On Energy-Momentum Transfer of Quantum Fields

Herdegen, Andrzej

doi:10.1007/s11005-014-0710-5

Cited by 4 publications

(15 citation statements)

References 14 publications

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“…By Lemma 14 in Appendix A of [11] we have |φpsq| ď const pλ`|s|q´2. Thus φ is absolutely integrable.…”

Section: 5mentioning

confidence: 94%

“…with δ P p0, 1q, δ ă n´p3{2q. This function satisfies the assumptions of Lemma 14 in [11] with γ " δ, so hp xq is integrable. Consider relation (14) with the replacements B Ñ C " p1´λ 2 ∆q 2 B , k Ñ n´δ , f ps, lq Ñ l bps, lq .…”

Section: Asymptotic Fieldsmentioning

confidence: 96%

“…Our main tool in this section will be a partial result of Proposition 9 in [11]. We rewrite the necessary result with the use of the norms }.}…”

Section: Spectral Propertiesmentioning

confidence: 99%

“…Fields are assumed to satisfy some weak condition on the decay of their commutators in spacelike directions, but need not be local. We believe that the limits of strict locality may be to narrow in a constrained theory like QED; we refer the reader to our earlier papers [10], [11] for more comments on nonlocality and our specific choice of commutator laws. The smearing applied here to the fields still cuts the infrared-singular degrees of freedom, but no further assumptions beside relativistic positivity of energy spectrum in the Hilbert space are needed.…”

Section: Introductionmentioning

confidence: 99%

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Massless Asymptotic Fields and Haag–Ruelle Theory

Duch

Herdegen

2014

Lett Math Phys

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Abstract.We revisit the problem of the existence of asymptotic massless boson fields in quantum field theory. The well-known construction of such fields by Buchholz (Commun. Math. Phys. 52:147-173, 1977; Commun. Math. Phys. 85:49-71, 1982) is based on locality and the existence of vacuum vector, at least in regions spacelike to spacelike cones. Our analysis does not depend on these assumptions and supplies a more general framework for fields only very weakly decaying in spacelike directions. In this setting, the existence of appropriate null asymptotes of fields is linked with their spectral properties in the neighborhood of the lightcone. The main technical tool is one of the results of a recent analysis by one of us (Herdegen in Lett. Math. Phys. 104:1263-1280. doi:10.1007/ s11005-014-0710-5, 2014), which allows application of the null asymptotic limit separately to creation/annihilation parts of a wide class of nonlocal fields. In vacuum representation the scheme allows application of the methods of the Haag-Ruelle theory closely analogous to those of the massive case. In local case this Haag-Ruelle procedure may be combined with the Buchholz method, which leads to significant simplification.Mathematics Subject Classification. 81T05, 81U99.

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“…By Lemma 14 in Appendix A of [11] we have |φpsq| ď const pλ`|s|q´2. Thus φ is absolutely integrable.…”

Section: 5mentioning

confidence: 94%

Section: Asymptotic Fieldsmentioning

confidence: 96%

“…Our main tool in this section will be a partial result of Proposition 9 in [11]. We rewrite the necessary result with the use of the norms }.}…”

Section: Spectral Propertiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Massless Asymptotic Fields and Haag–Ruelle Theory

Duch

Herdegen

2014

Lett Math Phys

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“…its division into pure-point, absolutely continuous and singular continuous parts) remains to a large extent unexplored. Some steps to close this gap, with physical applications in mind, have been taken in [16,25,38]. Finally, we note that partial derivatives of a function f ∈ C ∞ (∆), where ∆ is an open subset of Γ, are independent of a chosen parametrization of the torus, an observation which is implicitly used e.g.…”

Section: A2 Groups Of Unitariesmentioning

confidence: 99%

Lieb–Robinson Bounds, Arveson Spectrum and Haag–Ruelle Scattering Theory for Gapped Quantum Spin Systems

Bachmann

Dybalski

Naaijkens

2015

Ann. Henri Poincaré

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We consider translation invariant gapped quantum spin systems satisfying the Lieb-Robinson bound and containing single-particle states in a ground state representation. Following the HaagRuelle approach from relativistic quantum field theory, we construct states describing collisions of several particles, and define the corresponding S-matrix. We also obtain some general restrictions on the shape of the energy-momentum spectrum. For the purpose of our analysis we adapt the concepts of almost local observables and energy-momentum transfer (or Arveson spectrum) from relativistic QFT to the lattice setting. The Lieb-Robinson bound, which is the crucial substitute of strict locality from relativistic QFT, underlies all our constructions. Our results hold, in particular, in the Ising model in strong transverse magnetic fields.

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The Bisognano–Wichmann Property for Asymptotically Complete Massless QFT

Dybalski

Morinelli

2020

Commun. Math. Phys.

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We prove the Bisognano–Wichmann property for asymptotically complete Haag–Kastler theories of massless particles. These particles should either be scalar or appear as a direct sum of two opposite integer helicities, thus, e.g., photons are covered. The argument relies on a modularity condition formulated recently by one of us (VM) and on the Buchholz’ scattering theory of massless particles.

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On Energy-Momentum Transfer of Quantum Fields

Cited by 4 publications

References 14 publications

Massless Asymptotic Fields and Haag–Ruelle Theory

Massless Asymptotic Fields and Haag–Ruelle Theory

Lieb–Robinson Bounds, Arveson Spectrum and Haag–Ruelle Scattering Theory for Gapped Quantum Spin Systems

The Bisognano–Wichmann Property for Asymptotically Complete Massless QFT

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