TY - JOUR
T1 - Inertia of decomposable entanglement witnesses
AU - Chen, Lin
AU - Jiang, Bohan
N1 - Publisher Copyright:
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PY - 2025/1/1
Y1 - 2025/1/1
N2 - We investigate the inertia (i.e., the array of numbers of negative, zero and positive eigenvalues of an Hermitian matrix) of decomposable entanglement witnesses (EWs). We show that the 2 × n and two-qutrit decomposable EWs have the same inertias as those of non-positive-transpose (NPT) EWs. We also show that if an m × n EW W has inertia (p, ap, mn − p − ap) with p≥1, then for every integer b ∈ [0, ap], then we can find an EW Wb such that InWb = (p, b, mn − p − b). If W is a decomposable (resp. NPT) EW, then we can choose Wb as also a decomposable (resp. NPT) EW. We further show that the m × n decomposable EW with the maximum number of negative eigenvalues can be chosen as an NPT EW. Then we explicitly characterize the 2 × 3 EWs, and decomposable EWs PΓ + Q with positive semidefinite matrices P of rank one and Q. We also show that a 2 × 4 non-decomposable EW has no inertia (3, 2, 3). Then we show some properties of a 2 × 4 non-decomposable EW of inertia (2, 3, 3), if it exists.
AB - We investigate the inertia (i.e., the array of numbers of negative, zero and positive eigenvalues of an Hermitian matrix) of decomposable entanglement witnesses (EWs). We show that the 2 × n and two-qutrit decomposable EWs have the same inertias as those of non-positive-transpose (NPT) EWs. We also show that if an m × n EW W has inertia (p, ap, mn − p − ap) with p≥1, then for every integer b ∈ [0, ap], then we can find an EW Wb such that InWb = (p, b, mn − p − b). If W is a decomposable (resp. NPT) EW, then we can choose Wb as also a decomposable (resp. NPT) EW. We further show that the m × n decomposable EW with the maximum number of negative eigenvalues can be chosen as an NPT EW. Then we explicitly characterize the 2 × 3 EWs, and decomposable EWs PΓ + Q with positive semidefinite matrices P of rank one and Q. We also show that a 2 × 4 non-decomposable EW has no inertia (3, 2, 3). Then we show some properties of a 2 × 4 non-decomposable EW of inertia (2, 3, 3), if it exists.
KW - decomposable
KW - entanglement
KW - inertias
KW - witnesses
UR - https://www.scopus.com/pages/publications/85219585004
U2 - 10.1088/1402-4896/ad94ae
DO - 10.1088/1402-4896/ad94ae
M3 - 文章
AN - SCOPUS:85219585004
SN - 0031-8949
VL - 100
JO - Physica Scripta
JF - Physica Scripta
IS - 1
M1 - 015101
ER -