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1. Extracting scattering amplitudes for arbitrary two-particle systems with one-particle left-hand cuts via lattice QCD

Author

Raposo, André Baião, Briceño, Raúl A, Hansen, Maxwell T, and Jackura, Andrew W

Subjects
High Energy Physics - Lattice
Abstract

We derive a general formalism that relates the spectrum of two-particle systems in a finite volume to physical scattering amplitudes, taking into account the presence of any left-hand branch cuts due to single-particle exchanges. The method first relates the finite-volume spectrum to an infinite-volume short-range quantity, denoted \mathcal{M}_0, and then relates the latter to the physical scattering amplitudes via known integral equations. The derivation of both relations is performed using all-orders perturbation theory and is exact up to neglected exponentially suppressed volume dependence. The relations hold for arbitrary two-particle systems with any number of coupled channels, non-identical and non-degenerate particles, and any intrinsic spin., Comment: 41 pages, 5 figures, v1

Published
2025

2. Finite-volume quantization condition from the $N/D$ representation

Author

Dawid, Sebastian M., Jackura, Andrew W., and Szczepaniak, Adam P.

Subjects
High Energy Physics - Lattice, Nuclear Theory
Abstract

We propose a new model-independent method for determining hadronic resonances from lattice QCD. The formalism is derived from the general principles of unitarity and analyticity, as encoded in the $N/D$ representation of a partial-wave two-body amplitude. The associated quantization condition relates the finite-volume spectrum to the infinite-volume numerator, $\mathcal{N}$, used to reconstruct the scattering amplitude from dispersive relations. Unlike the original L\"uscher condition, this new formalism is valid for energies coinciding with the left-hand cuts from arbitrary one- and multi-particle exchanges., Comment: 13 pages, 2 figures

Published
2024

3. Partial-wave projection of relativistic three-body amplitudes

Author

Briceño, Raúl A., Costa, Caroline S. R., and Jackura, Andrew W.

Subjects
High Energy Physics - Phenomenology, High Energy Physics - Lattice, High Energy Physics - Theory, Nuclear Theory
Abstract

We derive the integral equations for partial-wave projected three-body scattering amplitudes, starting from the integral equations for three-body amplitudes developed for lattice QCD analyses. The results, which hold for generic three-body systems of spinless particles, build upon the recently derived partial-wave projected one-particle exchange, a primary component of the relativistic framework proven to satisfy S matrix unitarity. We derive simplified expressions for factorizable short-distance interactions, $\mathcal{K}_{3}$, in two equivalent formalisms - one symmetric under particle interchange and one asymmetric. For the asymmetric case, we offer parameterizations useful for amplitude analysis. Finally, we examine toy models for $3\pi$ systems at unphysically heavy pion masses with total isospins 0,1, and 2., Comment: 47 pages, 5 figures

Published
2024

4. Partial-wave projection of the one-particle exchange in three-body scattering amplitudes

Author

Jackura, Andrew W and Briceño, Raúl A

Subjects
Nuclear and Plasma Physics, Particle and High Energy Physics, Synchrotrons and Accelerators, Physical Sciences
Abstract

As the study of three-hadron physics from lattice QCD matures, it is necessary to develop proper analysis tools in order to reliably study a variety of phenomena, including resonance spectroscopy and nuclear structure. Reconstructing the three-particle scattering amplitude requires solving integral equations, which can be written in terms of data-constrained dynamical functions and physical on shell quantities. The driving term in these equations is the so-called one-particle exchange, which leads to a kinematic divergence for particles on mass shell. A vital component in defining three-particle amplitudes with definite parity and total angular momentum, which are used in spectroscopic studies, is to project the one-particle exchange into definite partial waves. We present a general procedure to construct exact analytic partial-wave projections of the one-particle exchange contribution for any system composed of three spinless hadrons. Our result allows one full control over the analytic structure of the projection, which we explore for some low-lying partial waves with applications to three pions. Published by the American Physical Society 2024

Published
2024

5. Partial-wave projection of the one-particle exchange in three-body scattering amplitudes

Author

Jackura, Andrew W. and Briceño, Raúl A.

Subjects
High Energy Physics - Phenomenology, High Energy Physics - Lattice, High Energy Physics - Theory, Nuclear Theory
Abstract

As the study of three-hadron physics from lattice QCD matures, it is necessary to develop proper analysis tools in order to reliably study a variety of phenomena, including resonance spectroscopy and nuclear structure. Reconstructing the three-particle scattering amplitude requires solving integral equations, which can be written in terms of data-constrained dynamical functions and physical on-shell quantities. The driving term in these equations is the so-called one-particle exchange, which leads to a kinematic divergence for particles on-mass-shell. A vital component in defining three-particle amplitudes with definite parity and total angular momentum, which are used in spectroscopic studies, is to project the one-particle exchange into definite partial waves. We present a general procedure to construct exact analytic partial wave projections of the one-particle exchange contribution for any system composed of three spinless hadrons. Our result allows one full control over the analytic structure of the projection, which we explore for some low-lying partial waves with applications to three pions., Comment: 73 pages, 17 figures, 4 appendices, ancillary Mathematica notebook at https://github.com/ajackura/partial_wave_three_body_ope_notebook

Published
2023

6. Electroweak three-body decays in the presence of two- and three-body bound states

Author

Briceño, Raul A, Jackura, Andrew W, Pefkou, Dimitra A, and Romero-López, Fernando

Subjects
Nuclear and Plasma Physics, Particle and High Energy Physics, Mathematical Physics, Mathematical Sciences, Physical Sciences, Hadronic Matrix Elements and Weak Decays, Hadronic Spectroscopy, Structure and Interactions, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Quantum Physics, Nuclear & Particles Physics, Mathematical physics, Nuclear and plasma physics, Particle and high energy physics
Abstract

Abstract : Recently, formalism has been derived for studying electroweak transition amplitudes for three-body systems both in infinite and finite volumes. The formalism provides exact relations that the infinite-volume amplitudes must satisfy, as well as a relationship between physical amplitudes and finite-volume matrix elements, which can be constrained from lattice QCD calculations. This formalism poses additional challenges when compared with the analogous well-studied two-body equivalent one, including the necessary step of solving integral equations of singular functions. In this work, we provide some non-trivial analytical and numerical tests on the aforementioned formalism. In particular, we consider a case where the three-particle system can have three-body bound states as well as bound states in the two-body subsystem. For kinematics below the three-body threshold, we demonstrate that the scattering amplitudes satisfy unitarity. We also check that for these kinematics the finite-volume matrix elements are accurately described by the formalism for two-body systems up to exponentially suppressed corrections. Finally, we verify that in the case of the three-body bound state, the finite-volume matrix element is equal to the infinite-volume coupling of the bound state, up to exponentially suppressed errors.

Published
2024

7. Evolution of Efimov States

Author

Dawid, Sebastian M., Islam, Md Habib E, Briceño, Raúl A., and Jackura, Andrew W.

Subjects
Nuclear Theory, High Energy Physics - Lattice, High Energy Physics - Phenomenology, Physics - Atomic Physics
Abstract

The Efimov phenomenon manifests itself as an emergent discrete scaling symmetry in the quantum three-body problem. In the unitarity limit, it leads to an infinite tower of three-body bound states with energies forming a geometric sequence. In this work, we study the evolution of these so-called Efimov states using relativistic scattering theory. We identify them as poles of the three-particle $S$ matrix and trace their trajectories in the complex energy plane as they evolve from virtual states through bound states to resonances. We dial the scattering parameters toward the unitarity limit and observe the emergence of the universal scaling of energies and couplings -- a behavior known from the non-relativistic case. Interestingly, we find that Efimov resonances follow unusual, cyclic trajectories accumulating at the three-body threshold and then disappear at some values of the two-body scattering length. We propose a partial resolution to this "missing states" problem., Comment: 15 pages, 10 figures

Published
2023

8. Three-pion effects in $K^0-\bar{K}^0$ mixing

Author

Jackura, Andrew W., Briceńo, Raúl A., and Hansen, Maxwell T.

Subjects
High Energy Physics - Lattice
Abstract

The rate of mixing between a neutral kaon and an anti-kaon ($K^0-\bar{K}^0$) is given, in part, by a long-range matrix element, defined with two insertions of the weak Hamiltonian separated by physical, Minkowski time evolution. For physical quark masses, the kaon mass lies above the two- and three-pion thresholds and, as a result, this long-range matrix element receives contributions from intermediate on-shell $2\pi$ and $3\pi$ states. These contributions cannot easily be captured in a finite Euclidean spacetime, meaning that such matrix elements are not directly accessible via lattice QCD. In this talk, we present a strategy for combining quantities that can be extracted in numerical lattice QCD calculations in order to reproduce the physical, infinite-volume long-range amplitude for $K^0-\bar{K}^0$. The key novelty relative to published work is that we fully include the effects of three-particle states that were previously neglected. The strategy is built on existing formalism for long-range matrix elements with two-particle intermediate states, together with the relativistic-field-theory finite-volume formalism for extracting three-hadron weak decays., Comment: 10 pages, 4 figures, Contribution to the 39th International Symposium on Lattice Field theory (LATTICE2022), 8th-13th August, 2022, Bonn, Germany

Published
2022

9. Prospects for $\gamma^\star \gamma^\star \to \pi \pi$ via lattice QCD

Author

Briceño, Raúl A., Jackura, Andrew W., Rodas, Arkaitz, and Guerrero, Juan V.

Subjects
High Energy Physics - Lattice, High Energy Physics - Phenomenology, Nuclear Theory
Abstract

The $\gamma^\star \gamma^\star \to \pi \pi$ scattering amplitude plays a key role in a wide range of phenomena, including understanding the inner structure of scalar resonances as well as constraining the hadronic contributions to the anomalous magnetic moment of the muon. In this work, we explain how the infinite-volume Minkowski amplitude can be constrained from finite-volume Euclidean correlation functions. The relationship between the finite-volume Euclidean correlation functions and the desired amplitude holds up to energies where $3\pi$ states can go on shell, and is exact up to exponentially small corrections that scale like $\mathcal{O}(e^{-m_\pi L})$, where $L$ is the spatial extent of the cubic volume and $m_\pi$ is the pion mass. In order to implement this formalism and remove all power-law finite volume errors, it is necessary to first obtain $\pi \pi \to \pi\pi$, $\pi \gamma^\star \to \pi$, $\gamma^\star \to\pi\pi$, and $\pi\pi\gamma^\star \to\pi\pi$ amplitudes; all of which can be determined via lattice quantum chromodynamic calculations., Comment: 23 pages, 9 figures

Published
2022
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10. Three-body scattering and quantization conditions from $S$ matrix unitarity

Author

Jackura, Andrew W.

Subjects
High Energy Physics - Lattice, High Energy Physics - Phenomenology, Nuclear Theory
Abstract

Two methodologies have been presented in the literature which connect relativistic three-particle scattering amplitudes with lattice QCD spectra -- the ``relativistic effective field theory'' approach and the ``finite-volume unitarity'' method. While both methods have been shown to be equivalent in various works, it has not been shown how to arrive at the relativistic effective field theory results directly from $S$ matrix unitarity. In this work, we provide a simple proof of the relativistic effective field theory form of the scattering equations directly from unitarity. Motivated by the finite-volume unitarity approach, we then postulate a set of quantization conditions which relate the finite-volume energy spectra to the $K$ matrices which drive the short-distance physics in the scattering equations, obtaining all previously known results for three identical particles. This work also presents new relations which provide a new pathway to generalize the results to arbitrary systems., Comment: 34 pages, 8 figures

Published
2022

11. Snowmass white paper: Need for amplitude analysis in the discovery of new hadrons

Author

Albaladejo, Miguel, Battaglieri, Marco, Bibrzycki, Lukasz, Celentano, Andrea, Danilkin, Igor V., Dawid, Sebastian M., Doring, Michael, Fanelli, Cristiano, Fernandez-Ramirez, Cesar, Gonzalez-Solis, Sergi, Blin, Astrid N. Hiller, Jackura, Andrew W., Mathieu, Vincent, Mikhasenko, Mikhail, Mokeev, Victor I., Passemar, Emilie, Perry, Robert J., Pilloni, Alessandro, Rodas, Arkaitz, Shepherd, Matthew R., Sherrill, Nathaniel, Silva-Castro, Jorge A., Skwarnicki, Tomasz, Szczepaniak, Adam P., and Winney, Daniel

Subjects
High Energy Physics - Phenomenology, High Energy Physics - Experiment, Nuclear Theory
Abstract

We highlight the need for the development of comprehensive amplitude analysis methods to further our understanding of hadron spectroscopy. Reaction amplitudes constrained by first principles of $S$-matrix theory and by QCD phenomenology are needed to extract robust interpretations of the data from experiments and from lattice calculations., Comment: 15 pages, 9 figures. Contribution to Snowmass 2021

Published
2022

12. Two-current transition amplitudes with two-body final states

Author

Sherman, Keegan H., Ortega-Gama, Felipe G., Briceño, Raúl A., and Jackura, Andrew W.

Subjects
High Energy Physics - Lattice, High Energy Physics - Phenomenology, Nuclear Theory
Abstract

We derive the on-shell form of amplitudes containing two external currents with a single hadron in the initial state and two hadrons in the final state, denoted as $1+\mathcal{J}\to 2+\mathcal{J}$. This class of amplitude is relevant in precision tests of the Standard Model as well as for exploring the structure of excited states in the QCD spectrum. We present a model-independent description of the amplitudes where we sum to all orders in the strong interaction. From this analytic form we are able to extract transition and elastic resonance form factors consistent with previous work as well as a novel Compton-like amplitude coupling a single particle state to a resonance. The results also hold for reactions where the one-particle state is replaced with the vacuum, namely $\mathcal{J}\to 2+\mathcal{J}$ amplitudes. We also investigate constraints placed upon the formalism for the case of a conserved vector current in the form of the Ward-Takahashi identity. The formalism presented here is valid for currents of arbitrary Lorentz structure and quantum numbers with spinless hadrons where any number of two-particle intermediate channels may be open. When combined with the appropriate finite-volume framework, this work facilitates the extraction of physical observables from this class of amplitudes via lattice QCD calculations., Comment: 33 pages, 10 figures

Published
2022
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13. Novel approaches in Hadron Spectroscopy

Author

JPAC Collaboration, Albaladejo, Miguel, Bibrzycki, Lukasz, Dawid, Sebastian M., Fernandez-Ramirez, Cesar, Gonzalez-Solis, Sergi, Blin, Astrid N. Hiller, Jackura, Andrew W., Mathieu, Vincent, Mikhasenko, Mikhail, Mokeev, Victor I., Passemar, Emilie, Pilloni, Alessandro, Rodas, Arkaitz, Silva-Castro, Jorge A., Smith, Wyatt A., Szczepaniak, Adam P., and Winney, Daniel

Subjects
High Energy Physics - Phenomenology, High Energy Physics - Experiment, Nuclear Theory
Abstract

The last two decades have witnessed the discovery of a myriad of new and unexpected hadrons. The future holds more surprises for us, thanks to new-generation experiments. Understanding the signals and determining the properties of the states requires a parallel theoretical effort. To make full use of available and forthcoming data, a careful amplitude modeling is required, together with a sound treatment of the statistical uncertainties, and a systematic survey of the model dependencies. We review the contributions made by the Joint Physics Analysis Center to the field of hadron spectroscopy., Comment: 98 pages, 58 figures. To appear in Progress in Particle and Nuclear Physics

Published
2021
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14. Connecting Matrix Elements to Multi-Hadron Form-Factors

Author

Jackura, Andrew W.

Subjects
High Energy Physics - Lattice, High Energy Physics - Phenomenology, Nuclear Theory
Abstract

We discuss developments in calculating multi-hadron form-factors and transition processes via lattice QCD. Our primary tools are finite-volume scaling relations, which map spectra and matrix elements to the corresponding multi-hadron infinite-volume amplitudes. We focus on two hadron processes probed by an external current, and provide various checks on the finite-volume formalism in the limiting cases of perturbative interactions and systems forming a bound state. By studying model-independent properties of the infinite-volume amplitudes, we are able to rigorously define form-factors of resonances., Comment: 11 pages, 6 figures, proceedings to the 38th International Symposium on Lattice Field Theory (LATTICE21), 26-30 July 2021, Zoom/Gather@Massachusetts Institute of Technology

Published
2021

15. On-shell representations of two-body transition amplitudes: single external current

Author

Briceño, Raúl A., Jackura, Andrew W., Ortega-Gama, Felipe G., and Sherman, Keegan H.

Subjects
High Energy Physics - Lattice, High Energy Physics - Phenomenology, Nuclear Theory
Abstract

This work explores scattering amplitudes that couple two-particle systems via a single external current insertion, $2+\mathcal{J}\to 2$. Such amplitudes can provide structural information about the excited QCD spectrum. We derive an exact analytic representation for these reactions. From these amplitudes, we show how to rigorously define resonance and bound-state form-factors. Furthermore, we explore the consequences of the narrow-width limit of the amplitudes as well as the role of the Ward-Takahashi identity for conserved vector currents. These results hold for any number of two-body channels with no intrinsic spin, and a current with arbitrary Lorentz structure and quantum numbers. This work and the existing finite-volume formalism provide a complete framework for determining this class of amplitudes from lattice QCD., Comment: 35 pages, 13 figures

Published
2020
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16. Solving relativistic three-body integral equations in the presence of bound states

Author

Jackura, Andrew W., Briceño, Raúl A., Dawid, Sebastian M., Islam, Md Habib E, and McCarty, Connor

Subjects
High Energy Physics - Lattice, High Energy Physics - Phenomenology, Nuclear Theory
Abstract

We present a systematically improvable method for numerically solving relativistic three-body integral equations for the partial-wave projected amplitudes. The method consists of a discretization procedure in momentum space, which approximates the continuum problem with a matrix equation. It is solved for different matrix sizes, and in the end, an extrapolation is employed to restore the continuum limit. Our technique is tested by solving a three-body problem of scalar particles with an $S$ wave two-body bound state. We discuss two methods of incorporating the pole contribution in the integral equations, both of them leading to agreement with previous results obtained using finite-volume spectra of the same theory. We provide an analytic and numerical estimate of the systematic errors. Although we focus on kinematics below the three-particle threshold, we provide numerical evidence that the methods presented allow for determination of amplitude above this threshold as well., Comment: 20 pages, 9 figures

Published
2020
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17. Consistency checks for two-body finite-volume matrix elements: II. Perturbative systems

Author

Briceño, Raúl A., Hansen, Maxwell T., and Jackura, Andrew W.

Subjects
High Energy Physics - Lattice, High Energy Physics - Phenomenology, Nuclear Theory
Abstract

Using the general formalism presented in Refs. [1,2], we study the finite-volume effects for the $\mathbf{2}+\mathcal{J}\to\mathbf{2}$ matrix element of an external current coupled to a two-particle state of identical scalars with perturbative interactions. Working in a finite cubic volume with periodicity $L$, we derive a $1/L$ expansion of the matrix element through $\mathcal O(1/L^5)$ and find that it is governed by two universal current-dependent parameters, the scalar charge and the threshold two-particle form factor. We confirm the result through a numerical study of the general formalism and additionally through an independent perturbative calculation. We further demonstrate a consistency with the Feynman-Hellmann theorem, which can be used to relate the $1/L$ expansions of the ground-state energy and matrix element. The latter gives a simple insight into why the leading volume corrections to the matrix element have the same scaling as those in the energy, $1/L^3$, in contradiction to earlier work, which found a $1/L^2$ contribution to the matrix element. We show here that such a term arises at intermediate stages in the perturbative calculation, but cancels in the final result., Comment: 17 pages, 4 figures

Published
2020
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18. Matrix elements of bound states in a finite volume

Author

Jackura, Andrew W.

Subjects
High Energy Physics - Lattice
Abstract

Recently, a framework was developed for studying form factors of two-body states probed with an external current. Finite volume matrix elements that may be computed via lattice QCD are converted to infinite volume generalized form factors. These generalized form factors allow us to study the structure of composite states. In this talk, we consider the application of this formalism to bound states, and compare the leading finite volume effects to the general results of the framework. Specifically, we consider the implications for the deuteron at the physical point, and conclude that it's necessary to use the full formalism to not be saturated by systematics, Comment: 7 pages, 2 figures, presented at the 37th International Symposium on Lattice Field Theory - LATTICE2019 - 16-22 June, 2019, Wuhan, China

Published
2019

19. Consistency checks for two-body finite-volume matrix elements: I. Conserved currents and bound states

Author

Briceño, Raúl A., Hansen, Maxwell T., and Jackura, Andrew W.

Subjects
High Energy Physics - Lattice, High Energy Physics - Phenomenology, Nuclear Theory
Abstract

Recently, a framework has been developed to study form factors of two-hadron states probed by an external current. The method is based on relating finite-volume matrix elements, computed using numerical lattice QCD, to the corresponding infinite-volume observables. As the formalism is complicated, it is important to provide non-trivial checks on the final results and also to explore limiting cases in which more straightforward predications may be extracted. In this work we provide examples on both fronts. First, we show that, in the case of a conserved vector current, the formalism ensures that the finite-volume matrix element of the conserved charge is volume-independent and equal to the total charge of the two-particle state. Second, we study the implications for a two-particle bound state. We demonstrate that the infinite-volume limit reproduces the expected matrix element and derive the leading finite-volume corrections to this result for a scalar current. Finally, we provide numerical estimates for the expected size of volume effects in future lattice QCD calculations of the deuteron's scalar charge. We find that these effects completely dominate the infinite-volume result for realistic lattice volumes and that applying the present formalism, to analytically remove an infinite-series of leading volume corrections, is crucial to reliably extract the infinite-volume charge of the state., Comment: 20 pages, 5 figures

Published
2019
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20. Moments of angular distribution and beam asymmetries in $\eta\pi^0$ photoproduction at GlueX

Author

Mathieu, V., Albaladejo, M., Fernández-Ramírez, C., Jackura, A. W., Mikhasenko, M., Pilloni, A., and Szczepaniak, A. P.

Subjects
High Energy Physics - Phenomenology
Abstract

In the search for exotic mesons, the GlueX collaboration will soon extract moments of the $\eta\pi^0$ angular distribution. In the perspective of these results, we generalize the formalism of moment extraction to the case in which the two mesons are produced with a linearly polarized beam, and build a model for the reaction $\vec \gamma p \to \eta \pi^0 p$. The model includes resonant $S$-, $P$-, $D$-waves in $\eta\pi^0$, produced by natural exchanges. Moments of the $\eta\pi^0$ angular distribution are computed with and without the $P$-wave, to illustrate the sensitivity to exotic resonances. Although little sensitivity to the $P$-wave is found in moments of even angular momentum, moments of odd angular momentum are proportional to the interference between the $P$-wave and the dominant $S$- and $D$-waves. We also generalize the definition of the beam asymmetry for two mesons photoproduction and show that, when the meson momenta are perpendicular to the reaction plane, the beam asymmetry enhances the sensitivity to the exotic $P$-wave., Comment: 17 pages, 7 figures, match the published version

Published
2019
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21. On the Equivalence of Three-Particle Scattering Formalisms

Author

Jackura, A. W., Dawid, S. M., Fernández-Ramírez, C., Mathieu, V., Mikhasenko, M., Pilloni, A., Sharpe, S. R., and Szczepaniak, A. P.

Subjects
High Energy Physics - Phenomenology, High Energy Physics - Lattice, Nuclear Theory
Abstract

In recent years, different on-shell $\mathbf{3}\to\mathbf{3}$ scattering formalisms have been proposed to be applied to both lattice QCD and infinite volume scattering processes. We prove that the formulation in the infinite volume presented by Hansen and Sharpe in Phys.~Rev.~D92, 114509 (2015) and subsequently Brice\~no, Hansen, and Sharpe in Phys.~Rev.~D95, 074510 (2017) can be recovered from the $B$-matrix representation, derived on the basis of $S$-matrix unitarity, presented by Mai {\em et al.} in Eur.~Phys.~J.~A53, 177 (2017) and Jackura {\em et al.} in Eur.~Phys.~J.~C79, 56 (2019). Therefore, both formalisms in the infinite volume are equivalent and the physical content is identical. Additionally, the Faddeev equations are recovered in the non-relativistic limit of both representations., Comment: 13 pages, 5 figures

Published
2019
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23. Electroweak three-body decays in the presence of two- and three-body bound states

Author

Briceño, Raul A., Jackura, Andrew W., Pefkou, Dimitra A., Romero-López, Fernando, Briceño, Raul A., Jackura, Andrew W., Pefkou, Dimitra A., and Romero-López, Fernando

Abstract

Recently, formalism has been derived for studying electroweak transition amplitudes for three-body systems both in infinite and finite volumes. The formalism provides exact relations that the infinite-volume amplitudes must satisfy, as well as a relationship between physical amplitudes and finite-volume matrix elements, which can be constrained from lattice QCD calculations. This formalism poses additional challenges when compared with the analogous well-studied two-body equivalent one, including the necessary step of solving integral equations of singular functions. In this work, we provide some non-trivial analytical and numerical tests on the aforementioned formalism. In particular, we consider a case where the three-particle system can have three-body bound states as well as bound states in the two-body subsystem. For kinematics below the three-body threshold, we demonstrate that the scattering amplitudes satisfy unitarity. We also check that for these kinematics the finite-volume matrix elements are accurately described by the formalism for two-body systems up to exponentially suppressed corrections. Finally, we verify that in the case of the three-body bound state, the finite-volume matrix element is equal to the infinite-volume coupling of the bound state, up to exponentially suppressed errors.

Published
2024

25. Prospects for <math><mrow><msup><mrow><mi>γ</mi></mrow><mrow><mo>⋆</mo></mrow></msup><msup><mrow><mi>γ</mi></mrow><mrow><mo>⋆</mo></mrow></msup><mo>→</mo><mi>π</mi><mi>π</mi></mrow></math> via lattice QCD

Author

Briceño, Raúl A., Jackura, Andrew W., Rodas, Arkaitz, and Guerrero, Juan V.

Abstract

The γ⋆γ⋆→ππ scattering amplitude plays a key role in a wide range of phenomena, including understanding the inner structure of scalar resonances as well as constraining the hadronic contributions to the anomalous magnetic moment of the muon. In this work, we explain how the infinite-volume Minkowski amplitude can be constrained from finite-volume Euclidean correlation functions. The relationship between the finite-volume Euclidean correlation functions and the desired amplitude holds up to energies where 3π states can go on shell, and is exact up to exponentially small corrections that scale like O(e−mπL), where L is the spatial extent of the cubic volume and mπ is the pion mass. In order to implement this formalism and remove all power-law finite volume errors, it is necessary to first obtain ππ→ππ, πγ⋆→π, γ⋆→ππ, and ππγ⋆→ππ amplitudes; all of which can be determined via lattice quantum chromodynamic calculations.

Published
2023

27. Novel approaches in hadron spectroscopy

Author

Albaladejo, Miguel, primary, Bibrzycki, Łukasz, additional, Dawid, Sebastian M., additional, Fernández-Ramírez, César, additional, Gonzàlez-Solís, Sergi, additional, Blin, Astrid N. Hiller, additional, Jackura, Andrew W., additional, Mathieu, Vincent, additional, Mikhasenko, Mikhail, additional, Mokeev, Victor I., additional, Passemar, Emilie, additional, Pilloni, Alessandro, additional, Rodas, Arkaitz, additional, Silva-Castro, Jorge A., additional, Smith, Wyatt A., additional, Szczepaniak, Adam P., additional, and Winney, Daniel, additional

Published
2022
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29. Prospects for $γ^\star γ^\star \to ππ$ via lattice QCD

Author

Briceño, Raúl A., Jackura, Andrew W., Rodas, Arkaitz, and Guerrero, Juan V.

Subjects
Nuclear Theory (nucl-th), High Energy Physics - Phenomenology (hep-ph), High Energy Physics - Lattice (hep-lat), FOS: Physical sciences
Abstract

The $γ^\star γ^\star \to ππ$ scattering amplitude plays a key role in a wide range of phenomena, including understanding the inner structure of scalar resonances as well as constraining the hadronic contributions to the anomalous magnetic moment of the muon. In this work, we explain how the infinite-volume Minkowski amplitude can be constrained from finite-volume Euclidean correlation functions. The relationship between the finite-volume Euclidean correlation functions and the desired amplitude holds up to energies where $3π$ states can go on shell, and is exact up to exponentially small corrections that scale like $\mathcal{O}(e^{-m_πL})$, where $L$ is the spatial extent of the cubic volume and $m_π$ is the pion mass. In order to implement this formalism and remove all power-law finite volume errors, it is necessary to first obtain $ππ\to ππ$, $πγ^\star \to π$, $γ^\star \toππ$, and $ππγ^\star \toππ$ amplitudes; all of which can be determined via lattice quantum chromodynamic calculations., 23 pages, 9 figures

Published
2022
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34. Snowmass white paper: Need for amplitude analysis in the discovery of new hadrons

Author

Albaladejo, Miguel, Battaglieri, Marco, Bibrzycki, Lukasz, Celentano, Andrea, Danilkin, Igor V., Dawid, Sebastian M., Michael Döring, Fanelli, Cristiano, Fernandez-Ramirez, Cesar, Gonzalez-Solis, Sergi, Blin, Astrid N. Hiller, Jackura, Andrew W., Mathieu, Vincent, Mikhasenko, Mikhail, Mokeev, Victor I., Passemar, Emilie, Perry, Robert J., Pilloni, Alessandro, Rodas, Arkaitz, Shepherd, Matthew R., Sherrill, Nathaniel, Silva-Castro, Jorge A., Skwarnicki, Tomasz, Szczepaniak, Adam P., and Winney, Daniel

Subjects
Nuclear Theory (nucl-th), High Energy Physics - Phenomenology, High Energy Physics - Experiment (hep-ex), High Energy Physics - Phenomenology (hep-ph), Nuclear Theory, High Energy Physics::Lattice, FOS: Physical sciences, High Energy Physics - Experiment
Abstract

We highlight the need for the development of comprehensive amplitude analysis methods to further our understanding of hadron spectroscopy. Reaction amplitudes constrained by first principles of $S$-matrix theory and by QCD phenomenology are needed to extract robust interpretations of the data from experiments and from lattice calculations., Comment: 15 pages, 9 figures. Contribution to Snowmass 2021

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