E6 (mathematics)
   HOME

TheInfoList



OR:

In
mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...
, E6 is the name of some closely related Lie groups, linear
algebraic group In mathematics, an algebraic group is an algebraic variety endowed with a group structure which is compatible with its structure as an algebraic variety. Thus the study of algebraic groups belongs both to algebraic geometry and group theory. Ma ...
s or their Lie algebras \mathfrak_6, all of which have dimension 78; the same notation E6 is used for the corresponding
root lattice In mathematics, a root system is a configuration of vectors in a Euclidean space satisfying certain geometrical properties. The concept is fundamental in the theory of Lie groups and Lie algebras, especially the classification and representation ...
, which has
rank Rank is the relative position, value, worth, complexity, power, importance, authority, level, etc. of a person or object within a ranking, such as: Level or position in a hierarchical organization * Academic rank * Diplomatic rank * Hierarchy * ...
 6. The designation E6 comes from the Cartan–Killing classification of the complex
simple Lie algebra In algebra, a simple Lie algebra is a Lie algebra that is non-abelian and contains no nonzero proper ideals. The classification of real simple Lie algebras is one of the major achievements of Wilhelm Killing and Élie Cartan. A direct sum of s ...
s (see ). This classifies Lie algebras into four infinite series labeled A''n'', B''n'', C''n'', D''n'', and five exceptional cases labeled E6, E7, E8, F4, and G2. The E6 algebra is thus one of the five exceptional cases. The fundamental group of the complex form, compact real form, or any algebraic version of E6 is the
cyclic group In group theory, a branch of abstract algebra in pure mathematics, a cyclic group or monogenous group is a group, denoted C''n'', that is generated by a single element. That is, it is a set of invertible elements with a single associative bina ...
Z/3Z, and its
outer automorphism group In mathematics, the outer automorphism group of a group, , is the quotient, , where is the automorphism group of and ) is the subgroup consisting of inner automorphisms. The outer automorphism group is usually denoted . If is trivial and has a t ...
is the cyclic group Z/2Z. Its
fundamental representation In representation theory of Lie groups and Lie algebras, a fundamental representation is an irreducible representation, irreducible finite-dimensional representation of a semisimple Lie algebra, semisimple Lie group or Lie algebra whose highest weig ...
is 27-dimensional (complex), and a basis is given by the 27 lines on a cubic surface. The
dual representation In mathematics, if is a group and is a linear representation of it on the vector space , then the dual representation is defined over the dual vector space as follows: : is the transpose of , that is, = for all . The dual representation ...
, which is inequivalent, is also 27-dimensional. In
particle physics Particle physics or high energy physics is the study of fundamental particles and forces that constitute matter and radiation. The fundamental particles in the universe are classified in the Standard Model as fermions (matter particles) an ...
, E6 plays a role in some
grand unified theories A Grand Unified Theory (GUT) is a model in particle physics in which, at high energies, the three gauge interactions of the Standard Model comprising the electromagnetic, weak, and strong forces are merged into a single force. Although this u ...
.


Real and complex forms

There is a unique complex Lie algebra of type E6, corresponding to a complex group of complex dimension 78. The complex adjoint Lie group E6 of
complex dimension In mathematics, complex dimension usually refers to the dimension of a complex manifold or a complex algebraic variety. These are spaces in which the local neighborhoods of points (or of non-singular points in the case of a variety) are modeled on a ...
78 can be considered as a simple real Lie group of real dimension 156. This has fundamental group Z/3Z, has maximal
compact Compact as used in politics may refer broadly to a pact or treaty; in more specific cases it may refer to: * Interstate compact * Blood compact, an ancient ritual of the Philippines * Compact government, a type of colonial rule utilized in British ...
subgroup the compact form (see below) of E6, and has an outer automorphism group non-cyclic of order 4 generated by complex conjugation and by the outer automorphism which already exists as a complex automorphism. As well as the complex Lie group of type E6, there are five real forms of the Lie algebra, and correspondingly five real forms of the group with trivial center (all of which have an algebraic double cover, and three of which have further non-algebraic covers, giving further real forms), all of real dimension 78, as follows: * The compact form (which is usually the one meant if no other information is given), which has fundamental group Z/3Z and outer automorphism group Z/2Z. * The split form, EI (or E6(6)), which has maximal compact subgroup Sp(4)/(±1), fundamental group of order 2 and outer automorphism group of order 2. * The quasi-split form EII (or E6(2)), which has maximal compact subgroup SU(2) × SU(6)/(center), fundamental group cyclic of order 6 and outer automorphism group of order 2. * EIII (or E6(-14)), which has maximal compact subgroup SO(2) × Spin(10)/(center), fundamental group Z and trivial outer automorphism group. * EIV (or E6(-26)), which has maximal compact subgroup F4, trivial fundamental group cyclic and outer automorphism group of order 2. The EIV form of E6 is the group of collineations (line-preserving transformations) of the
octonionic projective plane In mathematics, the Cayley plane (or octonionic projective plane) P2(O) is a projective plane over the octonions.Baez (2002). The Cayley plane was discovered in 1933 by Ruth Moufang, and is named after Arthur Cayley for his 1845 paper describin ...
OP2. It is also the group of determinant-preserving linear transformations of the exceptional
Jordan algebra In abstract algebra, a Jordan algebra is a nonassociative algebra over a field whose multiplication satisfies the following axioms: # xy = yx (commutative law) # (xy)(xx) = x(y(xx)) (). The product of two elements ''x'' and ''y'' in a Jordan alg ...
. The exceptional Jordan algebra is 27-dimensional, which explains why the compact real form of E6 has a 27-dimensional complex representation. The compact real form of E6 is the
isometry group In mathematics, the isometry group of a metric space is the set of all bijective isometries (i.e. bijective, distance-preserving maps) from the metric space onto itself, with the function composition as group operation. Its identity element is the ...
of a 32-dimensional Riemannian manifold known as the 'bioctonionic projective plane'; similar constructions for E7 and E8 are known as the
Rosenfeld projective plane In mathematics, the Freudenthal magic square (or Freudenthal–Tits magic square) is a construction relating several Lie algebras (and their associated Lie groups). It is named after Hans Freudenthal and Jacques Tits, who developed the idea indep ...
s, and are part of the
Freudenthal magic square In mathematics, the Freudenthal magic square (or Freudenthal–Tits magic square) is a construction relating several Lie algebras (and their associated Lie groups). It is named after Hans Freudenthal and Jacques Tits, who developed the idea i ...
.


E6 as an algebraic group

By means of a
Chevalley basis In mathematics, a Chevalley basis for a simple complex Lie algebra is a basis constructed by Claude Chevalley with the property that all structure constants are integers. Chevalley used these bases to construct analogues of Lie groups over finite f ...
for the Lie algebra, one can define E6 as a linear algebraic group over the integers and, consequently, over any commutative ring and in particular over any field: this defines the so-called split (sometimes also known as "untwisted") adjoint form of E6. Over an algebraically closed field, this and its triple cover are the only forms; however, over other fields, there are often many other forms, or "twists" of E6, which are classified in the general framework of
Galois cohomology In mathematics, Galois cohomology is the study of the group cohomology of Galois modules, that is, the application of homological algebra to modules for Galois groups. A Galois group ''G'' associated to a field extension ''L''/''K'' acts in a natur ...
(over a
perfect field In algebra, a field ''k'' is perfect if any one of the following equivalent conditions holds: * Every irreducible polynomial over ''k'' has distinct roots. * Every irreducible polynomial over ''k'' is separable. * Every finite extension of ''k' ...
''k'') by the set ''H''1(''k'', Aut(E6)) which, because the Dynkin diagram of E6 (see below) has automorphism group Z/2Z, maps to ''H''1(''k'', Z/2Z) = Hom (Gal(''k''), Z/2Z) with kernel ''H''1(''k'', E6,ad). Over the field of real numbers, the real component of the identity of these algebraically twisted forms of E6 coincide with the three real Lie groups mentioned above, but with a subtlety concerning the fundamental group: all adjoint forms of E6 have fundamental group Z/3Z in the sense of algebraic geometry, with Galois action as on the third roots of unity; this means that they admit exactly one triple cover (which may be trivial on the real points); the further non-compact real Lie group forms of E6 are therefore not algebraic and admit no faithful finite-dimensional representations. The compact real form of E6 as well as the noncompact forms EI=E6(6) and EIV=E6(-26) are said to be ''inner'' or of type 1E6 meaning that their class lies in ''H''1(''k'', E6,ad) or that complex conjugation induces the trivial automorphism on the Dynkin diagram, whereas the other two real forms are said to be ''outer'' or of type 2E6. Over finite fields, the
Lang–Steinberg theorem In algebraic geometry, Lang's theorem, introduced by Serge Lang, states: if ''G'' is a connected smooth algebraic group over a finite field \mathbf_q, then, writing \sigma: G \to G, \, x \mapsto x^q for the Frobenius, the morphism of varieties :G ...
implies that ''H''1(''k'', E6) = 0, meaning that E6 has exactly one twisted form, known as 2E6: see below.


Automorphisms of an Albert Algebra

Similar to how the algebraic group G2 is the automorphism group of the
octonion In mathematics, the octonions are a normed division algebra over the real numbers, a kind of hypercomplex number system. The octonions are usually represented by the capital letter O, using boldface or blackboard bold \mathbb O. Octonions hav ...
s and the algebraic group F4 is the automorphism group of an Albert algebra, an exceptional
Jordan algebra In abstract algebra, a Jordan algebra is a nonassociative algebra over a field whose multiplication satisfies the following axioms: # xy = yx (commutative law) # (xy)(xx) = x(y(xx)) (). The product of two elements ''x'' and ''y'' in a Jordan alg ...
, the algebraic group E6 is the group of linear automorphisms of an Albert algebra that preserve a certain cubic form, called the "determinant".


Algebra


Dynkin diagram

The
Dynkin diagram In the Mathematics, mathematical field of Lie theory, a Dynkin diagram, named for Eugene Dynkin, is a type of Graph (discrete mathematics), graph with some edges doubled or tripled (drawn as a double or triple line). Dynkin diagrams arise in the ...
for E6 is given by , which may also be drawn as .


Roots of E6

Although they
span Span may refer to: Science, technology and engineering * Span (unit), the width of a human hand * Span (engineering), a section between two intermediate supports * Wingspan, the distance between the wingtips of a bird or aircraft * Sorbitan ester ...
a six-dimensional space, it is much more symmetrical to consider them as vectors in a six-dimensional subspace of a nine-dimensional space. Then one can take the roots to be :(1,−1,0;0,0,0;0,0,0), (−1,1,0;0,0,0;0,0,0), :(−1,0,1;0,0,0;0,0,0), (1,0,−1;0,0,0;0,0,0), :(0,1,−1;0,0,0;0,0,0), (0,−1,1;0,0,0;0,0,0), :(0,0,0;1,−1,0;0,0,0), (0,0,0;−1,1,0;0,0,0), :(0,0,0;−1,0,1;0,0,0), (0,0,0;1,0,−1;0,0,0), :(0,0,0;0,1,−1;0,0,0), (0,0,0;0,−1,1;0,0,0), :(0,0,0;0,0,0;1,−1,0), (0,0,0;0,0,0;−1,1,0), :(0,0,0;0,0,0;−1,0,1), (0,0,0;0,0,0;1,0,−1), :(0,0,0;0,0,0;0,1,−1), (0,0,0;0,0,0;0,−1,1), plus all 27 combinations of (\mathbf;\mathbf;\mathbf) where \mathbf is one of \left(\frac, -\frac, -\frac\right),\ \left( -\frac, \frac, -\frac\right),\ \left( -\frac, -\frac, \frac \right), plus all 27 combinations of (\bar;\bar;\bar) where \bar is one of \left(-\frac,\frac,\frac\right),\ \left(\frac, -\frac, \frac \right),\ \left( \frac, \frac, -\frac \right). Simple roots One possible selection for the simple roots of E6 is: :(0,0,0;0,0,0;0,1,−1) :(0,0,0;0,0,0;1,−1,0) :(0,0,0;0,1,−1;0,0,0) :(0,0,0;1,−1,0;0,0,0) :(0,1,−1;0,0,0;0,0,0) :\left(\frac,-\frac,\frac;-\frac,\frac,\frac;-\frac,\frac,\frac\right)


E6 roots derived from the roots of E8

E6 is the subset of E8 where a consistent set of three coordinates are equal (e.g. first or last). This facilitates explicit definitions of E7 and E6 as: :E''7'' = , :E''6'' = The following 72 E6 roots are derived in this manner from the split real even E8 roots. Notice the last 3 dimensions being the same as required: :


An alternative description

An alternative (6-dimensional) description of the root system, which is useful in considering E6 × SU(3) as a subgroup of E8, is the following: All 4\times\begin5\\2\end permutations of :(\pm1,\pm1,0,0,0,0) preserving the zero at the last entry, and all of the following roots with an odd number of plus signs :\left(\pm,\pm,\pm,\pm,\pm,\pm\right). Thus the 78 generators consist of the following subalgebras: : A 45-dimensional SO(10) subalgebra, including the above 4\times\begin5\\2\end generators plus the five Cartan generators corresponding to the first five entries. : Two 16-dimensional subalgebras that transform as a
Weyl spinor In physics, particularly in quantum field theory, the Weyl equation is a relativistic wave equation for describing massless spin-1/2 particles called Weyl fermions. The equation is named after Hermann Weyl. The Weyl fermions are one of the three p ...
of \operatorname(10) and its complex conjugate. These have a non-zero last entry. : 1 generator which is their chirality generator, and is the sixth Cartan generator. One choice of
simple root Simple or SIMPLE may refer to: *Simplicity, the state or quality of being simple Arts and entertainment * ''Simple'' (album), by Andy Yorke, 2008, and its title track * "Simple" (Florida Georgia Line song), 2018 * "Simple", a song by Johnn ...
s for E6 is given by the rows of the following matrix, indexed in the order : :\left begin 1&-1&0&0&0&0 \\ 0&1&-1&0&0&0 \\ 0&0&1&-1&0&0 \\ 0&0&0&1&1&0 \\ -\frac&-\frac&-\frac&-\frac&-\frac&\frac\\ 0&0&0&1&-1&0 \\ \end\right /math>


Weyl group

The
Weyl group In mathematics, in particular the theory of Lie algebras, the Weyl group (named after Hermann Weyl) of a root system Φ is a subgroup of the isometry group of that root system. Specifically, it is the subgroup which is generated by reflections ...
of E6 is of order 51840: it is the automorphism group of the unique
simple group SIMPLE Group Limited is a conglomeration of separately run companies that each has its core area in International Consulting. The core business areas are Legal Services, Fiduciary Activities, Banking Intermediation and Corporate Service. The d ...
of order 25920 (which can be described as any of: PSU4(2), PSΩ6(2), PSp4(3) or PSΩ5(3)).


Cartan matrix

:\left begin 2&-1&0&0&0&0\\ -1&2&-1&0&0&0\\ 0&-1&2&-1&0&-1\\ 0&0&-1&2&-1&0\\ 0&0&0&-1&2&0\\ 0&0&-1&0&0&2 \end\right /math>


Important subalgebras and representations

The Lie algebra E6 has an F4 subalgebra, which is the fixed subalgebra of an outer automorphism, and an SU(3) × SU(3) × SU(3) subalgebra. Other maximal subalgebras which have an importance in physics (see below) and can be read off the Dynkin diagram, are the algebras of SO(10) × U(1) and SU(6) × SU(2). In addition to the 78-dimensional adjoint representation, there are two dual 27-dimensional "vector" representations. The characters of finite dimensional representations of the real and complex Lie algebras and Lie groups are all given by the
Weyl character formula In mathematics, the Weyl character formula in representation theory describes the characters of irreducible representations of compact Lie groups in terms of their highest weights. It was proved by . There is a closely related formula for the ch ...
. The dimensions of the smallest irreducible representations are : :1, 27 (twice), 78, 351 (four times), 650, 1728 (twice), 2430, 2925, 3003 (twice), 5824 (twice), 7371 (twice), 7722 (twice), 17550 (twice), 19305 (four times), 34398 (twice), 34749, 43758, 46332 (twice), 51975 (twice), 54054 (twice), 61425 (twice), 70070, 78975 (twice), 85293, 100386 (twice), 105600, 112320 (twice), 146432 (twice), 252252 (twice), 314496 (twice), 359424 (four times), 371800 (twice), 386100 (twice), 393822 (twice), 412776 (twice), 442442 (twice)... The underlined terms in the sequence above are the dimensions of those irreducible representations possessed by the adjoint form of E6 (equivalently, those whose weights belong to the root lattice of E6), whereas the full sequence gives the dimensions of the irreducible representations of the simply connected form of E6. The symmetry of the Dynkin diagram of E6 explains why many dimensions occur twice, the corresponding representations being related by the non-trivial outer automorphism; however, there are sometimes even more representations than this, such as four of dimension 351, two of which are fundamental and two of which are not. The
fundamental representation In representation theory of Lie groups and Lie algebras, a fundamental representation is an irreducible representation, irreducible finite-dimensional representation of a semisimple Lie algebra, semisimple Lie group or Lie algebra whose highest weig ...
s have dimensions 27, 351, 2925, 351, 27 and 78 (corresponding to the six nodes in the
Dynkin diagram In the Mathematics, mathematical field of Lie theory, a Dynkin diagram, named for Eugene Dynkin, is a type of Graph (discrete mathematics), graph with some edges doubled or tripled (drawn as a double or triple line). Dynkin diagrams arise in the ...
in the order chosen for the
Cartan matrix In mathematics, the term Cartan matrix has three meanings. All of these are named after the French mathematician Élie Cartan. Amusingly, the Cartan matrices in the context of Lie algebras were first investigated by Wilhelm Killing, whereas the Ki ...
above, i.e., the nodes are read in the five-node chain first, with the last node being connected to the middle one).


E6 polytope

The E6 polytope is the convex hull of the roots of E6. It therefore exists in 6 dimensions; its symmetry group contains the
Coxeter group In mathematics, a Coxeter group, named after H. S. M. Coxeter, is an abstract group that admits a formal description in terms of reflections (or kaleidoscopic mirrors). Indeed, the finite Coxeter groups are precisely the finite Euclidean refle ...
for E6 as an index 2 subgroup.


Chevalley and Steinberg groups of type E6 and 2E6

The groups of type ''E''6 over arbitrary fields (in particular finite fields) were introduced by . The points over a
finite field In mathematics, a finite field or Galois field (so-named in honor of Évariste Galois) is a field that contains a finite number of elements. As with any field, a finite field is a set on which the operations of multiplication, addition, subtr ...
with ''q'' elements of the (split) algebraic group E6 (see above), whether of the adjoint (centerless) or simply connected form (its algebraic universal cover), give a finite
Chevalley group In mathematics, specifically in group theory, the phrase ''group of Lie type'' usually refers to finite groups that are closely related to the group of rational points of a reductive linear algebraic group with values in a finite field. The phra ...
. This is closely connected to the group written E6(''q''), however there is ambiguity in this notation, which can stand for several things: * the finite group consisting of the points over F''q'' of the simply connected form of E6 (for clarity, this can be written E6,sc(''q'') or more rarely \tilde E_6(q) and is known as the "universal" Chevalley group of type E6 over F''q''), * (rarely) the finite group consisting of the points over F''q'' of the adjoint form of E6 (for clarity, this can be written E6,ad(''q''), and is known as the "adjoint" Chevalley group of type E6 over F''q''), or * the finite group which is the image of the natural map from the former to the latter: this is what will be denoted by E6(''q'') in the following, as is most common in texts dealing with finite groups. From the finite group perspective, the relation between these three groups, which is quite analogous to that between SL(''n,q''), PGL(''n,q'') and PSL(''n,q''), can be summarized as follows: E6(''q'') is simple for any ''q'', E6,sc(''q'') is its
Schur cover In mathematical group theory, the Schur multiplier or Schur multiplicator is the second homology group H_2(G, \Z) of a group ''G''. It was introduced by in his work on projective representations. Examples and properties The Schur multiplier \oper ...
, and E6,ad(''q'') lies in its automorphism group; furthermore, when ''q''−1 is not divisible by 3, all three coincide, and otherwise (when ''q'' is congruent to 1 mod 3), the Schur multiplier of E6(''q'') is 3 and E6(''q'') is of index 3 in E6,ad(''q''), which explains why E6,sc(''q'') and E6,ad(''q'') are often written as 3·E6(''q'') and E6(''q'')·3. From the algebraic group perspective, it is less common for E6(''q'') to refer to the finite simple group, because the latter is not in a natural way the set of points of an algebraic group over F''q'' unlike E6,sc(''q'') and E6,ad(''q''). Beyond this "split" (or "untwisted") form of E6, there is also one other form of E6 over the finite field F''q'', known as 2E6, which is obtained by twisting by the non-trivial automorphism of the Dynkin diagram of E6. Concretely, 2E6(''q''), which is known as a Steinberg group, can be seen as the subgroup of E6(''q''2) fixed by the composition of the non-trivial diagram automorphism and the non-trivial field automorphism of F''q''2. Twisting does not change the fact that the algebraic fundamental group of 2E6,ad is Z/3Z, but it does change those ''q'' for which the covering of 2E6,ad by 2E6,sc is non-trivial on the F''q''-points. Precisely: 2E6,sc(''q'') is a covering of 2E6(''q''), and 2E6,ad(''q'') lies in its automorphism group; when ''q''+1 is not divisible by 3, all three coincide, and otherwise (when ''q'' is congruent to 2 mod 3), the degree of 2E6,sc(''q'') over 2E6(''q'') is 3 and 2E6(''q'') is of index 3 in 2E6,ad(''q''), which explains why 2E6,sc(''q'') and 2E6,ad(''q'') are often written as 3·2E6(''q'') and 2E6(''q'')·3. Two notational issues should be raised concerning the groups 2E6(''q''). One is that this is sometimes written 2E6(''q''2), a notation which has the advantage of transposing more easily to the Suzuki and Ree groups, but the disadvantage of deviating from the notation for the F''q''-points of an algebraic group. Another is that whereas 2E6,sc(''q'') and 2E6,ad(''q'') are the F''q''-points of an algebraic group, the group in question also depends on ''q'' (e.g., the points over F''q''2 of the same group are the untwisted E6,sc(''q''2) and E6,ad(''q''2)). The groups E6(''q'') and 2E6(''q'') are simple for any ''q'', and constitute two of the infinite families in the
classification of finite simple groups In mathematics, the classification of the finite simple groups is a result of group theory stating that every finite simple group is either cyclic, or alternating, or it belongs to a broad infinite class called the groups of Lie type, or else i ...
. Their order is given by the following formula : :, E_6 (q), = \fracq^(q^-1)(q^9-1)(q^8-1)(q^6-1)(q^5-1)(q^2-1) :, ^2\!E_6 (q), = \fracq^(q^-1)(q^9+1)(q^8-1)(q^6-1)(q^5+1)(q^2-1) . The order of E6,sc(''q'') or E6,ad(''q'') (both are equal) can be obtained by removing the dividing factor gcd(3,''q''−1) from the first formula , and the order of 2E6,sc(''q'') or 2E6,ad(''q'') (both are equal) can be obtained by removing the dividing factor gcd(3,''q''+1) from the second . The Schur multiplier of E6(''q'') is always gcd(3,''q''−1) (i.e., E6,sc(''q'') is its Schur cover). The Schur multiplier of 2E6(''q'') is gcd(3,''q''+1) (i.e., 2E6,sc(''q'') is its Schur cover) outside of the exceptional case ''q''=2 where it is 22·3 (i.e., there is an additional 22-fold cover). The outer automorphism group of E6(''q'') is the product of the diagonal automorphism group Z/gcd(3,''q''−1)Z (given by the action of E6,ad(''q'')), the group Z/2Z of diagram automorphisms, and the group of field automorphisms (i.e., cyclic of order ''f'' if ''q''=''pf'' where ''p'' is prime). The outer automorphism group of 2E6(''q'') is the product of the diagonal automorphism group Z/gcd(3,''q''+1)Z (given by the action of 2E6,ad(''q'')) and the group of field automorphisms (i.e., cyclic of order ''f'' if ''q''=''p''''f'' where ''p'' is prime).


Importance in physics

supergravity In theoretical physics, supergravity (supergravity theory; SUGRA for short) is a modern field theory that combines the principles of supersymmetry and general relativity; this is in contrast to non-gravitational supersymmetric theories such as ...
in five dimensions, which is a
dimensional reduction Dimensional reduction is the limit of a compactified theory where the size of the compact dimension goes to zero. In physics, a theory in ''D'' spacetime dimensions can be redefined in a lower number of dimensions ''d'', by taking all the fields ...
from dimensional supergravity, admits an bosonic global symmetry and an bosonic
local symmetry In physics, a symmetry of a physical system is a physical or mathematical feature of the system (observed or intrinsic) that is preserved or remains unchanged under some transformation. A family of particular transformations may be ''continuo ...
. The fermions are in representations of , the gauge fields are in a representation of , and the scalars are in a representation of both (Gravitons are singlets with respect to both). Physical states are in representations of the coset . In grand unification theories, appears as a possible gauge group which, after its breaking, gives rise to
gauge group In physics, a gauge theory is a type of field theory in which the Lagrangian (and hence the dynamics of the system itself) does not change (is invariant) under local transformations according to certain smooth families of operations (Lie group ...
of the standard model. One way of achieving this is through breaking to . The adjoint representation breaks, as explained above, into an adjoint , spinor and as well as a singlet of the subalgebra. Including the charge we have :78 \rightarrow 45_0 \oplus 16_ \oplus \overline_3 + 1_0. Where the subscript denotes the charge. Likewise, the fundamental representation and its conjugate break into a scalar , a vector and a spinor, either or : :27 \rightarrow 1_4 \oplus 10_ \oplus 16_1, :\bar \rightarrow 1_ \oplus 10_2 \oplus \overline_. Thus, one can get the Standard Model's elementary fermions and Higgs boson.


See also

*
En (Lie algebra) In mathematics, especially in Lie theory, E''n'' is the Kac–Moody algebra whose Dynkin diagram is a bifurcating graph with three branches of length 1, 2 and ''k'', with ''k'' = ''n'' − 4. In some older books and papers, ''E''2 and ''E''4 a ...
*
ADE classification In mathematics, the ADE classification (originally ''A-D-E'' classifications) is a situation where certain kinds of objects are in correspondence with simply laced Dynkin diagrams. The question of giving a common origin to these classifications, r ...
*
Freudenthal magic square In mathematics, the Freudenthal magic square (or Freudenthal–Tits magic square) is a construction relating several Lie algebras (and their associated Lie groups). It is named after Hans Freudenthal and Jacques Tits, who developed the idea i ...


References

*. * Online HTML version a

* Online scanned version a

* * * {{DEFAULTSORT:E6 (Mathematics) Algebraic groups Lie groups Exceptional Lie algebras