Paraparticles intrinsically exhibit Hardy-space breakdown
Abstract
The memory kernel of an open quantum system obeys Kramers--Kronig (KK) relations if and only if its Laplace transform is analytic in the upper half-plane -- a property known as Hardy-space analyticity. Here we show that non-unitary exchange statistics, the defining property of paraparticles, intrinsically breaks Hardy-space analyticity. The metric $η$ that guarantees a real closed-system spectrum for these particles necessarily differs from the physical Born inner product ($\|η- I\|_F / \|I\|_F ...
Description / Details
The memory kernel of an open quantum system obeys Kramers--Kronig (KK) relations if and only if its Laplace transform is analytic in the upper half-plane -- a property known as Hardy-space analyticity. Here we show that non-unitary exchange statistics, the defining property of paraparticles, intrinsically breaks Hardy-space analyticity. The metric that guarantees a real closed-system spectrum for these particles necessarily differs from the physical Born inner product () -- a mathematical consequence of the R-matrix's non-unitarity, not a parameter choice. This metric is a "shadow metric": Schur's lemma forces it to commute with every bilinear observable, making the distortion physically invisible in the closed system. But when the paraparticle is coupled to a bath, any coupling operator that lies outside the symmetry algebra -- that is, any interaction that sees the internal flavour structure -- exposes the distortion. The memory kernel then develops upper-half-plane poles at coupling , breaking standard dispersion relations before the closed-system spectrum complexifies. Fermions and bosons, whose exchange is unitary ( as an analytic fact of the canonical anticommutation algebra), are immune at any coupling, because there is no distortion to expose. The violation is intrinsic: it distinguishes non-unitary exchange statistics from ordinary particle statistics at the level of the memory kernel's analytic structure.
Source: arXiv:2607.11867v1 - http://arxiv.org/abs/2607.11867v1 PDF: https://arxiv.org/pdf/2607.11867v1 Original Link: http://arxiv.org/abs/2607.11867v1
Please sign in to join the discussion.
No comments yet. Be the first to share your thoughts!
Jul 14, 2026
Quantum Computing
Quantum Physics
0