HADRONIC PHYSICS (6 ECTS)
The subject will be taught in 23 lectures and tutorships of 1:30 hours. The tutorial sessions will be devoted to discussing questions about the contents of the course, proposed exercises, etc.
Lectures and Teachers:
Assumpta Parreño
P1. QCD Lagrangian. Non-perturbative methods.
P2. Effective theories (I).
P3. Effective theories (II).
P4. Lattice QCD.
P5. Tutorship A. Parreño
Volodymyr Magas
M1. Klein-Gordon and Dirac equations.
M2. Relativistic collisions and Feynman diagrams.
M3. Quantum electrodynamics of particles with spin 0, examples.
M4. Quantum electrodynamics of particles with spin 1/2, examples.
M5. Tutorship V. Magas
Laura Tolós
T1. Phenomenology of the NN interaction. One-meson exchange model.
T2. Bethe-Goldstone equation: interaction in the nuclear medium.
T3. Hadrons in nuclear matter.
T4. Tutorship L. Tolós
Sergi Gonzalez-Solis de la Fuente
G1. Introduction to the Standard Model (I): fundamental particles and their interactions
G2. Introduction to the Standard Model (II): the quark model (mesons and baryons)
G3. Tutorship S. Gonzalez-Solis
Juan Torres
J1. Deep inelastic scattering. Parton model.
J2. Quark-gluon plasma. QCD Phase Diagram.
J3. Tutorship J. Torres
Vincent Mathieu
V1. Tools for Hadronic Physics: Theoretical review
V2. Tools for Hadronic Physics: Numerical application I
V3. Tools for Hadronic Physics: Numerical application II
Timetable
|
Monday, |
Tuesday, |
Wednesday, 19-03 |
Thursday, 20-03 |
Friday, |
|
|
9:30 – 11:00 |
G1. S. Gonzalez |
G2. S. Gonzalez |
G3. |
T1. |
T2. L. Tolós |
|
11:30 – 13:00 |
M1. V. Magas |
M2. V. Magas |
M3. V. Magas |
M4. V. Magas |
T3. L. Tolós |
|
|
Monday, (in person) |
Tuesday, |
Wednesday, 26-03 |
Thursday, 27-03 |
Friday, |
|
9:30 – 11:00 |
P1. A. Parreño |
P2. A. Parreño |
Visit to ALBA synchrotron |
P4. A. Parreño |
J3. J. Torres |
|
11:30 – 13:00 |
M5. V. Magas |
J1. |
J2. |
V2. V. Mathieu |
|
|
15:00-16:30 |
V1. |
P3. A. Parreño |
T4. L. Tolós |
P5. A. Parreño |
V3. V. Mathieu |
Evaluation: the evaluation will be based on a series of exercises to be carried out during the course and a final exam.
Basic Bibliography:
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“Quantum Field Theory”, F. Mandl y G. Shaw, Wiley and Sons Ltd, 1984.
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“Models of the nucleon: from quarks to solitons”, R.K. Bhaduri, Addison-Wesley, 1988.
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“Quarks and Leptons: an introductory course in modern particle physics”, F. Halzen and A.D. Martin, Wiley and Sons Ltd., 1984.
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“Pions and Nuclei”, T.E.O. Ericson, W. Weise. Oxford-Clarendon Press, 1988.
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“Electroweak and Strong Interactions”, F. Scheck, Springer-Verlag, 3rd edition.
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“Theoretical Nuclear and Subnuclear Physics”, J.D. Walecka. Oxford University Press, 1995.
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“Gauge theories in Particle Physic”, I.J.R.Aitchison and A.J.G.Hey
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“Introduction to the Quark Model of Elementary Particle”, D. Flamm and F. Schöberl. Gordon and Breach, Science Publishers Inc. 1982.
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“Quantum Theory of Many Particle Systems”, A.L. Fetter y J.D. Walecka, Dover, 2003.
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“A Guide to Feynman Diagrams in the Many Body Problem”, R.D. Mattuck (Dover, New York, 1992), Second Edition.
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“The Meson theory of nuclear forces and nuclear structure”, R. Machleidt, Adv. Nucl. Phys. 19 (1989) 189-376.
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“Production, structure and decay of hypernuclei”, H. Bando, T. Motoba, J. Zofka, Int. J. Mod. Phys. A5 (1990) 4021-4198.
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“In-medium nuclear interactions of low-energy hadrons”, E. Friedman, A. Gal, Phys. Rept. 452 (2007) 89-153.
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"Chiral Effective Field Theory and Nuclear Forces", R. Machleidt and D.R. Entem, Phys. Rept. 503, 1-75 (2011); arXiv:1105.2919
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"Lattice QCD for novices", G. Peter Lepage, Proceedings of HUGS 98, edited by J.L. Goity, World Scientific (2000); arXiv:hep-lat/0506036
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"Introduction to Lattice QCD", Rajan Gupta, arXiv:hep-lat/9807028
