Pure multiparticle quantum states are called absolutely maximally entangled if all reduced states obtained by tracing out at least half of the particles are maximally mixed. We provide a method to characterize these states for a general multiparticle system. With that, we prove that a sevenqubit state whose three-body marginals are all maximally mixed, or equivalently, a pure ((7, 1, 4))2 quantum error correcting code, does not exist. Furthermore, we obtain an upper limit on the possible number of maximally mixed three-body marginals and identify the state saturating the bound. This solves the seven-particle problem as the last open case concerning maximally entangled states of qubits.Introduction.-Multiparticle entanglement is central for the understanding of the possible quantum advantages in metrology or information processing. When investigating multiparticle entanglement as a resource, the question arises which quantum states are most entangled. For a pure multiparticle quantum state maximal entanglement is present across a bipartition if the smaller of the two corresponding reduced systems is maximally mixed. It is then a natural question to ask whether or not there exist quantum states for any number of parties n, such that all of its reductions to n/2 parties are maximally mixed [1,2]. If this is the case, maximal entanglement is present across all bipartitions and, accordingly, these states are also known as absolutely maximally entangled (AME) states [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18]. These states have been shown to be a resource for open-destination and parallel teleportation [10], for threshold quantum secret sharing schemes [12], and are a type of quantum error correcting codes [3].If the local dimension is chosen large enough, AME states always exist [12]. For qubits, however, the situation is only partially resolved. The three-qubit Greenberger-Horne-Zeilinger (GHZ) state is an AME state since all the single-qubit reduced states are maximally mixed. For four qubits it was shown that AME states do not exist [2] and best approximations of AME states (where not all reduced states are maximally mixed) have been presented [8]. Five-and six-qubit AME states are known [3,5,7]. These can be represented as graph states and correspond to additive or stabilizer codes used in quantum error correction [3,19]. For more than eight qubits, AME states do not exist [3,[20][21][22].Despite many attempts, the case of seven qubits remained unresolved. Numerical results give some evidence for the absence of an AME state [5][6][7]. By exhaustive search, it was shown that such a state could not have the form of a stabilizer state [19]. Nevertheless, some approximation has been presented by making many but not all three-body marginals maximally mixed [9,23].As shortly mentioned, AME states are a type of pure quantum error correcting codes (QECC), having the max-
