Your search keyword '"Hackett, Daniel A."' showing total 567 results

1. Block Lanczos for lattice QCD spectroscopy and matrix elements

Author

Hackett, Daniel C. and Wagman, Michael L.

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology, Mathematics - Numerical Analysis, Nuclear Theory

Abstract

Recent work introduced a new framework for analyzing correlation functions with improved convergence and signal-to-noise properties, as well as rigorous quantification of excited-state effects, based on the Lanczos algorithm and spurious eigenvalue filtering with the Cullum-Willoughby test. Here, we extend this framework to the analysis of correlation-function matrices built from multiple interpolating operators in lattice quantum chromodynamics (QCD) by constructing an oblique generalization of the block Lanczos algorithm, as well as a new physically motivated reformulation of the Cullum-Willoughby test that generalizes to block Lanczos straightforwardly. The resulting block Lanczos method directly extends generalized eigenvalue problem (GEVP) methods, which can be viewed as applying a single iteration of block Lanczos. Block Lanczos provides qualitative and quantitative advantages over GEVP methods analogous to the benefits of Lanczos over the standard effective mass, including faster convergence to ground- and excited-state energies, explicitly computable two-sided error bounds, straightforward extraction of matrix elements of external currents, and asymptotically constant signal-to-noise. No fits or statistical inference are required. Proof-of-principle calculations are performed for noiseless mock-data examples as well as two-by-two proton correlation-function matrices in lattice QCD., Comment: 39+13 pages, 36 figures, 7 tables

Published

2024

2. Gravitational form factors of glueballs in Yang-Mills theory

Author

Abbott, Ryan, Hackett, Daniel C., Pefkou, Dimitra A., Romero-López, Fernando, and Shanahan, Phiala

Subjects

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

Abstract

This work presents preliminary results of the first determination of the energy-momentum tensor form factors of the scalar glueball, referred to as gravitational form factors (GFFs). The calculation has been carried out in lattice Yang-Mills theory at a single lattice spacing. Using variationally optimized operators, the matrix elements are extracted from ratios of three-point functions to two-point functions. The glueball GFFs and their kinematic dependence are compared to those of other hadrons from previous calculations., Comment: 9 pages, 3 figures, Contribution to the 41st International Symposium on Lattice Field Theory, July 28th - August 3rd 2024, Liverpool, UK

Published

2024

3. Lanczos for lattice QCD matrix elements

Author

Hackett, Daniel C. and Wagman, Michael L.

Subjects

High Energy Physics - Lattice

Abstract

Recent work found that an analysis formalism based on the Lanczos algorithm allows energy levels to be extracted from Euclidean correlation functions with faster convergence than existing methods, two-sided error bounds, and no apparent signal-to-noise problems. We extend this formalism to the determination of matrix elements from three-point correlation functions. We demonstrate similar advantages over previously available methods in both signal-to-noise and control of excited-state contamination through example applications to noiseless mock-data as well as calculations of (bare) forward matrix elements of the strange scalar current between both ground and excited states with the quantum numbers of the nucleon., Comment: 28 pages, 16 figures

Published

2024

4. Practical applications of machine-learned flows on gauge fields

Author

Abbott, Ryan, Albergo, Michael S., Boyda, Denis, Hackett, Daniel C., Kanwar, Gurtej, Romero-López, Fernando, Shanahan, Phiala E., and Urban, Julian M.

Subjects

High Energy Physics - Lattice, Condensed Matter - Statistical Mechanics, Computer Science - Machine Learning

Abstract

Normalizing flows are machine-learned maps between different lattice theories which can be used as components in exact sampling and inference schemes. Ongoing work yields increasingly expressive flows on gauge fields, but it remains an open question how flows can improve lattice QCD at state-of-the-art scales. We discuss and demonstrate two applications of flows in replica exchange (parallel tempering) sampling, aimed at improving topological mixing, which are viable with iterative improvements upon presently available flows., Comment: 9 pages, 5 figures, proceedings of the 40th International Symposium on Lattice Field Theory (Lattice 2023)

Published

2024

5. Multiscale Normalizing Flows for Gauge Theories

Author

Abbott, Ryan, Albergo, Michael S., Boyda, Denis, Hackett, Daniel C., Kanwar, Gurtej, Romero-López, Fernando, Shanahan, Phiala E., and Urban, Julian M.

Subjects

High Energy Physics - Lattice

Abstract

Scale separation is an important physical principle that has previously enabled algorithmic advances such as multigrid solvers. Previous work on normalizing flows has been able to utilize scale separation in the context of scalar field theories, but the principle has been largely unexploited in the context of gauge theories. This work gives an overview of a new method for generating gauge fields using hierarchical normalizing flow models. This method builds gauge fields from the outside in, allowing different parts of the model to focus on different scales of the problem. Numerical results are presented for $U(1)$ and $SU(3)$ gauge theories in 2, 3, and 4 spacetime dimensions., Comment: Submitted as a proceedings to the 40th International Symposium on Lattice Field Theory (Lattice 2023)

Published

2024

6. Guiding Evidence-Based Classification in Para Sporting Populations: A Systematic Review of Impairment Measures and Activity Limitations

Author

Wileman, Taylor M., McKay, Marnee J., Hackett, Daniel A., Watson, Timothy J., Fleeton, Jennifer, and Fornusek, Ché

Published

2024

7. Applications of flow models to the generation of correlated lattice QCD ensembles

Author

Abbott, Ryan, Botev, Aleksandar, Boyda, Denis, Hackett, Daniel C., Kanwar, Gurtej, Racanière, Sébastien, Rezende, Danilo J., Romero-López, Fernando, Shanahan, Phiala E., and Urban, Julian M.

Subjects

High Energy Physics - Lattice, Computer Science - Machine Learning

Abstract

Machine-learned normalizing flows can be used in the context of lattice quantum field theory to generate statistically correlated ensembles of lattice gauge fields at different action parameters. This work demonstrates how these correlations can be exploited for variance reduction in the computation of observables. Three different proof-of-concept applications are demonstrated using a novel residual flow architecture: continuum limits of gauge theories, the mass dependence of QCD observables, and hadronic matrix elements based on the Feynman-Hellmann approach. In all three cases, it is shown that statistical uncertainties are significantly reduced when machine-learned flows are incorporated as compared with the same calculations performed with uncorrelated ensembles or direct reweighting., Comment: 12 pages, 2 tables, 5 figures. v2: accepted for publication

Published

2024

8. Gravitational Form Factors of the Proton from Lattice QCD

Author

Hackett, Daniel C, Pefkou, Dimitra A, and Shanahan, Phiala E

Abstract

The gravitational form factors (GFFs) of a hadron encode fundamental aspects of its structure, including its shape and size as defined from, e.g., its energy density. This Letter presents a determination of the flavor decomposition of the GFFs of the proton from lattice QCD, in the kinematic region 0≤−t≤2  GeV2. The decomposition into up-, down-, strange-quark, and gluon contributions provides first-principles constraints on the role of each constituent in generating key proton structure observables, such as its mechanical radius, mass radius, and D term. Published by the American Physical Society 2024

Published

2024

9. Gravitational form factors of the proton from lattice QCD

Author

Hackett, Daniel C., Pefkou, Dimitra A., and Shanahan, Phiala E.

Subjects

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

Abstract

The gravitational form factors (GFFs) of a hadron encode fundamental aspects of its structure, including its shape and size as defined from e.g., its energy density. This work presents a determination of the flavor decomposition of the GFFs of the proton from lattice QCD, in the kinematic region $0\leq -t\leq 2~\text{GeV}^2$. The decomposition into up-, down-, strange-quark, and gluon contributions provides first-principles constraints on the role of each constituent in generating key proton structure observables, such as its mechanical radius, mass radius, and $D$-term., Comment: Version published in PRL

Published

2023

10. Normalizing flows for lattice gauge theory in arbitrary space-time dimension

Author

Abbott, Ryan, Albergo, Michael S., Botev, Aleksandar, Boyda, Denis, Cranmer, Kyle, Hackett, Daniel C., Kanwar, Gurtej, Matthews, Alexander G. D. G., Racanière, Sébastien, Razavi, Ali, Rezende, Danilo J., Romero-López, Fernando, Shanahan, Phiala E., and Urban, Julian M.

Subjects

High Energy Physics - Lattice, Condensed Matter - Statistical Mechanics, Computer Science - Machine Learning

Abstract

Applications of normalizing flows to the sampling of field configurations in lattice gauge theory have so far been explored almost exclusively in two space-time dimensions. We report new algorithmic developments of gauge-equivariant flow architectures facilitating the generalization to higher-dimensional lattice geometries. Specifically, we discuss masked autoregressive transformations with tractable and unbiased Jacobian determinants, a key ingredient for scalable and asymptotically exact flow-based sampling algorithms. For concreteness, results from a proof-of-principle application to SU(3) lattice gauge theory in four space-time dimensions are reported.

Published

2023

11. Aspects of scaling and scalability for flow-based sampling of lattice QCD

Author

Abbott, Ryan, Albergo, Michael S., Botev, Aleksandar, Boyda, Denis, Cranmer, Kyle, Hackett, Daniel C., Matthews, Alexander G. D. G., Racanière, Sébastien, Razavi, Ali, Rezende, Danilo J., Romero-López, Fernando, Shanahan, Phiala E., and Urban, Julian M.

Subjects

High Energy Physics - Lattice, Condensed Matter - Statistical Mechanics, Computer Science - Machine Learning

Abstract

Recent applications of machine-learned normalizing flows to sampling in lattice field theory suggest that such methods may be able to mitigate critical slowing down and topological freezing. However, these demonstrations have been at the scale of toy models, and it remains to be determined whether they can be applied to state-of-the-art lattice quantum chromodynamics calculations. Assessing the viability of sampling algorithms for lattice field theory at scale has traditionally been accomplished using simple cost scaling laws, but as we discuss in this work, their utility is limited for flow-based approaches. We conclude that flow-based approaches to sampling are better thought of as a broad family of algorithms with different scaling properties, and that scalability must be assessed experimentally., Comment: 22 pages, 8 figures

Published

2022

12. Report of the Snowmass 2021 Topical Group on Lattice Gauge Theory

Author

Davoudi, Zohreh, Neil, Ethan T., Bauer, Christian W., Bhattacharya, Tanmoy, Blum, Thomas, Boyle, Peter, Brower, Richard C., Catterall, Simon, Christ, Norman H., Cirigliano, Vincenzo, Colangelo, Gilberto, DeTar, Carleton, Detmold, William, Edwards, Robert G., El-Khadra, Aida X., Gottlieb, Steven, Gupta, Rajan, Hackett, Daniel C., Hasenfratz, Anna, Izubuchi, Taku, Jay, William I., Jin, Luchang, Kelly, Christopher, Kronfeld, Andreas S., Lehner, Christoph, Lin, Huey-Wen, Lin, Meifeng, Lytle, Andrew T., Meinel, Stefan, Meurice, Yannick, Mukherjee, Swagato, Nicholson, Amy, Prelovsek, Sasa, Savage, Martin J., Shanahan, Phiala E., Van De Water, Ruth S., Wagman, Michael L., and Witzel, Oliver

Subjects

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

Abstract

Lattice gauge theory continues to be a powerful theoretical and computational approach to simulating strongly interacting quantum field theories, whose applications permeate almost all disciplines of modern-day research in High-Energy Physics. Whether it is to enable precision quark- and lepton-flavor physics, to uncover signals of new physics in nucleons and nuclei, to elucidate hadron structure and spectrum, to serve as a numerical laboratory to reach beyond the Standard Model, or to invent and improve state-of-the-art computational paradigms, the lattice-gauge-theory program is in a prime position to impact the course of developments and enhance discovery potential of a vibrant experimental program in High-Energy Physics over the coming decade. This projection is based on abundant successful results that have emerged using lattice gauge theory over the years: on continued improvement in theoretical frameworks and algorithmic suits; on the forthcoming transition into the exascale era of high-performance computing; and on a skillful, dedicated, and organized community of lattice gauge theorists in the U.S. and worldwide. The prospects of this effort in pushing the frontiers of research in High-Energy Physics have recently been studied within the U.S. decadal Particle Physics Planning Exercise (Snowmass 2021), and the conclusions are summarized in this Topical Report., Comment: 57 pages, 1 figure. Submitted to the Proceedings of the US Community Study on the Future of Particle Physics (Snowmass 2021). Topical Group Report for TF05 - Lattice Gauge Theory

Published

2022

13. Sampling QCD field configurations with gauge-equivariant flow models

Author

Abbott, Ryan, Albergo, Michael S., Botev, Aleksandar, Boyda, Denis, Cranmer, Kyle, Hackett, Daniel C., Kanwar, Gurtej, Matthews, Alexander G. D. G., Racanière, Sébastien, Razavi, Ali, Rezende, Danilo J., Romero-López, Fernando, Shanahan, Phiala E., and Urban, Julian M.

Subjects

High Energy Physics - Lattice

Abstract

Machine learning methods based on normalizing flows have been shown to address important challenges, such as critical slowing-down and topological freezing, in the sampling of gauge field configurations in simple lattice field theories. A critical question is whether this success will translate to studies of QCD. This Proceedings presents a status update on advances in this area. In particular, it is illustrated how recently developed algorithmic components may be combined to construct flow-based sampling algorithms for QCD in four dimensions. The prospects and challenges for future use of this approach in at-scale applications are summarized., Comment: Submitted as a proceedings to the 39th International Symposium on Lattice Field Theory (Lattice 2022)

Published

2022

14. Neural-network preconditioners for solving the Dirac equation in lattice gauge theory

Author

Calì, Salvatore, Hackett, Daniel C., Lin, Yin, Shanahan, Phiala E., and Xiao, Brian

Subjects

High Energy Physics - Lattice, Computer Science - Machine Learning

Abstract

This work develops neural-network--based preconditioners to accelerate solution of the Wilson-Dirac normal equation in lattice quantum field theories. The approach is implemented for the two-flavor lattice Schwinger model near the critical point. In this system, neural-network preconditioners are found to accelerate the convergence of the conjugate gradient solver compared with the solution of unpreconditioned systems or those preconditioned with conventional approaches based on even-odd or incomplete Cholesky decompositions, as measured by reductions in the number of iterations and/or complex operations required for convergence. It is also shown that a preconditioner trained on ensembles with small lattice volumes can be used to construct preconditioners for ensembles with many times larger lattice volumes, with minimal degradation of performance. This volume-transferring technique amortizes the training cost and presents a pathway towards scaling such preconditioners to lattice field theory calculations with larger lattice volumes and in four dimensions., Comment: 11 pages, 6 figures, and 2 tables

Published

2022

15. Gauge-equivariant flow models for sampling in lattice field theories with pseudofermions

Author

Abbott, Ryan, Albergo, Michael S., Boyda, Denis, Cranmer, Kyle, Hackett, Daniel C., Kanwar, Gurtej, Racanière, Sébastien, Rezende, Danilo J., Romero-López, Fernando, Shanahan, Phiala E., Tian, Betsy, and Urban, Julian M.

Subjects

High Energy Physics - Lattice, Computer Science - Machine Learning

Abstract

This work presents gauge-equivariant architectures for flow-based sampling in fermionic lattice field theories using pseudofermions as stochastic estimators for the fermionic determinant. This is the default approach in state-of-the-art lattice field theory calculations, making this development critical to the practical application of flow models to theories such as QCD. Methods by which flow-based sampling approaches can be improved via standard techniques such as even/odd preconditioning and the Hasenbusch factorization are also outlined. Numerical demonstrations in two-dimensional U(1) and SU(3) gauge theories with $N_f=2$ flavors of fermions are provided., Comment: 15 pages, 7 figures. v3: accepted version for publication. New appendix C

Published

2022

16. Improvement in physical function and lipid profile following low-intensity resistance training and a lower limb conditioning program in people with diabetic neuropathy

Author

Hosseini, Mahdi, Chow, Chin-Moi, Nadi, Maryam, Hackett, Daniel, and Marandi, Sayyed Mohammad

Published

2024

17. Flow-based sampling in the lattice Schwinger model at criticality

Author

Albergo, Michael S., Boyda, Denis, Cranmer, Kyle, Hackett, Daniel C., Kanwar, Gurtej, Racanière, Sébastien, Rezende, Danilo J., Romero-López, Fernando, Shanahan, Phiala E., and Urban, Julian M.

Subjects

High Energy Physics - Lattice, Condensed Matter - Statistical Mechanics, Computer Science - Machine Learning

Abstract

Recent results suggest that flow-based algorithms may provide efficient sampling of field distributions for lattice field theory applications, such as studies of quantum chromodynamics and the Schwinger model. In this work, we provide a numerical demonstration of robust flow-based sampling in the Schwinger model at the critical value of the fermion mass. In contrast, at the same parameters, conventional methods fail to sample all parts of configuration space, leading to severely underestimated uncertainties., Comment: 5 pages main text, 3 pages supplementary material. 4 figures

Published

2022

18. Applications of Machine Learning to Lattice Quantum Field Theory

Author

Boyda, Denis, Calì, Salvatore, Foreman, Sam, Funcke, Lena, Hackett, Daniel C., Lin, Yin, Aarts, Gert, Alexandru, Andrei, Jin, Xiao-Yong, Lucini, Biagio, and Shanahan, Phiala E.

Subjects

High Energy Physics - Lattice, Computer Science - Machine Learning, High Energy Physics - Phenomenology

Abstract

There is great potential to apply machine learning in the area of numerical lattice quantum field theory, but full exploitation of that potential will require new strategies. In this white paper for the Snowmass community planning process, we discuss the unique requirements of machine learning for lattice quantum field theory research and outline what is needed to enable exploration and deployment of this approach in the future., Comment: 10 pages, contribution to Snowmass 2022

Published

2022

19. Sexual and reproductive history of female prisoners in Iran: a health care needs analysis

Author

Farhoudi, Behnam, Shahmohamadi, Elnaz, SeyedAlinaghi, SeyedAhmad, Rostam Afshar, Zohreh, Mirzapour, Pegah, Nadji, SeyedAlireza, Golsoorat Pahlaviani, Fatemeh, Tashakorian, Mehrzad, and Hackett, Daniel

Published

2023

20. Gluon gravitational structure of hadrons of different spin

Author

Pefkou, Dimitra A., Hackett, Daniel C., and Shanahan, Phiala E.

Subjects

High Energy Physics - Lattice, Nuclear Theory

Abstract

The gravitational form factors (GFFs) of hadrons encode the matrix elements of the energy momentum tensor of QCD. These quantities describe how energy, spin, and various mechanical properties of hadrons are carried by their quark and gluon constituents. We present the gluon GFFs of the pion, nucleon, $\rho$ meson, and $\Delta$ baryon as functions of the squared momentum transfer $t$ in the region $0 \leq -t < 2 \; \text{GeV}^2$, as determined in a lattice QCD study with pion mass $m_{\pi} = 450(5) \; \text{MeV}$. By fitting the extracted GFFs using multipole and z-parameter expansion functional forms, we extract various gluon contributions to the energy, pressure, and shear force distributions of the hadrons in the 3D and 2D Breit frames as well as in the infinite momentum frame. We also obtain estimates for the corresponding gluon mechanical and mass radii, as well as the forward-limit gluon contributions to the momentum fraction and angular momentum of the hadrons., Comment: 41 pages, 19 figures, as published in PRD. v2,v3: updated citations

Published

2021

21. Flow-based sampling for multimodal distributions in lattice field theory

Author

Hackett, Daniel C., Hsieh, Chung-Chun, Albergo, Michael S., Boyda, Denis, Chen, Jiunn-Wei, Chen, Kai-Feng, Cranmer, Kyle, Kanwar, Gurtej, and Shanahan, Phiala E.

Subjects

High Energy Physics - Lattice, Condensed Matter - Statistical Mechanics, Computer Science - Machine Learning

Abstract

Recent results have demonstrated that samplers constructed with flow-based generative models are a promising new approach for configuration generation in lattice field theory. In this paper, we present a set of methods to construct flow models for targets with multiple separated modes (i.e. theories with multiple vacua). We demonstrate the application of these methods to modeling two-dimensional real scalar field theory in its symmetry-broken phase. In this context we investigate the performance of different flow-based sampling algorithms, including a composite sampling algorithm where flow-based proposals are occasionally augmented by applying updates using traditional algorithms like HMC., Comment: 33 pages, 29 figures

Published

2021

22. Soft pion scattering in infrared-conformal gauge-fermion theories

Author

Hackett, Daniel C. and Neil, Ethan T.

Subjects

High Energy Physics - Phenomenology, High Energy Physics - Lattice, High Energy Physics - Theory

Abstract

We consider the problem of soft scattering for the analogue of pion states in gauge-fermion theories which approach a conformal fixed point in the infrared limit. Introducing a fermion mass into such a theory will explicitly break both scale invariance and chiral symmetry, leading to confinement and a spectrum of bound states. We argue that in such a theory, the pion scattering length diverges in the limit of zero fermion mass, in sharp contrast to QCD-like theories where the chiral Lagrangian predicts a vanishing scattering length. We demonstrate this effect both with a simple dimensional argument, and in a generalized linear sigma model which we argue can be used to describe the interactions of light scalar and pseudoscalar bound states in the soft limit of a mass-deformed infrared-conformal theory. As a result, lattice calculations of pion scattering lengths could be a sensitive probe for infrared scale invariance in gauge-fermion theories., Comment: 11 pages, 1 figure. v2: updated to journal version

Published

2021

23. Hearing loss and COVID-19: an umbrella review

Author

Mehraeen, Esmaeil, Afzalian, Arian, Afsahi, Amir Masoud, Shahidi, Ramin, Fakhfouri, Amirata, Karimi, Kiana, Varshochi, Sanaz, Habibi, Mohammad Amin, Molla, Ayoob, Dadjou, Ali, Tajabadi, Zohreh, Nasiri, Khadijeh, Seyed Alinaghi, Seyed Ahmad, and Hackett, Daniel

Published

2023

24. Flow-based sampling for fermionic lattice field theories

Author

Albergo, Michael S., Kanwar, Gurtej, Racanière, Sébastien, Rezende, Danilo J., Urban, Julian M., Boyda, Denis, Cranmer, Kyle, Hackett, Daniel C., and Shanahan, Phiala E.

Subjects

High Energy Physics - Lattice, Condensed Matter - Statistical Mechanics, Computer Science - Machine Learning

Abstract

Algorithms based on normalizing flows are emerging as promising machine learning approaches to sampling complicated probability distributions in a way that can be made asymptotically exact. In the context of lattice field theory, proof-of-principle studies have demonstrated the effectiveness of this approach for scalar theories, gauge theories, and statistical systems. This work develops approaches that enable flow-based sampling of theories with dynamical fermions, which is necessary for the technique to be applied to lattice field theory studies of the Standard Model of particle physics and many condensed matter systems. As a practical demonstration, these methods are applied to the sampling of field configurations for a two-dimensional theory of massless staggered fermions coupled to a scalar field via a Yukawa interaction., Comment: 26 pages, 5 figures

Published

2021

25. Introduction to Normalizing Flows for Lattice Field Theory

Author

Albergo, Michael S., Boyda, Denis, Hackett, Daniel C., Kanwar, Gurtej, Cranmer, Kyle, Racanière, Sébastien, Rezende, Danilo Jimenez, and Shanahan, Phiala E.

Subjects

High Energy Physics - Lattice, Condensed Matter - Statistical Mechanics, Computer Science - Machine Learning

Abstract

This notebook tutorial demonstrates a method for sampling Boltzmann distributions of lattice field theories using a class of machine learning models known as normalizing flows. The ideas and approaches proposed in arXiv:1904.12072, arXiv:2002.02428, and arXiv:2003.06413 are reviewed and a concrete implementation of the framework is presented. We apply this framework to a lattice scalar field theory and to U(1) gauge theory, explicitly encoding gauge symmetries in the flow-based approach to the latter. This presentation is intended to be interactive and working with the attached Jupyter notebook is recommended., Comment: 38 pages, 5 numbered figures, Jupyter notebook included as ancillary file

Published

2021

26. Sampling using $SU(N)$ gauge equivariant flows

Author

Boyda, Denis, Kanwar, Gurtej, Racanière, Sébastien, Rezende, Danilo Jimenez, Albergo, Michael S., Cranmer, Kyle, Hackett, Daniel C., and Shanahan, Phiala E.

Subjects

High Energy Physics - Lattice, Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

We develop a flow-based sampling algorithm for $SU(N)$ lattice gauge theories that is gauge-invariant by construction. Our key contribution is constructing a class of flows on an $SU(N)$ variable (or on a $U(N)$ variable by a simple alternative) that respect matrix conjugation symmetry. We apply this technique to sample distributions of single $SU(N)$ variables and to construct flow-based samplers for $SU(2)$ and $SU(3)$ lattice gauge theory in two dimensions., Comment: 24 pages, 19 figures

Published

2020

27. Equivariant flow-based sampling for lattice gauge theory

Author

Kanwar, Gurtej, Albergo, Michael S., Boyda, Denis, Cranmer, Kyle, Hackett, Daniel C., Racanière, Sébastien, Rezende, Danilo Jimenez, and Shanahan, Phiala E.

Subjects

High Energy Physics - Lattice, Condensed Matter - Statistical Mechanics, Computer Science - Machine Learning

Abstract

We define a class of machine-learned flow-based sampling algorithms for lattice gauge theories that are gauge-invariant by construction. We demonstrate the application of this framework to U(1) gauge theory in two spacetime dimensions, and find that near critical points in parameter space the approach is orders of magnitude more efficient at sampling topological quantities than more traditional sampling procedures such as Hybrid Monte Carlo and Heat Bath., Comment: 6 pages, 4 figures

Published

2020

28. Cluster Sets to Prescribe Interval Resistance Training: A Potential Method to Optimise Resistance Training Safety, Feasibility and Efficacy in Cardiac Patients

Author

Way, Kimberley L., Thomas, Hannah J., Parker, Lewan, Maiorana, Andrew, Keske, Michelle A., Scott, David, Reed, Jennifer L., Tieng, Jessica, Hackett, Daniel, Hawkins, Tess, Latella, Christopher, Cordina, Rachael, and Tran, Derek L.

Published

2023

29. Reactions and perspectives of medical students on workplace violence during clinical training in Ardabil, Iran, 2020

Author

Sadeghi, Saber, Shadman, Atefeh, Mardi, Afrouz, and Hackett, Daniel

Published

2023

30. Aspects of scaling and scalability for flow-based sampling of lattice QCD

Author

Abbott, Ryan, Albergo, Michael S., Botev, Aleksandar, Boyda, Denis, Cranmer, Kyle, Hackett, Daniel C., Matthews, Alexander G. D. G., Racanière, Sébastien, Razavi, Ali, Rezende, Danilo J., Romero-López, Fernando, Shanahan, Phiala E., and Urban, Julian M.

Published

2023

31. Effects of Functional Electrical Stimulation Cycling Combined With Arm Cranking Exercise on Cardiorespiratory Fitness in People With Central Nervous System Disorders: A Systematic Review and Meta-analysis

Author

Máté, Suzanne, Sinan-Fornusek, Canan, Dhopte, Prakash, Singh, Maria Fiatarone, Hackett, Daniel, and Fornusek, Ché

Published

2023

32. Radiative contribution to the composite-Higgs potential in a two-representation lattice model

Author

Ayyar, Venkitesh, Golterman, Maarten, Hackett, Daniel C., Jay, William I., Neil, Ethan T., Shamir, Yigal, and Svetitsky, and Benjamin

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology

Abstract

Working in a two-representation lattice gauge theory that is close to a composite Higgs model, we calculate the low-energy constant CLR which controls the contribution of the electroweak gauge bosons to the Higgs potential. In QCD, the corresponding low-energy constant governs the mass splitting of the pion multiplet. Taking the continuum and chiral limits, we find that CLR, in units of the pseudoscalar decay constant, is roughly of the same size as its QCD counterpart.

Published

2019

33. Effect of resistance training on local muscle endurance in middle-aged and older adults: A systematic review with meta-analysis and meta-regression

Author

Wang, Boliang, Davies, Timothy B., Way, Kimberley L., Tran, Derek L., Davis, Glen M., Singh, Maria Fiatarone, and Hackett, Daniel A.

Published

2023

34. Partial compositeness and baryon matrix elements on the lattice

Author

Ayyar, Venkitesh, DeGrand, Thomas, Hackett, Daniel C., Jay, William I., Neil, Ethan T., Shamir, Yigal, and Svetitsky, Benjamin

Subjects

High Energy Physics - Phenomenology, High Energy Physics - Lattice

Abstract

Partial compositeness is a mechanism for the generation of fermion masses which replaces a direct Higgs coupling to the fermions by a linear mixing with heavy composite partners. We present the first calculation of the relevant matrix element in a lattice model which is very close to a candidate theory containing a composite Higgs boson and a partially composite top quark. Specifically, our model is an SU(4) gauge theory coupled to dynamical fermions in the fundamental and two-index antisymmetric (sextet) representations. The matrix element we obtain is small and hence our result disfavors the scenario of obtaining a realistic top mass in this model., Comment: Updated title and version accepted for publication in PRD

Published

2018

35. Digitizing Gauge Fields: Lattice Monte Carlo Results for Future Quantum Computers

Author

Hackett, Daniel C., Howe, Kiel, Hughes, Ciaran, Jay, William, Neil, Ethan T., and Simone, James N.

Subjects

Quantum Physics, High Energy Physics - Lattice, High Energy Physics - Phenomenology, High Energy Physics - Theory

Abstract

In the near-future noisy intermediate-scale quantum (NISQ) era of quantum computing technology, applications of quantum computing will be limited to calculations of very modest scales in terms of the number of qubits used. The need to represent numeric quantities using limited resources leads to digitization errors which must be taken into account. As a first step towards quantum simulations of realistic high-energy physics problems, we explore classically the effects of digitizing elements of the $\mathrm{SU}(2)$ gauge group to a finite set. We consider several methods for digitizing the group, finding the best performance from an action-preserving projection onto a mesh. Working in (3+1) dimensions, we find that using $\sim 7$ (qu)bits to represent each $\mathrm{SU}(2)$ gauge link induces a digitization error on the order of $10\%$ in short-distance observables and $2\%$ in long-distance observables. Promisingly, our results indicate that each $\mathrm{SU}(2)$ gauge link can be represented by $\mathcal{O}(10)$ (qu)bits, from which we estimate that a $16^3$ $\mathrm{SU}(2)$ lattice could be simulated with no more than $\mathcal{O}(10^5)$ (qu)bits. Our results on digitization are also of interest as a form of lossy compression that could be used in high-performance classical computing to alleviate communications bottlenecks., Comment: 16 pages; 11 figures; To be submitted to Physical Review A

Published

2018

36. Large $N_c$ Thermodynamics with Dynamical Fermions

Author

DeGrand, Thomas, Hackett, Daniel C., and Neil, Ethan T.

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology

Abstract

We present a progress report on our investigation of the thermodynamics of QCD with $N_f=2$ flavors of dynamical Wilson fermions in the limit of a large number of colors $N_c$. To date, studies of the thermodynamics of QCD at large $N_c$ have been limited to the quenched approximation, i.e., to the behavior of pure $\mathrm{SU}(N_c)$ gauge theory at large $N_c$. This is the first study of thermodynamics at large $N_c$ using dynamical fermions, and thus the first study able to test whether the quenched approximation is a valid way to investigate large $N_c$ thermodynamics. After reviewing 't Hooft's large $N_c$ limit, we discuss the automation we use to make this study feasible, and finally compare our preliminary physics results for $\mathrm{SU}(3-5)$ with large $N_c$ expectations., Comment: 7 pages, 3 figures. To appear in the Proceedings of The 36th Annual International Symposium on Lattice Field Theory - LATTICE2018, 22-28 July 2018, Michigan State University, East Lansing, Michigan, USA

Published

2018

37. Finite-temperature phase structure of SU(4) gauge theory with multiple fermion representations

Author

Ayyar, Venkitesh, DeGrand, Thomas, Hackett, Daniel C., Jay, William I., Neil, Ethan T., Shamir, Yigal, and Svetitsky, Benjamin

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology

Abstract

We investigate the phase structure of SU(4) gauge theory with the gauge field simultaneously coupled to two flavors of fermion in the fundamental representation and two flavors of fermion in the two-index antisymmetric representation. We find that the theory has only two phases, a low-temperature phase with both species of fermion confined and chirally broken, and a high-temperature phase with both species of fermion deconfined and chirally restored. The single phase transition in the theory appears to be first order, in agreement with theoretical predictions., Comment: 27 pages, 15 figures

Published

2018

38. Automated lattice data generation

Author

Ayyar, Venkitesh, Hackett, Daniel C., Jay, William I., and Neil, Ethan T.

Subjects

High Energy Physics - Lattice

Abstract

The process of generating ensembles of gauge configurations (and measuring various observables over them) can be tedious and error-prone when done "by hand". In practice, most of this procedure can be automated with the use of a workflow manager. We discuss how this automation can be accomplished using Taxi, a minimal Python-based workflow manager built for generating lattice data. We present a case study demonstrating this technology., Comment: 7 pages, 1 figure. Presented at Lattice 2017, the 35th International Symposium on Lattice Field Theory, Granada, Spain, 18-24 June 2017

Published

2018

39. Baryon spectrum of SU(4) composite Higgs theory with two distinct fermion representations

Author

Ayyar, Venkitesh, DeGrand, Thomas, Hackett, Daniel C., Jay, William I., Neil, Ethan T., Shamir, Yigal, and Svetitsky, Benjamin

Subjects

High Energy Physics - Phenomenology, High Energy Physics - Lattice

Abstract

We use lattice simulations to compute the baryon spectrum of SU(4) lattice gauge theory coupled to dynamical fermions in the fundamental and two-index antisymmetric (sextet) representations simultaneously. This model is closely related to a composite Higgs model in which the chimera baryon made up of fermions from both representations plays the role of a composite top-quark partner. The dependence of the baryon masses on each underlying fermion mass is found to be generally consistent with a quark-model description and large-Nc scaling. We combine our numerical results with experimental bounds on the scale of the new strong sector to derive a lower bound on the mass of the top partner., Comment: 23 pages, 11 figures, 7 tables

Published

2018

40. Stability Analysis of the Chiral Transition in SU(4) Gauge Theory with Fermions in Multiple Representations

Author

Hackett, Daniel C.

Subjects

High Energy Physics - Phenomenology, High Energy Physics - Lattice

Abstract

We present a Pisarski-Wilczek stability analysis of SU(4) gauge theory coupled simultaneously to fermions charged under the fundamental and two-index antisymmetric representations of the gauge group. We carry out the calculation to one loop in the $\epsilon$ expansion, assuming that the two species of fermion undergo a simultaneous chiral transition. The results indicate that the chiral transition is first order., Comment: 16 pages, 2 appendices

Published

2017

41. Confinement study of an SU(4) gauge theory with fermions in multiple representations

Author

Ayyar, Venkitesh, Hackett, Daniel, Jay, William, and Neil, Ethan

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology

Abstract

We discuss the phase diagnostics used in our finite-temperature study of an SU(4) gauge theory with dynamical fermions in both the fundamental and two-index antisymmetric representations. Beyond the usual Polyakov loop diagnostics of confinement, we employ several Wilson flow phase diagnostics. The first, what we call the "flow anisotropy", is known in the literature: the deconfinement transition introduces anisotropy between the spatial and temporal directions, to which the flow is extremely sensitive. The second, the "long flow time Polyakov loop," is related but novel. While we do not claim to fully understand this diagnostic, we have empirically found it to be useful as an unusually sharp diagnostic of phase., Comment: 7 pages, 6 figures. Presented at Lattice 2017, the 35th International Symposium on Lattice Field Theory, Granada, Spain, 18-24 June 2017

Published

2017

42. Spectroscopy of SU(4) composite Higgs theory with two distinct fermion representations

Author

Ayyar, Venkitesh, DeGrand, Thomas, Golterman, Maarten, Hackett, Daniel C., Jay, William I., Neil, Ethan T., Shamir, Yigal, and Svetitsky, Benjamin

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology

Abstract

We have simulated the SU(4) lattice gauge theory coupled to dynamical fermions in the fundamental and two-index antisymmetric (sextet) representations simultaneously. Such theories arise naturally in the context of composite Higgs models that include a partially composite top quark. We describe the low-lying meson spectrum of the theory and fit the pseudoscalar masses and decay constants to chiral perturbation theory. We infer as well the mass and decay constant of the Goldstone boson corresponding to the non-anomalous U(1) symmetry of the model. Our results are broadly consistent with large-Nc scaling and vector-meson dominance., Comment: 53 pages, 24 figures, 14 tables. v2: updated to journal version

Published

2017

43. Chiral Transition of SU(4) Gauge Theory with Fermions in Multiple Representations

Author

Ayyar, Venkitesh, DeGrand, Thomas, Hackett, Daniel C., Jay, William I., Neil, Ethan T., Shamir, Yigal, and Svetitsky, Benjamin

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology

Abstract

We report preliminary results on the finite temperature behavior of SU(4) gauge theory with dynamical quarks in both the fundamental and two-index antisymmetric representations. This system is a candidate to present scale separation behavior, where fermions in different representations condense at different temperature or coupling scales. Our simulations, however, reveal a single finite-temperature phase transition at which both representations deconfine and exhibit chiral restoration. It appears to be strongly first order. We compare our results to previous single-representation simulations. We also describe a Pisarski-Wilczek stability analysis, which suggests that the transition should be first order., Comment: 8 pages, 5 figures. Presented at at Lattice 2017, the 35th International Symposium on Lattice Field Theory, Granada, Spain, 18-24 June 2017

Published

2017

44. Efficacy of Morning Shorter Wavelength Lighting in the Visible (Blue) Range and Broad-Spectrum or Blue-Enriched Bright White Light in Regulating Sleep, Mood, and Fatigue in Traumatic Brain Injury: A Systematic Review

Author

Chow, Chin Moi, primary, Ekanayake, Kanchana, additional, and Hackett, Daniel, additional

Published

2024

45. Applications of flow models to the generation of correlated lattice QCD ensembles

Author

Abbott, Ryan, primary, Botev, Aleksandar, additional, Boyda, Denis, additional, Hackett, Daniel C., additional, Kanwar, Gurtej, additional, Racanière, Sébastien, additional, Rezende, Danilo J., additional, Romero-López, Fernando, additional, Shanahan, Phiala E., additional, and Urban, Julian M., additional

Published

2024

46. Pilot Study of Enhancing Cardiorespiratory Exercise Response in People With Advanced Multiple Sclerosis With Hybrid Functional Electrical Stimulation

Author

Máté, Suzanne, Soutter, Megan, Hackett, Daniel, Barnett, Michael, Singh, Maria Fiatarone, and Fornusek, Ché

Published

2021

47. Towards Partial Compositeness on the Lattice: Baryons with Fermions in Multiple Representations

Author

DeGrand, Thomas A., Hackett, Daniel, Jay, William I., Neil, Ethan T., Shamir, Yigal, and Svetitsky, Benjamin

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology

Abstract

We describe our recent lattice study of SU(4) gauge theory with fermions in the fundamental and sextet representations. In this theory, a new type of baryon consists of quarks in both representations. The spectrum of these "chimera baryons" has a straightforward interpretation in terms of a non-relativistic quark model based on SU(4). Our results are particularly relevant to composite Higgs models in which the top quark is partially composite., Comment: 7 pages, 3 figures. Presented at the 34th International Symposium on Lattice Field Theory - LATTICE 2016, 24-30 July, 2016, University of Southampton, UK

Published

2016

48. Lung function and respiratory muscle strength and their relationship with weightlifting strength and body composition in non-athletic males

Author

Hackett, Daniel A. and Sabag, Angelo

Published

2021

49. Powerlifting exercise performance and muscle mass indices and their relationship with bone mineral density

Author

Hackett, Daniel A. and Sabag, Angelo

Published

2021

50. Blood Flow Restriction Walking for Older Adults: A Brief Review.

Author

Ghayomzadeh, Morteza and Hackett, Daniel A.

Abstract

Walking is a low-impact form of physical activity feasible, acceptable, and safe for load-compromised individuals, such as older adults. Options available to increase the potency of this exercise exerto promote training adaptations are generally limited to manipulation of speed, gradient, and duration. How-Comever, emerging studies have suggested that blood flow restriction BFR) combined with walking is a method that can accentuate training-Emerginduced adaptations compared with walking alone. This narrative review aimed to examine the effectiveness and safety of BFR walking in older adults according to the existing literature. Of the limited evidence available on this topic, it appears that BFR walking compared with walking alone can induce significant increases in muscular hypertrophy and strength. Therefore, implementing BFR walking may be a feasible and safe option for older adults to enhance the effectiveness of their walking interventions, at least from a musculoskeletal perspective. [ABSTRACT FROM AUTHOR]

Published

2024