarely projective. Indeed, if a simple module is projective, then it is the only simple module in its block, which is then isomorphic to the endomorphism algebra of the underlying vector space, a full matrix algebra. In that case, the block is said to have 'defect 0'. Generally, the structure of projective modules is difficult to determine.

For the group algebra of a finite group, the (isomorphism types of) projective indecomposable modules are in a one-to-one correspondence with the (isomorphism types of) simple modules: the socle of each projective indecomposable is simple (and isomorphic to the top), and this affords the bijection, as non-isomorphic projective indecomposables have non-isomorphic socles. The multiplicity of a projective indecomposable module as a summand of the group algebra (viewed as the regular module) is the dimension of its socle (for large enough fields of characteristic zero, this recovers the fact that each simple module occurs with multiplicity equal to its dimension as a direct summand of the regular module).

Each projective indecomposable module (and hence each projective module) in positive characteristic p may be lifted to a module in characteristic 0. Using the ring R as above, with residue field K, the identity element of G may be decomposed as a sum of mutually orthogonal primitive idempotents (not necessarily central) of K[G]. Each projective indecomposable K[G]-module is isomorphic to e.K[G] for a primitive idempotent e that occurs in this decomposition. The idempotent e lifts to a primitive idempotent, say E, of R[G], and the left module E.R[G] has reduction (mod p) isomorphic to e.K[G].

Some orthogonality relations for Brauer characters

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When a projective module is lifted, the associated character vanishes on all elements of order divisible by p, and (with consistent choice of roots of unity), agrees with the Brauer character of the original characteristic p module on p-regular elements. The (usual character-ring) inner product of the Brauer character of a projective indecomposable with any other Brauer character can thus be defined: this is 0 if the second Brauer character is that of the socle of a non-isomorphic projective indecomposable, and 1 if the second Brauer character is that of its own socle. The multiplicity of an ordinary irreducible character in the character of the lift of a projective indecomposable is equal to the number of occurrences of the Brauer character of the socle of the projective indecomposable when the restriction of the ordinary character to p-regular elements is expressed as a sum of irreducible Brauer characters.

Decomposition matrix and Cartan matrix

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The composition factors of the projective indecomposable modules may be calculated as follows: Given the ordinary irreducible and irreducible Brauer characters of a particular finite group, the irreducible ordinary characters may be decomposed as non-negative integer combinations of the irreducible Brauer characters. The integers involved can be placed in a matrix, with the ordinary irreducible characters assigned rows and the irreducible Brauer characters assigned columns. This is referred to as the decomposition matrix, and is frequently labelled D. It is customary to place the trivial ordinary and Brauer characters in the first row and column respectively. The product of the transpose of D with D itself results in the Cartan matrix, usually denoted C; this is a symmetric matrix such that the entries in its j-th row are the multiplicities of the respective simple modules as composition factors of the j-th projective indecomposable module. The Cartan matrix is non-singular; in fact, its determinant is a power of the characteristic of K.

Since a projective indecomposable module in a given block has all its composition factors in that same block, each block has its own Cartan matrix.

Defect groups

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To each block B of the group algebra K[G], Brauer associated a certain p-subgroup, known as its defect group (where p is the characteristic of K). Formally, it is the largest p-subgroup D of G for which there is a Brauer correspondent of B for the subgroup , where is the centralizer of D in G.

The defect group of a block is unique up to conjugacy and has a strong influence on the structure of the block. For example, if the defect group is trivial, then the block contains just one simple module, just one ordinary character, the ordinary and Brauer irreducible characters agree on elements of order prime to the relevant characteristic p, and the simple module is projective. At the other extreme, when K has characteristic p, the Sylow p-subgroup of the finite group G is a defect group for the principal block of K[G].

The order of the defect group of a block has many arithmetical characterizations related to representation theory. It is the largest invariant factor of the Cartan matrix of the block, and occurs with multiplicity one. Also, the power of p dividing the index of the defect group of a block is the greatest common divisor of the powers of p dividing the dimensions of the simple modules in that block, and this coincides with the greatest common divisor of the powers of p dividing the degrees of the ordinary irreducible characters in that block.

Other relationships between the defect group of a block and character theory include Brauer's result that if no conjugate of the p-part of a group element g is in the defect group of a given block, then each irreducible character in that block vanishes at g. This is one of many consequences of Brauer's second main theorem.

The defect group of a block also has several characterizations in the more module-theoretic approach to block theory, building on the work of J. A. Green, which associates a p-subgroup known as the vertex to an indecomposable module, defined in terms of relative projectivity of the module. For example, the vertex of each indecomposable module in a block is contained (up to conjugacy) in the defect group of the block, and no proper subgroup of the defect group has that property.

Brauer's first main theorem states that the number of blocks of a finite group that have a given p-subgroup as defect group is the same as the corresponding number for the normalizer in the group of that p-subgroup.

The easiest block structure to analyse with non-trivial defect group is when the latter is cyclic. Then there are only finitely many isomorphism types of indecomposable modules in the block, and the structure of the block is by now well understood, by virtue of work of Brauer, E.C. Dade, J.A. Green and J.G. Thompson, among others. In all other cases, there are infinitely many isomorphism types of indecomposable modules in the block.

Blocks whose defect groups are not cyclic can be divided into two types: tame and wild. The tame blocks (which only occur for the prime 2) have as a defect group a dihedral group, semidihedral group or (generalized) quaternion group, and their structure has been broadly determined in a series of papers by Karin Erdmann. The indecomposable modules in wild blocks are extremely difficult to classify, even in principle.

References

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Modular representation theory

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Modular representation theory is a branch of representation theory that examines linear representations of finite groups over fields of positive characteristic pp, especially when pp divides the order of the group, leading to non-semisimple structures unlike the completely reducible representations in characteristic zero. In this setting, a representation is a homomorphism from the group to the general linear group over a vector space, but Maschke's theorem fails to guarantee complete reducibility, resulting in indecomposable modules that cannot be expressed as direct sums of irreducibles. Key concepts include irreducible modules, which admit no nontrivial submodules, and projective modules, which play a central role in resolving the complexities arising from the characteristic dividing the group order. Tools such as Brauer characters, defined on pp-regular elements of the group, extend ordinary to identify composition factors and decomposition numbers, while block theory decomposes the group algebra into indecomposable components linked by central characters. The Jacobson radical of the group algebra further aids in analyzing these structures by intersecting maximal ideals. Historically, the foundations were laid by Maschke's work in 1899 on semisimple representations, but modular theory advanced significantly through Richard Brauer's contributions starting in 1935, including character-theoretic methods that influenced the classification of finite simple groups. Later developments by J.A. Green introduced module-theoretic approaches, emphasizing rings and algebras, with applications extending to symmetric groups, Lie-type groups, and connections to quantum groups and diagrammatic algebras like the Temperley-Lieb algebra. These ideas underpin broader areas in algebra, including the study of Cartan matrices and Grothendieck groups for tracking module compositions.

Historical Development

Origins and Early Work

Modular representation theory emerged in the late as mathematicians sought to extend the theory of linear representations of finite groups from fields of characteristic zero, such as the complex numbers, to fields of positive characteristic. A foundational contribution came from in 1897, who examined the decomposition of the of the S3S_3 over fields of characteristic 2 and 3 in his supplements to Dirichlet's Vorlesungen über Zahlentheorie. For characteristic 2, Dedekind computed the group determinant Θ(S3)\Theta(S_3) and observed that it factors as (Φ1Φ3)2mod2(\Phi_1 \Phi_3)^2 \mod 2, where Φ3\Phi_3 is an irreducible quadratic factor appearing with multiplicity 2, exceeding its degree, indicating non-semisimplicity. Similarly, in characteristic 3, Θ(S3)(Φ1Φ2)3mod3\Theta(S_3) \equiv (\Phi_1 \Phi_2)^3 \mod 3, with factors appearing to multiplicity 3. These explicit computations highlighted deviations from characteristic-zero behavior, laying groundwork for understanding modular decompositions. Issai Schur built upon these ideas in the early 1900s, extending to symmetric groups SnS_n and incorporating initial modular considerations. In his 1901 doctoral thesis and subsequent 1905 paper, Schur developed a comprehensive framework for the irreducible representations of SnS_n over the complex numbers, using Young tableaux to parametrize them, but he also explored forms and reductions primes. These efforts revealed how ordinary representations of symmetric groups behave under modular reduction, particularly when the characteristic divides the group order, influencing later modular classifications. Schur's work connected group representations to symmetric polynomials and , providing tools for analyzing modular cases through combinatorial methods. A key motivation for modular theory arose from the failure of Maschke's theorem in positive characteristic, first articulated by Heinrich Maschke in 1898 for characteristic zero, where group algebras are semisimple. , in his 1903 paper on linear substitutions and bilinear forms, proved that the group F[G]\mathbb{F}[G] over a field F\mathbb{F} of characteristic not dividing G|G| is semisimple, but fails otherwise, as the averaging projector no longer works due to division by G|G| becoming impossible. This semisimple structure underpinned ordinary but broke down modularly, prompting investigations into indecomposable representations and blocks. Early 20th-century developments, notably by Eugene Dickson in his 1907 address on modular theory of group characters, linked these issues to and modular class functions. Dickson extended Frobenius's character orthogonality to prime characteristic, using class functions to study reductions, and connected modular representations to invariants of binary forms under modular transformations, bridging and .

Key Advances and Modern Contributions

Richard Brauer's foundational work in the 1930s and 1950s established the framework for modular and block decomposition, enabling the study of representations over fields of characteristic dividing the group order. In particular, his 1941 paper introduced key relations between ordinary and modular characters, culminating in the theorem that the number of irreducible ordinary characters in a block equals the number of irreducible modular characters in that block. This result, often referred to as the Brauer-Cartan theorem in this context, bounds the number of simple modules per block and underpins subsequent block theory. Brauer characters, developed during this era as traces of modular representations on p-regular elements, serve as essential tools for lifting ordinary characters to modular settings. In the , James A. Green advanced the local structure of modules by introducing vertices and sources for indecomposable modules, providing a way to associate p-subgroups to module projectivity. Green's work defined the vertex of an indecomposable kG-module as a minimal p-subgroup Q such that the module is projective relative to N_G(Q), with sources capturing the local behavior over the normalizer. This framework, formalized in his Green correspondence, links indecomposable modules across subgroups and has become central to analyzing module lattices. During the and , contributions from Hisao Nagao and others refined defect groups and block invariants, shifting focus toward p-local properties. Nagao's theorem provided a module-theoretic analogue to Brauer's second main theorem, relating block idempotents to defect group actions. These developments solidified defect groups as conjugacy classes of p-subgroups determining block multiplicity and fusion, with applications to symmetric and alternating groups. Post-1980 extensions to finite groups of type have emphasized block invariants and equivalences, notably through work by Michel Broué and Jon Alperin. Broué's 1980s conjectures on abelian defect groups for principal blocks of type groups link modular representations to affine Weyl groups via derived equivalences. Alperin's fusion theorem (1986) and joint results with Broué classify block invariants like the number of simple modules via p-local data, facilitating computations for groups like GL_n(q). These invariants have proven crucial for verifying Brauer's k(B)-conjecture in type settings. The Alperin-McKay conjecture, proposed in the , posits that for a prime p, the number of irreducible characters of degree not divisible by p equals that for p-subgroups, with block-wise versions refining fusion patterns; it remains open in general as of , though a 2025 result completes its proof for the prime 2 in quasi-isolated blocks of exceptional groups of type, alongside partial resolutions for maximal defect blocks. Recent progress includes inductive verifications for quasi-isolated blocks, reducing it to local conditions. Computational tools have transformed modular representation theory, addressing gaps in manual verification; MAGMA's implementation of the MeatAxe algorithm decomposes modules over finite fields to compute Brauer characters and decomposition matrices. The MeatAxe, integrated into GAP and standalone, has facilitated computations for sporadic groups and symmetric groups, enabling checks of block invariants.

Basic Concepts and Examples

Definition and Setup

Modular representation theory is the study of representations of s over fields of positive characteristic. For a GG and a field kk of characteristic p>0p > 0 dividing the order G|G|, a modular representation of GG over kk is a finite-dimensional kGkG-module, where kGkG denotes the group algebra of GG over kk. This framework contrasts sharply with ordinary over fields of characteristic zero, such as C\mathbb{C}, where every representation is semisimple (completely reducible into a of irreducible representations) by Maschke's , as the group order G|G| is invertible in the field. In the modular setting, fails because pp divides G|G|, rendering the averaging operator over the group elements noninvertible in kk. Consequently, kGkG-modules are generally indecomposable and exhibit more complex structure, with every finite-dimensional module possessing a whose factors are simple modules. The kGkG itself is Artinian (as a finite-dimensional ) but not semisimple, leading to the study of its Jacobson radical and related invariants to understand module categories. The setup typically assumes kk is algebraically closed of characteristic pp, ensuring that every appears in a completely reducible module over an extension; more generally, kk may be any for kGkG, meaning the algebra decomposes into a of matrix algebras over division rings that split over kk. The term "modular" specifically denotes representations in characteristic pp dividing G|G|, distinguishing it from the broader "characteristic pp" context where pp may not divide the group order, and reflects the origins in modulo pp. This terminology evolved in the early alongside the development of the theory, emphasizing the reduction modulo pp from characteristic zero cases.

Illustrative Example

A concrete illustration of modular representation theory arises from the S3S_3, which has order 6 and σ,τσ3=τ2=1,τστ=σ1\langle \sigma, \tau \mid \sigma^3 = \tau^2 = 1, \tau \sigma \tau = \sigma^{-1} \rangle where σ=(123)\sigma = (1\,2\,3) and τ=(12)\tau = (1\,2). Consider the group algebra kS3kS_3 over the field k=F2k = \mathbb{F}_2 of characteristic 2. This algebra has dimension 6 with {1,σ,σ2,τ,στ,σ2τ}\{1, \sigma, \sigma^2, \tau, \sigma\tau, \sigma^2\tau\}. The augmentation map is the kk-linear trace ε:kS3k\varepsilon: kS_3 \to k defined by ε(gS3agg)=gS3ag\varepsilon\left( \sum_{g \in S_3} a_g g \right) = \sum_{g \in S_3} a_g, which is a surjective algebra homomorphism. The augmentation ideal is I=kerε=spank{g+1gS3,g1}I = \ker \varepsilon = \operatorname{span}_k \{ g + 1 \mid g \in S_3, g \neq 1 \} (noting that 1=1-1 = 1 in characteristic 2), which has dimension 5 and coincides with the Jacobson radical rad(kS3)\operatorname{rad}(kS_3). The quotient kS3/IkkS_3 / I \cong k realizes the trivial representation as a simple module. In characteristic 2, S3S_3 has two irreducible representations up to isomorphism: the 1-dimensional trivial module D(3)D^{(3)} (where the superscript denotes the partition labeling the Specht module) and the 2-dimensional simple module D(2,1)D^{(2,1)}. The latter admits an explicit basis {e1,e2}\{e_1, e_2\} where e1={123}+{321}e_1 = \{1\,2\,3\} + \{3\,2\,1\} and e2={132}+{231}e_2 = \{1\,3\,2\} + \{2\,3\,1\} in the permutation basis, with action σe1=e2\sigma \cdot e_1 = e_2 and σe2=e1+e2\sigma \cdot e_2 = e_1 + e_2, while transpositions act by swapping or fixing accordingly. The regular module kS3kS_3 decomposes into two blocks: the principal block (spanned by the idempotent e1=1+σ+σ2e_1 = 1 + \sigma + \sigma^2) containing the trivial simple, and a unipotent block (spanned by e2=σ+σ2e_2 = \sigma + \sigma^2) containing the 2-dimensional simple. Non-semisimplicity is evident in the permutation module M=kkkM = k \oplus k \oplus k with basis {e1,e2,e3}\{e_1, e_2, e_3\} corresponding to the standard action of S3S_3 on three points. The subspace U=e1+e2+e3U = \langle e_1 + e_2 + e_3 \rangle is the 1-dimensional trivial socle of MM, and the M/UD(2,1)M/U \cong D^{(2,1)} is the 2-dimensional simple head. Thus, MM is an indecomposable module of Loewy length 2 with composition factors D(3)D^{(3)} (multiplicity 1) and D(2,1)D^{(2,1)} (multiplicity 1), realizing a non-split extension 0D(3)MD(2,1)00 \to D^{(3)} \to M \to D^{(2,1)} \to 0. The submodule lattice of MM is a chain: {0}UM\{0\} \subset U \subset M with successive quotients U/{0}D(3)U/\{0\} \cong D^{(3)} and M/UD(2,1)M/U \cong D^{(2,1)}. In characteristic 3 over k=F3k = \mathbb{F}_3, the irreducibles are the 1-dimensional trivial D(3)D^{(3)} and D(1,1,1)D^{(1,1,1)} modules (the latter nontrivial since the sign is faithful in odd characteristic not dividing 3). The group algebra kS3kS_3 remains non-semisimple, with both indecomposable projectives of dimension 3 having Loewy length 3 and composition factors mixing the trivial and modules ( (2112)\begin{pmatrix} 2 & 1 \\ 1 & 2 \end{pmatrix}). For instance, the projective cover of the trivial has series with factors trivial (socle), , trivial (head). The 2-dimensional representation from characteristic 0 reduces modulo 3 to the semisimple module D(3)D(1,1,1)D^{(3)} \oplus D^{(1,1,1)}.

Algebraic Foundations

Group Algebra over Modular Rings

The group algebra kGkG of a finite group GG over a field kk of characteristic pp is the associative kk-algebra consisting of all formal kk-linear combinations gGcgg\sum_{g \in G} c_g g with cgkc_g \in k, equipped with extended linearly from the group operation via gh=ghg \cdot h = gh for g,hGg, h \in G. This endows kGkG with a basis {ggG}\{g \mid g \in G\} of G|G|, making it a finite-dimensional algebra of dimension G|G| over kk. The unit element is the identity 1G1_G of GG, and the algebra is unital. As a finite-dimensional algebra over a field, kGkG is Artinian and possesses rich ring-theoretic structure, notably as a symmetric Frobenius algebra regardless of whether pp divides G|G|. The Frobenius form is the nondegenerate bilinear pairing β:kG×kGk\beta: kG \times kG \to k defined by β(a,b)\beta(a, b) as the coefficient of the identity element in the product aba b, which satisfies β(ab,c)=β(a,bc)\beta(a b, c) = \beta(a, b c) for all a,b,ckGa, b, c \in kG. This symmetry follows from β(a,b)=β(b,a)\beta(a, b) = \beta(b, a) since the coefficient extraction is invariant under reversal via inverses in GG. Consequently, kGkG is quasi-Frobenius, meaning it is injective as a module over itself on both sides, with every projective module being injective and the socle and top composition factors isomorphic. In the broader context of ring theory, kGkG serves as a prototypical example of a finite-dimensional Hopf algebra, with coproduct Δ(g)=gg\Delta(g) = g \otimes g, counit ϵ(g)=1\epsilon(g) = 1, and antipode S(g)=g1S(g) = g^{-1}, though its finite-dimensionality underscores its role in modular representation theory. The center Z(kG)Z(kG) of kGkG is the subalgebra of elements that commute with every basis element, and it has kk-dimension equal to the number of conjugacy classes of GG; a basis for Z(kG)Z(kG) is given by the class sums cC=gCgc_C = \sum_{g \in C} g over each conjugacy class CC of GG. This spanning property holds independently of the characteristic pp, as conjugation preserves the linear independence of these sums. When pp does not divide G|G|, kGkG is semisimple by Maschke's theorem, and the Artin-Wedderburn theorem decomposes it as kGi=1lMni(Di)kG \cong \prod_{i=1}^l M_{n_i}(D_i), where each DiD_i is a finite-dimensional over kk and the nin_i are the dimensions of the irreducible representations. In the modular case where pp divides G|G|, kGkG is indecomposable as an algebra but possesses a Jacobson radical J(kG)J(kG), and the kG/J(kG)kG / J(kG) is semisimple with an analogous Artin-Wedderburn decomposition into matrix algebras over division rings, where the division rings may be non-commutative extensions adapted to the characteristic pp unless kk is a . Simple kGkG-modules in the semisimple case correspond to primitive central idempotents in Z(kG)Z(kG).

Reduction Modulo p

In modular representation theory, the process of reducing ordinary representations over the complex numbers C\mathbb{C} to modular representations over a field kk of characteristic pp begins with an model. Specifically, consider a CG\mathbb{C}G-representation VV realized via a ZG\mathbb{Z}G-lattice LL, which is a free Z\mathbb{Z}-module of finite rank equipped with a GG-action compatible with the group ring ZG\mathbb{Z}G. The reduction modulo pp yields the kGkG-module Lˉ=L/pLFpk\bar{L} = L/pL \otimes_{\mathbb{F}_p} k, where the tensor product ensures the structure over the splitting field kk. This construction bridges characteristic zero and positive characteristic, allowing the study of modular structure through ordinary data. The isomorphism class of Lˉ\bar{L} depends on the choice of lattice LL, as different Z\mathbb{Z}-forms of the same VV can produce non-isomorphic modular modules. However, all such reductions share the same composition factors, meaning they have identical Jordan-Hölder multiplicities for the simple kGkG-modules. This property follows from the consistency of Brauer characters across equivalent forms, ensuring that the modular content is invariant under lattice selection. For a CG\mathbb{C}G-representation ρ\rho with character χ\chi, the modular reduction is captured by specializing the character values modulo pp, but this requires embedding the cyclotomic field containing χ(g)\chi(g) into a pp-adic completion and reducing via the maximal ideal. Formally, if χ(g)\chi(g) lies in the ring of algebraic integers Z\overline{\mathbb{Z}}, the Brauer character ϕ\phi of ρˉ\bar{\rho} on pp-regular elements is given by ϕ(g)=θi(g)\phi(g) = \sum \overline{\theta_i(g)}, where θi\theta_i are lifts of eigenvalues to characteristic zero, but the result is non-unique due to embedding choices and lattice variations. This non-canonical nature underscores the role of the decomposition matrix in relating ordinary and modular characters precisely. Brauer's lifting theorem guarantees that every simple kGkG-module SS appears as a composition factor in Lˉ\bar{L} for some irreducible ZG\mathbb{Z}G-lattice LL associated to an irreducible CG\mathbb{C}G-module. The theorem establishes the surjectivity of the reduction map on the level of Grothendieck groups, with decomposition numbers dχ,S0d_{\chi,S} \geq 0 integers recording multiplicities, and ensures no modular simple is "missed" in the ordinary-to-modular transition. Illustrative examples of this reduction process reveal indecomposable structures akin to Jordan blocks. For the symmetric group S3S_3 with p=3p=3, the 2-dimensional irreducible ordinary representation reduces to a uniserial kGkG-module of length 2, with simple head (the sign module) and socle (the trivial module), demonstrating how non-semisimple extensions emerge modulo pp. Similar reductions in dihedral groups or pp-groups often yield chains of simple factors, highlighting the breakdown of complete reducibility in characteristic pp. Post-2000 developments have refined this framework through pp-adic lifts, allowing modular representations to be elevated to modules over pp-adic rings like Zp\mathbb{Z}_p or Z/p2Z\mathbb{Z}/p^2\mathbb{Z} for greater precision in deformations. For instance, in the representation theory of SL2(pr)\mathrm{SL}_2(p^r), basic homogeneous representations Vi(pr)V_i(p^r) (for 1ip1 \leq i \leq p) lift to Z/p2Z\mathbb{Z}/p^2\mathbb{Z} if and only if r=1r=1 and specific conditions on pp and ii hold, such as i=p2i = p-2 or p1p-1 for odd pp, with further lifts to Qp\mathbb{Q}_p possible; these results rely on computing Ext-groups to resolve obstructions. These reductions connect to stable isomorphism classes, where two kGkG-modules MM and NN (arising from different lattices) are stably isomorphic if MPNQM \oplus P \cong N \oplus Q for some projective modules P,QP, Q. Since projectives are trivial in the category, this equivalence preserves essential modular invariants like composition factors and endomorphism rings up to stable structure, facilitating comparisons across lattice choices.

Character Theory

Brauer Characters

In modular representation theory, the Brauer character of a kGkG-module MM, where kk is a field of characteristic pp and GG is a finite group, is defined as a class function ϕM:GpC\phi_M: G_{p' } \to \mathbb{C} on the pp-regular elements GpG_{p'}, taking values in a cyclotomic field. For a pp-regular gGg \in G, ϕM(g)\phi_M(g) is the sum iθ(λi)\sum_i \theta(\lambda_i), where λ1,,λdimkM\lambda_1, \dots, \lambda_{\dim_k M} are the eigenvalues of the matrix representing the action of gg on MM (over an algebraic closure of kk), and θ:k×C×\theta: k^\times \to \mathbb{C}^\times is a fixed embedding sending nonzero elements of kk to roots of unity of order prime to pp. Brauer characters are additive: for modules MM and NN, ϕMN=ϕM+ϕN\phi_{M \oplus N} = \phi_M + \phi_N, and more generally, they respect short exact sequences. The irreducible Brauer characters, corresponding to the simple kGkG-modules, form a basis for the space of class functions on GpG_{p'}. To compute a Brauer character, one lifts the modular representation to characteristic zero via a modular system and restricts to pp-regular elements, or directly finds the eigenvalues modulo pp and applies the embedding θ\theta to obtain the trace as ϕM(g)=iθ(λi)\phi_M(g) = \sum_i \theta(\lambda_i). For cyclic groups, Brauer characters simplify due to the diagonalizability of representations. Consider G=C3=xx3=1G = C_3 = \langle x \mid x^3 = 1 \rangle and p=3p=3; in characteristic zero, there are one-dimensional trivial and sign representations, but since pp divides G|G|, there is a unique irreducible of dimension 1 (the trivial). Here, Gp={1}G_{p'} = \{1\}, so Brauer characters are determined by their value at the identity, which equals the module dimension; for the regular module, ϕ(1)=3\phi(1) = 3. (In general, the regular module has Brauer character G|G| at 1 and 0 at other p-regular elements.) Recent work provides bounds on Brauer character degrees; for instance, if a prime qq (odd, with (p,q)(2,3)(p,q) \ne (2,3)) divides the degree of every nonlinear irreducible pp-Brauer character, then GG has a normal qq-complement.

Orthogonality Relations

The relations for Brauer characters provide fundamental tools for decomposing modular representations, mirroring the role of Frobenius-Schur orthogonality in characteristic zero but restricted to p-regular elements of the G. Let φ and ψ denote Brauer characters of FG-modules, where F is a of characteristic p. The inner product is defined as ϕ,ψ=1GgGpϕ(g)ψ(g1),\langle \phi, \psi \rangle = \frac{1}{|G|} \sum_{g \in G_{p'}} \phi(g) \overline{\psi(g^{-1})}, where G_{p'} is the set of p-regular elements (those of order coprime to p), and the sum is over conjugacy classes weighted appropriately by centralizer sizes in the unnormalized form. This Hermitian form equips the space of F-class functions on G_{p'} with an . For distinct irreducible Brauer characters φ_i and φ_j belonging to Irr_F(G), the basic row relation states that ⟨φ_i, φ_j⟩ = δ_{ij}, ensuring and establishing that the set {φ_i} forms an for the space of generalized Brauer characters. The unnormalized version follows as KClp(G)ϕi(gK)ϕj(gK)CG(gK)=δij,\sum_{K \in Cl_{p'}(G)} \frac{\phi_i(g_K) \overline{\phi_j(g_K)}}{|C_G(g_K)|} = \delta_{ij}, where Cl_{p'}(G) denotes the p-regular conjugacy classes and g_K is a representative of class K; here, l = |Cl_{p'}(G)| is the number of such classes, and the relation highlights the p-part |G|_p in the normalization when projecting to block structures. Column orthogonality in the modular setting extends the classical induction formulas and involves projective indecomposable characters Φ_ψ associated to irreducible Brauer characters ψ. Specifically, for p-regular elements g and h, ψIrrF(G)ψ(g1)Φψ(h)=CG(g)δgh,\sum_{\psi \in \mathrm{Irr}_F(G)} \psi(g^{-1}) \Phi_\psi(h) = |C_G(g)| \delta_{g \sim h}, where the sum is over irreducibles and δ_{g \sim h} is 1 if g and h are conjugate, else 0; this holds for induction from subgroups via Brauer's induction theorem, allowing decomposition of induced Brauer characters from p-regular classes in subgroups. These relations imply symmetry properties, such as the unitarity of the Brauer character table when viewed as a matrix over p-regular classes, and facilitate computations of dimensions and multiplicities in the Grothendieck group of FG-modules. A key application arises in decomposing permutation characters modulo p. The Brauer character of a permutation FG-module, obtained by reducing the ordinary permutation character to characteristic p and restricting to p-regular elements, decomposes as ∑_i m_i φ_i, where the multiplicity m_i = ⟨φ_i, \mathrm{perm}^B⟩ equals the number of fixed points of the permutation on p-regular elements, averaged appropriately; this inner product yields explicit formulas for the modular constituents of transitive permutation representations. Generalized orthogonality relations refine these for characters within p-blocks of the group algebra, incorporating height-zero characters and defect groups. Broué established such relations, showing that characters of height zero in a block satisfy enhanced with respect to block idempotents, bounding the number of irreducibles and linking to local structure.

Module Structure

Simple Modules and Their Number

In modular representation theory, the simple kGkG-modules, where GG is a and kk is a field of characteristic p>0p > 0, are the irreducible modules up to , denoted D1,,DlD_1, \dots, D_l. The number ll of these distinct simple modules equals the number of pp-regular conjugacy classes in GG, as established by Brauer's theorem. A conjugacy class is pp-regular if its elements have order coprime to pp. These simple modules are labeled by the irreducible Brauer characters, which are the characters afforded by the simple kGkG-modules evaluated on pp-regular elements. Assumptions often include kk being a splitting field, where the simple modules are absolutely irreducible, EndkG(Di)=k\operatorname{End}_{kG}(D_i) = k, and Brauer characters fully capture their traces on pp-regular elements. In the structure of general finite kGkG-modules, the simple modules appear as composition factors; specifically, the head of a module is its maximal semisimple quotient, which is a direct sum of simple modules, and the socle is its maximal semisimple submodule, likewise a direct sum of simples. Over a kk for kGkG, each simple module DiD_i satisfies dimkEndkG(Di)=1\dim_k \operatorname{End}_{kG}(D_i) = 1, by the modular analogue of , implying that the endomorphism ring is exactly kk. In non-splitting fields, the endomorphism ring EndkG(Di)\operatorname{End}_{kG}(D_i) is a finite-dimensional over kk, with dimension greater than 1, leading to more complex realization of the simples as representations. The composition multiplicities dijd_{ij} quantify how ordinary irreducible characters χj\chi_j decompose into modular simples upon reduction modulo pp, defined as the multiplicity [Sj:Di][S_j : D_i], where SjS_j is the simple CG\mathbb{C}G-module affording χj\chi_j. These multiplicities form the decomposition matrix, central to linking ordinary and modular theory.

Projective Modules

In modular representation theory, a kG-module P, where k is a field of characteristic p and G is a with p dividing |G|, is projective if it is a direct summand of a free kG-module, equivalently if the Hom_kG(P, −) is exact. The group algebra kG itself is projective as the free kG-module of , and it decomposes as a of indecomposable projective modules PiP_i (i = 1, \dots, l(G)), where l(G) is the number of simple kG-modules; these P_i are unique up to and form a complete set of representatives for the indecomposables. Each P_i has a simple head D_i = P_i / radkG(Pi)\mathrm{rad}_{kG}(P_i), establishing a between the isomorphism classes of indecomposable projectives and simple modules. Every finite-length kG-module M admits a projective cover, a surjective kG-homomorphism π: Q → M from an indecomposable projective Q = P(D) with kernel radkG(Q)\mathrm{rad}_{kG}(Q), unique up to , such that any other surjection from a projective to M factors through π. This cover allows the construction of minimal projective resolutions, sequences P1P0M0\cdots \to P_1 \to P_0 \to M \to 0 where the P_j are indecomposables and the images of the maps generate the radicals, providing tools for Ext\operatorname{Ext} groups and cohomological dimensions in the category of kG-modules. The dimension of the indecomposable projective P_i is given by dimkPi=GpdimDi\dim_k P_i = |G|_p \dim D_i, where |G|_p denotes the p-part of |G| (the highest power of p dividing |G|). The Green correspondence provides a between the indecomposable kG-modules with vertex J and the indecomposable kN_G(J)-modules with vertex J, where J is a p-subgroup of G, such that for corresponding modules M and N, M is isomorphic to IndNG(J)GN\operatorname{Ind}_{N_G(J)}^G N \oplus (projective kG-module), and conversely N is a direct summand of ResGNG(J)M\operatorname{Res}_G^{N_G(J)} M up to projectives. This correspondence preserves the lattice of submodules and is essential for reducing the study of global module structure to local data near p-subgroups. For an indecomposable kG-module M, a vertex is a minimal p-subgroup ≤ G such that M is relatively -projective, meaning M is a direct summand of IndQGN\mathrm{Ind}_Q^G N for some k-module N; all vertices are conjugate, and is essential in the sense that no proper of has this property. The corresponding source module N is indecomposable over k with M a direct summand of IndQGN\mathrm{Ind}_Q^G N, and for projective M, the vertex is the trivial with source the trivial module. The vertices classify the "p-local" behavior of modules, linking global projectives to local sources over p-subgroups. Source modules play a key role in describing projectives via induction from p-subgroups, and the Endo-Levi characterizes the ring EndkG(P)\operatorname{End}_{kG}(P) of an indecomposable projective P as a with radical structure determined by the source, providing a into matrix rings over division rings with p-group action; originally proved in the 1950s using classical methods, modern proofs employ of the module category.

Advanced Block Theory

Blocks of the Group Algebra

In modular representation theory, the group algebra kGkG over an algebraically closed field kk of characteristic p>0p > 0 decomposes as a direct sum kG=bbkGkG = \bigoplus_b b kG, where the sum runs over the primitive central idempotents bb in the center Z(kG)Z(kG). Each such bb determines a block B=bkGB = b kG, which is a two-sided ideal of kGkG and serves as the identity element for modules in that block. The simple kGkG-modules are partitioned into these blocks, with a module MM belonging to the block bb if bM=MbM = M. This decomposition arises from the semisimple structure of the commutative ring Z(kG)Z(kG), whose dimension equals the number of blocks. Brauer's block theory establishes a correspondence between blocks of kGkG and certain subsets of ordinary irreducible characters and modular irreducible (Brauer) characters, linked through the decomposition matrix DD. Specifically, the matrix DD, whose entries are the multiplicities of modular simples in the reductions modulo pp of ordinary characters, takes a block-diagonal form with respect to this partition: D=diag(DB1,,DBt)D = \operatorname{diag}(D_{B_1}, \dots, D_{B_t}), where each DBD_B describes the linkages within block BB. This framework reveals how blocks encode the interaction between characteristic-zero and modular representations, with ordinary characters in a block BB decomposing into modular characters also in BB. The number of blocks is at most the number of pp-regular conjugacy classes in GG, as the latter equals the number of irreducible Brauer characters (by the Brauer-Nesbitt theorem), and each block contains at least one such character. Each block bb is associated with a central character ωb\omega_b, a linear functional on the space of class functions on pp-regular elements, defined by ωb(gClG(x))=trace(bg)\omega_b(\sum g \in Cl_G(x)) = \operatorname{trace}(b \sum g) for pp-regular xGx \in G, up to scalar multiple. These central characters distinguish the blocks and extend the trace form restricted to pp-regular elements. Locally, each block bkGb kG is indecomposable as a kGkG-bimodule, meaning it cannot be expressed as a nontrivial of bimodules. This indecomposability reflects the block's role in localizing the module category and underpins further structures like fusion systems, which model pp- interactions within the block (as developed in works post-2000, e.g., Ragnarsson's contributions on block fusion systems).

Decomposition and Cartan Matrices

In modular representation theory, the decomposition matrix DD relates the irreducible ordinary characters of a GG to its irreducible Brauer characters in characteristic pp. The rows of DD are indexed by the ordinary irreducible characters χiIrr(G)\chi_i \in \operatorname{Irr}(G), while the columns are indexed by the irreducible Brauer characters ϕjIBrp(G)\phi_j \in \operatorname{IBr}_p(G). The entry dijd_{ij} is the multiplicity with which the simple kGkG-module affording ϕj\phi_j appears as a composition factor in the reduction modulo pp of the KGKG-module affording χi\chi_i, where KK is a field of characteristic zero and kk is its of characteristic pp. The matrix DD has non-negative entries and is independent of the of modular , provided it is a . On pp-regular elements of GG, the ordinary character satisfies χi=jdijϕj\chi_i = \sum_j d_{ij} \phi_j. The 0-1 posits that all entries of DD are 0 or 1, but this remains unproven in general; computational verifications confirm it holds for many small groups and certain classes, such as symmetric groups up to degree 17 in characteristic 2, though larger cases suggest potential complexity without known counterexamples as of 2025. The matrix DD decomposes into block-diagonal form corresponding to the pp-blocks of GG, with each block submatrix having full column rank equal to the number of Brauer characters in that block. The CC encodes the composition structure of the projective indecomposable kGkG-modules. Its entries cijc_{ij} are defined as the dimension of HomkG(Pj,Pi)\operatorname{Hom}_{kG}(P_j, P_i), where PjP_j is the projective cover of the simple module with Brauer character ϕj\phi_j, or equivalently, the multiplicity of the simple head of PiP_i (isomorphic to the socle of PjP_j) in the composition series of Pj/rad(Pj)P_j / \operatorname{rad}(P_j). When kk is a for GG, CC is symmetric and positive definite, with a power of pp, and satisfies the key relation C=DTDC = D^T D. This implies cij=ldlidljc_{ij} = \sum_l d_{li} d_{lj}, linking the multiplicities in projective modules to those in ordinary reductions. For the symmetric group S3S_3 in characteristic p=3p=3, the decomposition matrix is D=(100111),D = \begin{pmatrix} 1 & 0 \\ 0 & 1 \\ 1 & 1 \end{pmatrix},
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