Published for SISSA by Springer Received: April 7, 2015 Accepted: July 19, 2015

Published: August 10, 2015

Superalgebras, constraints and partition functions

Martin Cederwalla and Jakob Palmkvistb

aDepartment of Fundamental Physics, Chalmers University of Technology,

SE-412 96 Gteborg, Sweden

bMitchell Institute for Fundamental Physics and Astronomy, Texas A&M University,

College Station, TX 77843, U.S.A.

E-mail: [email protected], mailto:[email protected]

Web End [email protected]

Abstract: We consider Borcherds superalgebras obtained from semisimple nite-dimensional Lie algebras by adding an odd null root to the simple roots. The additional Serre relations can be expressed in a covariant way. The spectrum of generators at positive levels are associated to partition functions for a certain set of constrained bosonic variables, the constraints on which are complementary to the Serre relations in the symmetric product. We give some examples, focusing on superalgebras related to pure spinors, exceptional geometry and tensor hierarchies, of how construction of the content of the algebra at arbitrary levels is simplied.

Keywords: BRST Quantization, BRST Symmetry

ArXiv ePrint: 1503.06215

JHEP08(2015)036

Open Access, c

The Authors.

Article funded by SCOAP3. doi:http://dx.doi.org/10.1007/JHEP08(2015)036

Web End =10.1007/JHEP08(2015)036

Contents

1 Introduction 1

2 The superalgebras 3

3 Partition functions 5

4 BRST operator and coalgebra 7

5 A proof from denominator formulas 11

6 Why is the method not applicable to Lie algebras? 14

7 Examples 167.1 The extreme cases 167.2 D = 8 pure spinors and null vectors 167.3 D = 10 pure spinors and supergravity forms 177.4 Superalgebras and Lie algebras 19

1 Introduction

It is often useful in physics to describe a spectrum of states that appear at various integer levels by means of an associated partition function, especially if the spectrum is innite. If the states at each level transform in a representation of a Lie algebra, the spectrum of representations may also be obtained from an extended (possibly innite-dimensional) algebra by a level decomposition. In the present paper we will relate these two approaches to each other, and also to a third important tool in physics: the BRST treatment of reducible constraints.

Our main example is the spectrum of dynamical forms in D-dimensional maximal supergravity, which transform in representations of the U-duality group1 En, where n =

11D. Remarkably, these representations form a Lie superalgebra, which can be extended to an innite-dimensional Borcherds superalgebra [13]. Decomposing it with respect to the En subalgebra gives back the spectrum of dynamical forms at the positive levels, and also precisely the additional non-dynamical forms allowed by supersymmetry, rst determined for D = 10 in refs. [46]. The consistency with supersymmetry was shown in refs. [710] using a superspace formulation, generalising bosonic forms to superforms with arbitrary high degrees. However, already in the restriction to the bosonic sector, the wedge product

1Throughout the paper, we use the notation En for the split real form, and also for the corresponding Lie algebra. All arguments are however equally valid for the complex Lie algebras.

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in the di erential algebra, with even and odd forms, naturally gives rise to a superalgebra structure. Up to an arbitrary level p the representations can be also obtained from a level decomposition of the Kac-Moody algebra En+p [3, 1012]. This generalises results for

E11, which as a special case contains the form spectrum up to p = D [1315]. However, E11 is not enough to accommodate forms with higher degrees, and a rendition of all the representations coming from the Borcherds superalgebra would require a consideration of the innite-rank algebra E.

With a few exceptions, the level decomposition of the Borcherds superalgebra furthermore agrees with the tensor hierarchy of form potentials, eld strengths and gauge parameters that arises in the embedding tensor approach to gauged supergravity [1619]. The tensor hierarchy can be continued to innity, but misses some of the representations coming from the Borcherds superalgebra. Perfect agreement is instead given by a tensor hierarchy algebra, where the embedding tensor is interpreted as an element at level minus one [20]. Using this algebra all the Bianchi identities and gauge transformations for the gauged theory can be derived in a simple way [10, 21]. This demonstrates the e ciency of organising representations into a level decomposition of a Lie (super)algebra.

Yet another context where the same innite sequence of representations appears, and where it cannot be truncated, is exceptional geometry. The exceptional (generalised) diffeomorphisms have innite reducibility, and the sequence arises as the tower of ghosts for ghosts, describing this reducibility [22]. The connection to partition functions of constrained objects, of which pure spinors [23] is one example, was conjectured already in ref. [22], and used there to correctly regularise the innite sums arising when counting the degrees of freedom. The same representations occur for tensor elds in exceptional geometry [24], and in the tensor hierarchies considered in [2528]. The somewhat heuristic approach of ref. [22] provided one of the motivations for the present investigation, which puts the correspondence between the algebra and the constrained objects on a rmer footing.

For 3 D 8 the U-duality algebra En is extended to the innite-dimensional Borcherds superalgebra B by adding an odd null root 0 to the simple roots of En. This is the special case that we focus on in this paper, with En generalised to any semisimple nite-dimensional Lie algebra g. The inner products of 0 with the simple roots of g are assumed to be such that the Serre relations of the Borcherds superalgebra are at most quadratic in the odd Chevalley generators e0, f0 corresponding to 0. Denoting the representation at level p by Rp, the Serre relations quadratic in e0 (say) thus belong to a representation of g contained in the symmetric tensor product of R1 with itself, with R2 as its complement.2 It generates an ideal of the free Lie superalgebra generated by R1, and at each level p 2, the representation Rp is the complement that is left when this ideal is factored out. A recursive study of the ideal thus gives all information about the representations Rp at any level p. In this paper, we will show that the representations Rp alternatively, and often more directly, can be determined from the partition function for a bosonic object in R1,

subject to the constraint 2|R2 = 0. As our main result, we will show that this partition function is the inverse of the partition function for the universal enveloping algebra of B+,

the subalgebra of B at positive levels.

2With the complement of a representation R in another R we mean the quotient R R.

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The paper is organised as follows. In section 2 we describe in more detail the Lie superalgebras that we consider, and how they are constructed from the Chevalley generators and the Serre relations. In section 3 we introduce the partition functions that we use in section 4 to state our results and give them an interpretation in terms of a BRST operator. The argument of section 4 corresponds roughly to the heuristic argument of ref. [22]. We then prove the result in section 5 using the denominator formula for Borcherds superalgebras. Section 6 addresses the question why the method is not applicable to Lie algebras (extensions by an additional even real root). In section 7 we present and discuss some examples.

2 The superalgebras

Let g be a semisimple nite-dimensional Lie algebra of rank r with simple roots i (i =

1, . . . , r). We recall that they form a basis of a euclidean space, and from their mutual inner products we get the Cartan matrix aij of g by

aij = ( j, i) = 2( j, i)( i, i) , (2.1)

where i = 2 i/( i, i) is the coroot of i.

The construction of a Lie algebra from a basis of simple roots can be generalised to inner product spaces which are not necessarily euclidean, and even from Lie algebras to Lie superalgebras. Semisimple nite-dimensional Lie algebras are then generalised to Kac-Moody (super)algebras, which in turn are generalised further to Borcherds (super)algebras. Thus Borcherds superalgebras is a very general concept, but in this paper we only consider the special cases described below, motivated by their simplicity and by their appearance in the examples that we will study in section 7. We refer the reader to refs. [2932] for more general denitions and other details about Borcherds and Kac-Moody (super)algebras.

The Borcherds superalgebras that we consider are innite-dimensional superextensions of semisimple nite-dimensional Lie algebras, obtained by adding an odd null root to the simple roots. Let B be such an extension of g, with simple roots I (I = 0, 1, . . . , r). Thus

0 is odd and null, ( 0, 0) = 0, whereas i = i are even and real, ( i, i) > 0. The Cartan matrix BIJ of B is obtained from aij by adding an extra column

Bi0 = ( 0, i) = 2( 0, i)( i, i) (2.2)

and an extra row B0I = ( I, 0), including the diagonal entry B00 = ( 0, 0) = 0. The additional o -diagonal entries Bi0 are required to be non-positive integers, like Bij = aij for i 6= j. We assume furthermore that BIJ is non-degenerate, and for each i = 1, . . . , r, either B0i = 0 or B0i = 1.

Adding an extra column and row to the Cartan matrix of g corresponds to adding an extra node to the Dynkin diagram of g, connected with |Bi0| lines to node i. Following ref. [29] we indicate that 0 is both null and odd by painting the corresponding node grey

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(which means that it looks like ), and let the other nodes, representing real even roots, be white. For example, the Dynkin diagram

4

0 1 2 3

corresponds to the Cartan matrix

BIJ =

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0 1 0 0 0 1 2 1 0 0

0 1 2 1 1 0 0 1 2 0 0 0 1 0 2

. (2.3)

We will come back to this algebra, among other examples, in section 7.

To each simple root I of B we associate Chevalley generators eI, fI and hI, and B is then dened as the Lie superalgebra generated by these elements (of which e0 and f0 are odd and the others even) modulo the Chevalley relations

[hI, eJ] = BIJeJ , [hI, fJ] = BIJfJ , [eI, fJ} = IJhJ , (2.4)

and the Serre relations

(ad eI)1BIJ (eJ) = (ad fI)1BIJ (fJ) = 0 (2.5)

for I 6= J. For I = 0 the Serre relations (2.5) can equivalently be replaced by

{e0, e0} = {f0, f0} = 0 , (2.6)

since, by the Jacobi identity,

1

2 [{e0, e0}, eJ] = {e0, [e0, eJ]},

1

2 [{f0, f0}, fJ] = {f0, [f0, fJ]} , (2.7)

which gives

[{e0, [e0, eJ]}, fJ] = {e0, e0}, [{f0, [f0, fJ]}, eJ] = {f0, f0} (2.8)

if BJ0 = 1. Thus in this case the ideal generated by (2.5) is contained in the ideal generated by (2.6), and conversely. If BJ0 = 0, there is already a redundance in (2.5) because of the antisymmetry of the bracket, so replacing (2.5) by (2.6) in this case simply amounts to removing one of two equivalent relations in (2.5).

For any integer p, let Bp be the subspace of B spanned by all root vectors corresponding to roots = p 0 + , where is a linear combination of the real simple roots i = i, and, if p = 0, by the Cartan elements hI. Since B is the direct sum of all these subspaces, and [Bp, Bq} Bp+q, this decomposition is a Z-grading of B, leading to a

4

level decomposition of its adjoint representation under the subalgebra g B0, with Bp consisting of a (maybe reducible) representation3 of g at level p. We will throughout the paper denote this representation Rp.

Let B+ and B be the subalgebras of B spanned by elements at positive and negative levels, respectively, and let ~B be the free Lie superalgebra generated by B1. The Serre relations (2.6) generate an ideal of ~B which is the direct sum of two subalgebras D, where

D ~B (and is the maximal such ideal). The Borcherds superalgebra B is then obtained by factoring out this ideal from ~B, and in particular B+ is obtained by factoring out D+ from ~B+, the free Lie superalgebra generated by B1. The ideal D+ of ~B is generated by the element {e0, e0} at level two, which is set to zero in one of the Serre relations (2.6). However, considered as an ideal of ~B+ only, it is generated by all elements at level two in D+, which are not only {e0, e0} but also those obtained from {e0, e0} by successively acting with g. These elements form a representation R2, which is the complement of R2 in 2R1 (the symmetrised tensor product of R1 with itself) with a lowest weight vector {e0, e0}. It then follows from the Chevalley relations that the Dynkin labels of the lowest weight of R2 are given by i = 2Bi0.

Using a basis EM of B1 (so that the index M corresponds to the representation R1), we can summarize the above construction of B+ by saying that it is the Lie superalgebra generated by the odd elements EM modulo the covariant Serre relations

{EM, EN}|R2 = 0 . (2.9)

Recursive use of these relations (and of course of the Jacobi identity) gives complete information about the representation Rp at arbitrarily high levels p. In section 4 we will describe how this information can be e ciently encoded into partition functions, which will be discussed next.

3 Partition functions

The purpose of this section is to introduce and dene notation for the partition functions we use to state our results.

The partition functions we will consider count the number of bosonic and fermionic objects occurring with some Z-weight, or level, and some additional quantum numbers. In an unrened partition function, only counting the number of states per level, the presence of some set of N linearly independent objects with weight p corresponds to a term pNtp,

where = 1 for bosons and = 1 for fermions. This means we are really considering partition functions twisted by fermion number, which of course has the advantage that the partition function for a fermionic variable, or creation operator,

ZF (t) = 1 t , (3.1)

and that of a bosonic one,

ZB(t) = (1 t)1 , (3.2)

are each others inverses.

3Following the physics terminology, we use the term representation also for the module of the representation, i.e., the vector space it acts on.

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More rened partition functions may be dened if additional quantum numbers are available. In a typical case, a variable or operator will transform in some representation R of a Lie algebra g. A rened partition function encodes completely the representations of all states, and is a formal power series in a variable t (corresponding to the grading) with coe cients in the unit ring of g-representations (under tensor product).

The basic examples are the rened partition functions for fermionic and bosonic creation operators in R:

Z FR (t) =

e1++k , (3.6)

where the sum is over sets of distinct (in the sense above) weights in R. Thus,

~FR(t) ~(Z FR (t)) =

which of course is just the product of the characters for the individual fermions making up the representation R. It then follows that

~BR(t) ~(Z BR(t)) = (~FR(t))1 =

Y R(1 te)1 . (3.8)

The character picture will be used for a proof of our result in section 5.

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|R|

Mp=0 (t)ppR ,

Z BR(t) =

Mp=0tp pR . (3.3)

Here, we use and for antisymmetric and and symmetric products, respectively, and |R| denotes the dimension of a representation R. These two functions are also the inverses of each other, when multiplication is taken as the tensor product with the trivial representation as the identity. This can be seen explicitly at any order in t by observing that the tensor product (pR) (qR) generically contains exactly the plethysms described by the two di erent hook Young tableaux of sl(|R|) obtained by gluing together the column and the row describing the two factors. One thus has

Z FR (t) Z BR(t) = 1 , (3.4)

It is then reasonable to use the formal notation

Z FR (t) = (1 t)R ,

Z BR(t) = (1 t)R . (3.5)

A fermion in R can be seen as a boson in R and vice versa. It is important to understand the notation of eq. (3.5) as the shorthand it is, with eq. (3.3) being its dening expression.

All considerations of the rened partition functions may also be performed using characters, since they provide a ring homomorphism. Writing the character of the representation R as ~(R) =

P R e, where R is the set of weights for R, counting weights with multiplicities m > 1 as m distinct weights, we have

~(kR) =

X

{1,...,k}

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|R|

Xk=1 (t)k

e1++k =

Y R(1 te) , (3.7)

The examples above used for setting the notation are valid only for unconstrained variables (creation operators). We will use such rened partition functions to encode the spectrum of generators in the Borcherds superalgebras described in section 2.

Before going into the construction of partition functions for algebras and for constrained objects, we will consider two other situations, which will be of use later. The rst is when a fermionic or bosonic variable is maximally constrained, so that any bilinear vanishes. Then the partition function just contains a linear term:

Z (t) = 1 + Rt (3.9)

(where again = 1 for bosons and fermions, respectively). The second situation concerns variables of indenite statistics, meaning that both symmetric and antisymmetric products of R occur (but with odd levels still labeled as bosonic or fermionic by a sign ). Then the partition function is

Z (t) =

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Mp=0(t)ppR = (1 Rt)1 . (3.10)

The observation that the partition functions (3.9) and (3.10) are each others inverses for opposite choices of is one, somewhat trivial, example of our main result which will be demonstrated in the following sections. In this case the algebra is freely generated by the representation at level one.

4 BRST operator and coalgebra

Consider the subalgebra B+ of elements at positive levels of a Z-graded Borcherds superalgebra B, as dened in section 2. In the generic case, the algebra will be innite-dimensional, and contain elements at arbitrarily high levels. However, as we saw in section 2, all this information is contained in the covariant Serre relations

{EM, EN}|R

2 = 0 , (4.1) where R2 is the complement to R2 in 2R1. At level two, we thus have generators

EMN = {EM, EN} in R2.

As announced in section 1, we will argue that all information about the representations occurring at each level can be obtained in an alternative way, which often provides a more direct answer, namely by considering a bosonic object M in R1, subject to the constraint

2|R2 = 0 . (4.2)

Notice that the object M has opposite statistics (bosonic) to EM (thinking of odd elements in a superalgebra as fermionic), and that its constraint is in the symmetric representation complementary to that of the Serre relations. The precise relation we will establish, and which is the main result of this paper, is:

The partition function of the universal enveloping algebra U(B+) is the inverse of the partition function for the constrained object , i.e.,

ZU(B+)(t) Z (t) = 1 . (4.3)

7

Since the partition functions used are completely rened, in the sense of section 3, this provides complete information of the generators at each level of the Borcherds superalgebra

B. The rened partition function for , if is seen as a complex object, can be seen as encoding holomorphic functions of .

The way we will argue for this equality in the present section is by identifying the action of the BRST operator for the (conjugated) constraint with the operation d of the coalgebra B+. This will not constitute a full proof (which would require a consideration of cohomology of B+), but provides a clear picture of the correspondence. The proof, based on the denominator formula for Borcherds superalgebras, is given in section 5.

Let us rst consider the coalgebra, repeat some well known facts and set the notation. For simplicity, we do this for the case of an ordinary Lie algebra; the generalisation to graded brackets and Lie superalgebras is trivial. The coalgebra of a Lie algebra a is dened on the vector space a dual to a. It is equipped with a map d : a a a, which is dual to the Lie bracket [, ] in the sense that for any A, B a and X a,

h dX | A B i = h X | [A, B] i , (4.4)

where h|i is the canonical scalar product, naturally extended to tensor products. If Ea and Ea are dual bases for a and a, and [Ea, Eb] = fabcEc, eq. (4.4) reads

dEa = fbcaEb Ec . (4.5)

The action of d is naturally extended to tensor products of elements by dening it to act as a derivation. The Jacobi identity is equivalent to the nilpotency, d2 = 0, of d. The above can be generalised to a Lie superalgebra with the appropriate graded interpretation of wedge products, brackets and derivations.

We now specialise on the Borcherds superalgebras at hand. The rst two levels of the coalgebra B+ read

dEM = 0 ,

dEMN = EM EN| R2 . (4.6)

The Serre relations manifest themselves as the absence of generators in R2 at level two. What is the procedure for the continued construction? Of course, knowledge of the algebra directly provides the full information of the coalgebra. But it is also possible to use eq. (4.6) as a starting point for recursively deriving the content at each level as well as the coproduct. One must then allow for the most general representation for E(3) and the most general form of dE(3) E(2) E(1) consistent with d2 = 0. A general Ansatz consists of letting EMNP belong to a representation R3 R1 R2 and writing

dEMNP = EM ENP | R3 . (4.7)

The nilpotency of d then determines the allowed representation R3. For example, a totally symmetric representation is always excluded from R3, since it will vanish due to the Jacobi identity. This procedure can then be continued to all levels, where dE(p) will contain sums of terms E(q) E(pq) (wedge here denoting graded antisymmetrisation).

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The unique result of the procedure can be understood by the following argument, which also provides a conceptual idea behind the result stated in eq. (4.3). Everything starts from, and is generated from, the basic set of generators EM in the g-representation B1. Since they are odd elements of a superalgebra, they are normally thought of as fermionic. It is however useful to think of EM as not carrying a denite statistics. Indeed, considering the

Serre relations (4.1), the only constraint on a bilinear in EM (including both symmetric and anti-symmetric parts) is that a certain representation R2 of the symmetric bilinear vanishes. The identication of the symmetric part in the complement R2 with new generators EMN is in this sense optional. Without this identication, and corresponding identications at higher levels, the universal algebra U(B+) can be constructed from the tensor algebra of B1 by factoring out the ideal generated by EM EN|R2 . This provides a way of constructing an arbitrary element, not in the algebra B+, but in its universal enveloping algebra U(B+), in terms of powers of EM only. The partition function of the universal enveloping algebra will be that of an object EM in R1 of indenite statistics (although the elements at odd levels are labelled as fermionic in the partition function, see section 3), modulo the ideal generated by the Serre relations. Seen this way, our main result can be phrased in the following way:

The partition function for a bosonic object ( ) in R1 subject to a bilinear constraint in R2 is the inverse of the partition function for an object (the set of level-one generators in B) with indenite statistics, where odd powers are labeled as fermionic, subject to a bilinear constraint in R2.

This statement provides an interpolating generalisation for partitions of constrained objects of the ones made for unconstrained and maximally constrained ones in section 3. However, unlike in those limiting cases, the statistics here may not be switched, which we will comment on in section 6.

Now, consider an object

in R1, with the constraint

2| R2 = 0. The constraint can be treated using a BRST formalism. For convenience, we change our notation and use cM instead of

M. The rst term in the BRST operator Q is Q(2) = bMNcMcN, where bMN in R2 is the ghost for the constraint.4 However, if the constraint happens to be reducible, there will be higher order ghosts compensating for the reducibility. Such reducibility will be captured by the introduction of a new bc pair, and a term Q(3) = bMNP cMNcP in

Q. The representation of bMNP is everything that is allowed by Q2 = 0. This should be continued, as long as the reducibility continues, i.e., as long as further such terms can be added. A generic term will be of the form b(p+q)c(p)c(q), where the ghosts are alternatingly fermionic and bosonic. From this trilinear form of the BRST operator it is immediately clear that its action on the c ghosts denes the coalgebra of a Lie superalgebra. An innite reducibility5 corresponds to an innite-dimensional algebra.

4It would maybe be more conventional to use a notation where c is the ghost multiplying the constraint, and b its conjugate. Here, however, it turns out that all terms will be of the form bcc, which corresponds to the standard form of algebra ghost terms in a BRST operator.

5The concept of reducibility is not absolute, but may depend on the degree of covariance. Here, we always consider reducibility as expressed in terms of representations of the nite-dimensional Lie algebra g (but should of course not be confused with the possible reducibility of the representations themselves).

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We now recognise the exact parallel between on one hand the construction of the coal-gebra, given the Serre relations (and nothing more), and on the other hand the construction of the BRST operator. The di erence is only a matter of notation. The cogenerators E(p)

correspond to the ghosts c(p), and the graded wedge products are automatically implied by the wrong statistics of the ghosts. The operator d is the adjoint action (graded commutator) of Q, so that dE(p) [Q, c(p)}.

This means that if we calculate the partition function of as a constrained object, which is obtained as the conjugate of the tensor product of the partition functions of all the ghosts,

Z (t) =

it will coincide with the inverse partition function of the universal enveloping algebra U(B+), which by denition is

ZU(B+)(t) =

using the shorthand notation of (3.5). The inverse simply appears since the correspondence E(p) c(p) changes statistics.

The above argument does not provide a strict proof of eq. (4.3). The missing step is the proof that the BRST operator Q bcc correctly encodes the degrees of freedom of the constrained object, or, equivalently, that no other unwanted cohomology arises. We refrain from doing this, but we will present a di erent proof in section 5.

Neither of the two above methods of nding the spectrum of generators has an advantage over the other, since we just demonstrated that they contain exactly the same calculational steps. However, knowing that the partition function is that of a constrained object can often provide an alternative, more direct, and simpler way of obtaining the answer. Provided that we know from the constraint which representation Sp appear at any power p, the partition function is directly constructed as

Z (t) =

Expanding this partition function in a product form6 gives information about all the ghost representations, and thus about the generators of the algebra. This calculation becomes especially simple in cases where S1 = R1 is an irreducible representation of some Lie algebra with highest weight , and S2 = R2 = 2R1 R2 is the representation with highest weight 2 . Then Sp will have highest weight p . Indeed, the class of Borcherds superalgebras we consider all have this property, as will be shown in section 5. We will give some examples of such situations in section 7, among which are pure spinors and their

6This is the method used by Berkovits and Nekrasov in ref. [23] to obtain detailed information on the partition functions of pure spinors.

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Op=1(1 tp)(1)pRp , (4.8)

Op=1(1 tp)(1)p+1Rp , (4.9)

Mp=0

Sptp . (4.10)

associated superalgebras. Although the representations Rp are complicated, they can be calculated from the more readily available representations Sp by inserting eqs. (4.9)(4.10) into (4.3), which gives

Op=1(1 tp)(1)pRp =

The explicit solution of this relation for the spectrum of the Borcherds superalgebra, i.e., the representations Rp in terms of the known Sp, can be obtained by recursion, or by a

Mbius inversion. By comparing the left and right hand sides for the rst few powers of t we get

R1 = S1 ,

R2 = 2R1 S2 ,

R3 = (R1 R2) 3R1 S3 ,

R4 = (R1 R3) 2R2

(2R1 R2) 4R1 S4 . (4.12)

We will display some explicit examples of varying complexity in section 7.

5 A proof from denominator formulas

This section will provide a proof of our main result (4.3), using the denominator formula for Borcherds superalgebras [3134]. It is known for general Borcherds superalgebras but here we only need a simplied version given below, valid for the special cases of Borcherds superalgebras under consideration.

Let be the root system of B, and for any integer p, let p be the subset of consisting of all roots = p 0 + , where is a linear combination of the real simple roots i = i. Thus 0 is the root system of the subalgebra g, and Bp is the direct sum of all root spaces B such that p, and, if p = 0, the Cartan subalgebra.

We will show that the eq. (4.11), with the lowest weights of the representations Sq given by the Dynkin labels

i = q( 0, i) = q 2( 0, i)

( i, i) = qBi0 , (5.1)

is equivalent to the denominator formula for B [3134], which reads

Q +(0)(1 e )mult

Q +(1)(1 + e )mult =

XwW

Mq=0

Sqtq . (4.11)

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Xq=0(1)|w|(1)qew(q 0) . (5.2)

Here +(0) and +(1) consist of all even and odd positive roots, respectively, is the Weyl vector of B, dened by

(, I) = ( I, I)

2 , (5.3)

11

and the Weyl group W of B is generated by all fundamental Weyl reections

ri : 7 ( i, ) = 2 ( i, )

( i, i) . (5.4)

The length |w| of an element w in W is the minimal number of fundamental Weyl reections (not necessarily distinct), which, applied after each other, give w.

Note that the representations Sp are given by the Dynkin labels i of their lowest weights, since we consider positive levels of B. However, we are going to relate the denominator formula (5.2) for B to the character formula for g, which is usually expressed in terms of the highest weight of a representation. Therefore it is convenient to replace eq. (4.11) by the equivalent equation obtained by conjugating all representations,

Op=1(1 tp)(1)p Rp =

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Mq=0Sqtq , (5.5)

where now the highest weight of Sq is i = qBi0. What we will actually show is that this eq. (5.5) is equivalent to the denominator formula (5.2).7

Let ~

0 be the element in the weight space of B such that (~

0, i) = 0 for all i = 1, . . . , r,

and the componenent of ~

0 corresponding to 0 in the basis of simple roots is equal to one (this element exists uniquely since both BIJ and Bij = aij are non-degenerate). Thus ~

0 0 is an element in the weight space of g (considered as a subspace of the weight space of B). More generally, a root p can be written = p~

0 + , where = p~

0 is

an element in the weight space of g. We then get

Y p(1 e )mult =

YRp(1 ep~ 0e)mult

=

|Rp|

Xk=0 (1)k

Xe(1++k)(e~ 0)kp , (5.6)

where the second sum goes over all sets of k distinct weights 1, . . . , k among the weights of Rp, counting (as in section 3) a weight with multiplicity m as m distinct weights. This sum can be obtained from the character for kRp by inverting each term, which corresponds to conjugating the representation Rp. Thus

Y p(1 e )mult =

| Rp|

Xk=0(1)k~(k Rp)skp (5.7)

where we have set s = e~ 0. In the same way,

Xk=0~(k Rp)skp (5.8)

7Instead of considering positive levels in B and conjugating the representations we could of course also have considered negative levels and only highest weights from the beginning.

Y p(1 + e )mult =

| Rp|

12

and we know that the inverse of this is

Y p(1 + e )mult =

Xk=0(1)k~(k Rp)skp . (5.9)

Here the character of k Rp is given by the sum of all terms e(1++k), where 1, . . . , k are weights of Rp, this time not necessarily distinct. Following the notation in section 3, we write this as

Y p(1 e )mult = ~ (1 sp) Rp

, (5.10)

JHEP08(2015)036

and the left hand side of eq. (5.2) becomes

Q +(0)(1 e )mult

Q +(1)(1 + e )mult =

Yp=1~

1 (1)psp

(1)p Rp

, (5.11)

+0

(1 e )mult

where +0 consists of the positive roots of g.

We now turn to the right hand side of the denominator formula,

XwW

Xq=0(1)|w|(1)qew(q 0). (5.12)

Here W is the Weyl group of B, but since it is generated by the fundamental Weyl reections corresponding to the real roots only, it coincides with the Weyl group of g. In order to use the character formula for g we also need to replace the Weyl vector of B with the one of g, but this requires some more consideration. The Weyl vector = B of B is dened as the element in the weight space of B satisfying

(B, I) = ( I, I)

2 , (5.13)

whereas the Weyl vector g of g only has to satisfy

(g, i) = ( i, i)

2 , (5.14)

but on the other hand it must have a zero component corresponding to 0 in the basis of simple roots. Thus the Weyl vectors of B and g are di erent (in general), but since their di erence B g is orthogonal to the real roots, (B g, i) = 0, it is invariant under the Weyl group, w(B g) = B g. We then get

w(B q 0) B = w g + (B g) q 0

g (B g)

= w(g q 0) g + w(B g) (B g)= w(g q 0) g (5.15)

13

and we can indeed replace = B by g in eq. (5.12). To simplify the notation, we will henceforth write = g. Furthermore, since also ~

0 is orthogonal to the real roots, we have

w( q 0) = w q~

0 + q(~

0 0)

= w + q(~

0 0)

q~

0 (5.16)

and then

XwW

Xq=0 (1)|w|(1)qew(q 0) =

XwW

Xq=0 (1)|w|(1)qew(+q(~ 0 0))q~ 0

=

XwW

JHEP08(2015)036

Xq=0(1)|w|(1)qew(+q(~ 0 0))sq . (5.17)

Equating eqs. (5.11) and (5.17) we get

Yp=1~

1 (1)psp

(1)p Rp

=

PwW (1)|w|ew(+q(~ 0 0))

Q +0(1 e )mult (1)qsq , (5.18)

where we recognise

PwW (1)|w|ew(+q(~ 0 0))

Q +0(1 e )mult

(5.19)

as the character of the representation of g with highest weight q(~

0 0) given by the

Dynkin labels

q(~

0 0), i

= q( 0, i) = q 2( 0, i)

( i, i) = qBi0 = i , (5.20)

and thus

Yp=1~

1 (1)psp

(1)p Rp

Xq=0~( Sq)(1)qsq. (5.21)

Finally, substituting s by t we arrive at the equation

Yp=1~ (1 tp)(1)p Rp

=

=

Xq=0~( Sq)tq , (5.22)

which is the character version of (and thus equivalent to) eq. (5.5).

6 Why is the method not applicable to Lie algebras?

Let us replace 0 with an even simple root 0, which is real, ( 0, 0) > 0, but otherwise satises the same inner product relations as 0, thus ( 0, i) = ( 0, i). The Chevalley-Serre relations (2.4)(2.5), with all superbrackets being ordinary antisymmetric brackets, and with the Cartan matrix BIJ replaced by

AIJ = ( J, I) = 2( J, I)

( I, I) , (6.1)

14

denes a Kac-Moody algebra A . This corresponds to adding an ordinary (white) node to the Dynkin diagram of g instead of a grey one, and in analogy with B the adjoint representation of A dcomposes into g-representations Rp. The representation R1 is the same as in the case of B, but R2 is now a subrepresentation of 2R1, the anti-symmetric tensor product of R1 with itself. Its complement is the direct sum of representations with lowest weights given by the Dynkin labels i = Aij + 2Ai0 for all j such that A0j 6= 0.

One might imagine that the statement (4.3) would apply both for the Lie superalgebra B and the ordinary Lie algebra A . This would potentially have made it possible to extract precise information about the generators to all levels for classes of innite-dimensional (e.g. hyperbolic) Kac-Moody algebras. It turns out, however, that statistics can not just be changed. This is because the constrained object then would be fermionic. Having bilinear (bosonic) constraints on fermionic variables is generically a strange situation, and leads to complicated structures, as we will explain.

Consider a fermionic in a representation R1 of g with a bilinear constraint in R2 of A , thus complementary to some Serre relations in the anti-symmetric product 2R1. An

algebraic solution to the constraints (in the sense that one considers a power series in modulo the constraint) will result in a polynomial partition function, where the highest term is of order lower than or equal to |R1|. Its factorisation in ghost contributions is however innite. This is because the ghosts, like the original variables, are fermionic, and so are the ghosts for reducibility. Instead of removing fermionic degrees of freedom, the ghosts add more fermions, corresponding to the removal of bosonic degrees of freedom (the constraint).

This somewhat pathological behaviour is in itself not an obstruction for the existence of a relation like eq. (4.3) one might well imagine that a properly regularised sum with strictly positive terms yields a negative value (although it is a valid argument against an analogous construction when the Lie algebra is nite-dimensional). What makes things go wrong is the fact that a bilinear constraint on fermions inherently has some reducibility coming from the fermionic property of the variables. Whatever the bosonic constraint is, it is e.g. obvious that raising it to a su cient power will give zero due to saturation of fermions. This has no counterpart in the bosonic situation, and will introduce ghosts in a BRST treatment which do not enter Q in the bcc form. Therefore, a correct BRST treatment can not be given an interpretation in terms of a Lie algebra. We have observed in a number of examples that a naive treatment of the Serre relations as complementary to a constraint gives agreement in the spectrum to a number of low levels, before the saturation of fermions becomes relevant. Whether there is a systematic way of consistently dening partitions for fermions that circumvents this and correctly encodes the Serre relations (and thereby the spectrum of the Lie algebra) is an open question. In any case it seems reasonable that the occurrence, in the superalgebra case, of the highest weights which are simply multiples of the dening one, has particularly simple structure without counterpart in the Lie algebra situation.

Turning to the actual proof of the main result for the Lie superalgebra B in section 5, it is easy to identify the step where the argument fails for Lie algebras. The Weyl group of the extended algebra A is not identical to that of g, and the proof in its present form fails, although the denominator formula is known.

15

JHEP08(2015)036

7 Examples

We will give a number of examples that illustrate the connection between the constrained bosonic variable and the spectrum of generators in the superalgebra.

We use the notation B+ for the subalgebra of generators at positive levels, although in some examples (the freely generated algebras) it is not a subalgebra of a Borcherds superalgebra of the precise type described in section 2.

7.1 The extreme cases

Consider rst a freely generated superalgebra. Then the Serre relations are empty, and elements of the universal enveloping algebra U(B+) are given by arbitrary tensor products of R1. Thus ZU(B+) is given by eq. (3.10) with = 1, which is the inverse of the formal partition for a maximally constrained boson in R1. This is one extreme case of the correspondence (in which the statistics can be interchanged). It appears if the additional simple root is not a null root, but has negative length squared.

The other extremal case is when the Serre relations ll the whole symmetric product 2R1, so that {EM, EN} = 0. The superalgebra is then nite-dimensional with EM forming a basis for B+ = B1. The partition function ZU(B+) is the partition function of fermions in R1, which is the inverse of the partition function for an unconstrained boson. Also in this other special case the statistics can be interchanged.

Intermediary cases only work as a correspondence of the form (4.3) between superalgebras and constrained bosons, and these provide less trivial illustrations of our result.

7.2 D = 8 pure spinors and null vectors

Pure spinors provide well known and extensively studied examples of constrained bosons. They lead to minimal spinor orbits under Spin groups, due to the fact that only a single irreducible representation appears in a spinor bilinear (the one whose highest weight is twice the one of a spinor), and by induction there is only one representation for each positive power of the spinor. We will give two examples of pure spinors, in this subsection and the next.

Let us rst consider a pure spinor in D = 8, where the constraint is particularly simple, = 0. This is via triality equivalent to a null vector. The Dynkin diagram of the corresponding superalgebra is given below.

The analysis can equally well be performed for null vectors in general dimension D. The rened partition function for reads

Z (t) =

16

JHEP08(2015)036

Mp=0(p0 . . . 0)tp , (7.1)

where Dynkin labels of highest weights have been used for the representations, and (10 . . . 0) denotes the vector representation. The representation (p0 . . . 0) consists of symmetric and traceless multi-vectors. Its dimension is readily calculated to be

p + D 1 p

p

+ D 3 p 2

=

(2p + D 2)(p + D 3)!

(D 2)!p! , (7.2) so the unrened partition function (just counting dimensions) is

Z (t) =

Xp=0(2p + D 2)(p + D 3)!(D 2)!p! tp =1 + t(1 t)D1 =1 t2(1 t)D . (7.3)

The same result is obtained by constructing the partition function from the ghosts. An (unconstrained) variable contributes to Z with (1 t)(10...0), and the fermionic ghost for the constraint with (1 t2)(00...0). The constraint is irreducible, so there are no higher ghosts. The correspondence (4.3) tells us that the spectrum of the universal enveloping algebra U(B+) is given by

ZU(B+)(t) = (Z (t))1 = (1 t)(10...0) (1 t2)(00...0) , (7.4)

corresponding to a fermionic generator in (10 . . . 0) at level one and a bosonic one in (00 . . . 0) at level two. The superalgebra B, which here comes with a 5-grading, is nite-dimensional, B osp(D|2). A nite-dimensional superalgebra is obtained when the reducibility of the constraint on is nite.

7.3 D = 10 pure spinors and supergravity forms

Let us turn to the more interesting cases of innite-dimensional superalgebras, which are related to the spectrum of forms in supergravity, and thereby also to the tensor hierarchies in gauged supergravity (see the discussion in section 1).

Pure spinors in D = 10 are relevant for the o -shell supereld formulation of D = 10 super-Yang-Mills theory (see e.g. refs. [3538]). The partition function is described in some detail in ref. [23], and is given by

Z (t) =

JHEP08(2015)036

Mp=0 (0000k)tp

=

(00000) (10000)t2 (00001)t3

(00010)t5 (10000)t6 (00000)t8

(1 t)(00001) , (7.5)

or, just counting dimensions,

Z (t) = 1 10t2 + 16t3 16t5 + 10t6 t8

(1 t)16 =

(1 + t)(1 + 4t + t2)

(1 t)11 . (7.6)

The power 11 of the pole at t = 1 signals 11 degrees of freedom in a pure spinor. The Dynkin diagram of the corresponding superalgebra is given below.

17

This algebra is innite-dimensional. Still, we know that the spectrum is determined by ZU(B+) = Z 1. The generators at each level in B+ are obtained by rewriting the partition function (7.5) on product form, which reects the ghost structure corresponding to the innite reducibility:

(Z (t))1 =

Op=1(1 tp)(1)p+1Rp . (7.7)

This can be done recursively as in eq. (4.12), with the following result for the rst few representations:

R1 = (00001) = 16, R2 = (10000) = 10, R3 = (00010) = 16,R4 = (01000) = 45, R5 = (10010) = 144,R6 = (11000) (00020) (10000) = 320 126 10, . . . (7.8)

For the dimensionalities |Rp|, an explicit Mbius inversion formula can be found [23].

The case of D = 10 pure spinors is relevant to exceptional eld theory with U-duality group E5 Spin(5, 5). Generally, the innite ghost tower in exceptional eld theory with U-duality group En (n 8) is identical to the innite spectrum of superforms in D-dimensional maximal supergravity (D = 11 n), as was shown for low levels in ref. [22]. Our results here, combined with those in refs. [810], establish this correspondence for all levels. Here we have shown that the ghosts for a constrained object give rise to a Borcherds superalgebra by the action of the BRST operator, and in refs. [810] it was shown that the forms in the supergravity theory similarly give rise to a Borcherds superalgebra by their Bianchi identities. In the extended eld theory the constraint is directly associated with the section condition, and leads to the same Borcherds superalgebras as the supersymmetry constraint on the supergravity side. Since the Borcherds superalgebras are the same, the sequences of representations are the same as well.

The (unrened) partition functions corresponding to the constraint in the exceptional eld theories were give in ref. [22]. As an example, the E6 case gives a Borcherds superalgebra dened by a belonging to a cne over the Cayley plane [39]. The partition function is

Z (t) =

JHEP08(2015)036

Mk=0 (k00000)tk

=

(000000) (000001)t2 (010000)t3 (001000)t5

(100001)t6 (000002)t7 (200000)t8 (100001)t9

(000010)t10 (010000)t12 (100000)t13 (000000)t15

(1 t)(100000) , (7.9)

and the spectrum of the Borcherds algebra is obtained recursively by rewriting Z on

product form.

With the same interpretation as gauge transformations and reducibility for generalised di eomorphisms, our earlier example with null vectors, corresponding to a nite-dimensional superalgebra, is relevant for double eld theory with T-duality group O(d, d).

18

7.4 Superalgebras and Lie algebras

A curious observation, somewhat besides the main focus of this paper, is that the last Dynkin diagram of the previous subsection has the same form as the one for E6, had the extra node been white instead of grey. Similarly, had the extra node in the superalgebra of subsection 7.2 been white, we would have had the Lie algebra for SO(10), or in the general case SO(D + 2).

Polynomials of a pure spinor, the constrained object encoding the spectrum of the Borcherds algebra in question, indeed form an innite-dimensional singleton representation of E6, which can be constructed as follows. Consider generators of E6 so(10)u(1).

The adjoint splits as 78 161 (45 1)0 161. Call the spinorial generators and . With the conventions

[Jab, ] = 14( ab ) , [Q, ] = , (7.10)

the only non-manifestly covariant non-vanishing commutator is

[ , ] = ( ab) Jab + 32 Q . (7.11)

The relative coe cient is xed by demanding the Jacobi identity on the form

[[ , [ ], ]] = 0 . (7.12)

Now, we start from an so(10)-scalar ground state |0i annihilated by , and use as creation operators, giving a Verma module of polynomials in . Let the ground state have charge q, Q|0i = q|0i. We want to adjust the value of q so that ( a ) generates an E6-invariant ideal. This happens if ( a )|0i = 0. A short calculation leads to

( a )|0i = 32(2q + 1)( a ) |0i +

32(2q + 1) 27 2

19

JHEP08(2015)036

1 4( ij a ij ) |0i

=

( a ) |0i . (7.13)

If q = 4, this vanishes, and the ideal may be factored out without breaking E6. This shows how the space of (holomorphic) polynomials in a pure spinor forms an innite-dimensional lowest-weight representation of E6. It may be called a singleton representation, since it only consists of a leading trajectory of Spin(10) representations with highest weights (0000k) at each U(1) charge 4 + k. The lowering operator can be identied with the gauge invariant (in the sense that it respects the ideal) derivative with respect to a pure spinor constructed in ref. [40].

In the same way a singleton representation of SO(D + 2) [41] is obtained by starting from a ground state of a certain charge. We use the conventions

[Jab, c] = 2 [a b]c , [Q, a] = a ,

[a, b] = Jab abQ . (7.14)

The ideal generated by 2 can be factored out for vacuum charge q = D2

singleton representation.

At least in these particular cases, the constrained object, i.e., the pure spinor or null vector, has a direct relation both to a Borcherds superalgebra and to a (nite-dimensional) Lie algebra. Both algebras are obtained by adding a node, grey and white, respectively, in the same position to the Dynkin diagram of a semi-simple Lie algebra, but the rle of the pure spinor is quite di erent in the two cases. The phenomenon is certainly more general, but is in its present form limited to situations where the s commute, and thus are the only generators at positive level in the Lie algebra. It holds e.g. for the constrained objects occurring in relation to tensor hierarchies of En R+ with n 6, and the Borcherds superalgebras obtained by extending En by an odd null root. The corresponding Lie algebra, having polynomials of as a singleton representation is En+1 En R+, which

is a 3-grading.

Acknowledgments

MC would like to thank Sergio Benvenuti and Amihay Hanany for pointing out parallels with the work of refs. [42, 43], where similar partition functions occur e.g. in relation to moduli spaces of instantons. JP would like to thank Thomas Edlund, Alex Feingold, Sebastian Guttenberg, Axel Kleinschmidt and Arne Meurman for discussions. The work of JP is supported by NSF grant PHY-1214344.

Open Access. This article is distributed under the terms of the Creative Commons Attribution License (CC-BY 4.0), which permits any use, distribution and reproduction in any medium, provided the original author(s) and source are credited.

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