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Lattice QCD for Nuclear Physics electronic resource edited by Huey-Wen Lin, Harvey B. Meyer.

Contributor(s): Lin, Huey-Wen [editor.] | Meyer, Harvey B [editor.] | SpringerLink (Online service)Material type: TextTextSeries: Lecture Notes in PhysicsPublication details: Cham : Springer International Publishing : Imprint: Springer, 2015Description: XIII, 244 p. 78 illus., 59 illus. in color. online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9783319080222Subject(s): physics | Nuclear physics | Heavy ions | Hadrons | Elementary particles (Physics) | Quantum field theory | Physics | Nuclear Physics, Heavy Ions, Hadrons | Numerical and Computational Physics | Elementary Particles, Quantum Field TheoryDDC classification: 539.7092 LOC classification: QC770-798QC702.7.H42QC793.5.H32-793.5.H329Online resources: Click here to access online
Contents:
Lattice QCD: a Brief Introduction -- Lattice Methods for Hadron Spectroscopy -- Hadron Structure on the Lattice -- Chiral Perturbation Theory -- Nuclear Physics From Lattice QCD -- High Temperature and Density in Lattice QCD -- References.
In: Springer eBooksSummary: With ever increasing computational resources and improvements in algorithms, new opportunities are emerging for lattice gauge theory to address key questions in strongly interacting systems, such as nuclear matter. Calculations today use dynamical gauge-field ensembles with degenerate light up/down quarks and the strange quark and it is possible now to consider including charm-quark degrees of freedom in the QCD vacuum. Pion masses and other sources of systematic error, such as finite-volume and discretization effects, are beginning to be quantified systematically. Altogether, an era of precision calculation has begun, and many new observables will be calculated at the new computational facilities.  The aim of this set of lectures is to provide graduate students with a grounding in the application of lattice gauge theory methods to strongly interacting systems, and in particular to nuclear physics.  A wide variety of topics are covered, including continuum field theory, lattice discretizations, hadron spectroscopy and structure, many-body systems, together with more topical lectures in nuclear physics aimed a providing a broad phenomenological background. Exercises to encourage hands-on experience with parallel computing and data analysis are included.
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Lattice QCD: a Brief Introduction -- Lattice Methods for Hadron Spectroscopy -- Hadron Structure on the Lattice -- Chiral Perturbation Theory -- Nuclear Physics From Lattice QCD -- High Temperature and Density in Lattice QCD -- References.

With ever increasing computational resources and improvements in algorithms, new opportunities are emerging for lattice gauge theory to address key questions in strongly interacting systems, such as nuclear matter. Calculations today use dynamical gauge-field ensembles with degenerate light up/down quarks and the strange quark and it is possible now to consider including charm-quark degrees of freedom in the QCD vacuum. Pion masses and other sources of systematic error, such as finite-volume and discretization effects, are beginning to be quantified systematically. Altogether, an era of precision calculation has begun, and many new observables will be calculated at the new computational facilities.  The aim of this set of lectures is to provide graduate students with a grounding in the application of lattice gauge theory methods to strongly interacting systems, and in particular to nuclear physics.  A wide variety of topics are covered, including continuum field theory, lattice discretizations, hadron spectroscopy and structure, many-body systems, together with more topical lectures in nuclear physics aimed a providing a broad phenomenological background. Exercises to encourage hands-on experience with parallel computing and data analysis are included.

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