Towards studying the structural differences between the pion and its radial excitation

Xiang Gao; Nikhil Karthik; Swagato Mukherjee; Peter Petreczky; Sergey Syritsyn; Yong Zhao

doi:10.1103/PhysRevD.103.094510

Towards studying the structural differences between the pion and its radial excitation

Xiang Gao
, Nikhil Karthik
, Swagato Mukherjee
, Peter Petreczky
, Sergey Syritsyn
, Yong Zhao

Physics and Astronomy

Tsinghua University
United States Department of Energy
College of William and Mary
Thomas Jefferson National Accelerator Facility

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

We present an exploratory lattice QCD investigation of the differences between the valence quark structure of the pion and its radial excitation π(1300) in a fixed finite volume using the leading-twist factorization approach. We present evidences that the first pion excitation in our lattice computation is a single particle state that is likely to be the finite volume realization of π(1300). An analysis with reasonable priors result in better estimates of the excited state PDF and the moments, wherein we find evidence that the radial excitation of pion correlates with an almost two-fold increase in the momentum fraction of valence quarks. This proof-of-principle work establishes the viability of future lattice computations incorporating larger operator basis that can resolve the structural changes accompanying hadronic excitation.

Original language	English
Article number	094510
Journal	Physical Review D
Volume	103
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevD.103.094510
State	Published - May 17 2021

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abstract = "We present an exploratory lattice QCD investigation of the differences between the valence quark structure of the pion and its radial excitation π(1300) in a fixed finite volume using the leading-twist factorization approach. We present evidences that the first pion excitation in our lattice computation is a single particle state that is likely to be the finite volume realization of π(1300). An analysis with reasonable priors result in better estimates of the excited state PDF and the moments, wherein we find evidence that the radial excitation of pion correlates with an almost two-fold increase in the momentum fraction of valence quarks. This proof-of-principle work establishes the viability of future lattice computations incorporating larger operator basis that can resolve the structural changes accompanying hadronic excitation.",

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AU - Gao, Xiang

AU - Karthik, Nikhil

AU - Mukherjee, Swagato

AU - Petreczky, Peter

AU - Syritsyn, Sergey

AU - Zhao, Yong

PY - 2021/5/17

Y1 - 2021/5/17

N2 - We present an exploratory lattice QCD investigation of the differences between the valence quark structure of the pion and its radial excitation π(1300) in a fixed finite volume using the leading-twist factorization approach. We present evidences that the first pion excitation in our lattice computation is a single particle state that is likely to be the finite volume realization of π(1300). An analysis with reasonable priors result in better estimates of the excited state PDF and the moments, wherein we find evidence that the radial excitation of pion correlates with an almost two-fold increase in the momentum fraction of valence quarks. This proof-of-principle work establishes the viability of future lattice computations incorporating larger operator basis that can resolve the structural changes accompanying hadronic excitation.

AB - We present an exploratory lattice QCD investigation of the differences between the valence quark structure of the pion and its radial excitation π(1300) in a fixed finite volume using the leading-twist factorization approach. We present evidences that the first pion excitation in our lattice computation is a single particle state that is likely to be the finite volume realization of π(1300). An analysis with reasonable priors result in better estimates of the excited state PDF and the moments, wherein we find evidence that the radial excitation of pion correlates with an almost two-fold increase in the momentum fraction of valence quarks. This proof-of-principle work establishes the viability of future lattice computations incorporating larger operator basis that can resolve the structural changes accompanying hadronic excitation.

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JO - Physical Review D

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ER -

Towards studying the structural differences between the pion and its radial excitation

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