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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,
17-03
(online)

Tuesday,
18-03
(online)

Wednesday,

19-03
(online)

Thursday,

20-03
(online)

Friday,
21-03
(online)

9:30 – 11:00

G1.

S. Gonzalez

G2.

S. Gonzalez

G3.
S. Gonzalez

T1.
L. Tolós

T2.

L. Tolós

11:30 – 13:00

M1.

V. Magas

M2.

V. Magas

M3.

V. Magas

M4.

V. Magas

T3.

L. Tolós
           


Monday,
24-03

(in person)

Tuesday,
25-03
(in person)

Wednesday,

26-03
(in person)

Thursday,

27-03
(in person)

Friday,
28-04
(in person)

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.
J. Torres

J2.
J. Torres

V2.

V. Mathieu
           

15:00-16:30

V1.
V. Mathieu

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:

  1. Quantum Field Theory”, F. Mandl y G. Shaw, Wiley and Sons Ltd, 1984.

  1. Models of the nucleon: from quarks to solitons”, R.K. Bhaduri, Addison-Wesley, 1988.

  1. Quarks and Leptons: an introductory course in modern particle physics”, F. Halzen and A.D. Martin, Wiley and Sons Ltd., 1984.

  1. Pions and Nuclei”, T.E.O. Ericson, W. Weise. Oxford-Clarendon Press, 1988.

  1. Electroweak and Strong Interactions”, F. Scheck, Springer-Verlag, 3rd edition.

  1. Theoretical Nuclear and Subnuclear Physics”, J.D. Walecka. Oxford University Press, 1995.

  1. Gauge theories in Particle Physic”, I.J.R.Aitchison and A.J.G.Hey

  1. Introduction to the Quark Model of Elementary Particle”, D. Flamm and F. Schöberl. Gordon and Breach, Science Publishers Inc. 1982.

  1. Quantum Theory of Many Particle Systems”, A.L. Fetter y J.D. Walecka, Dover, 2003.

  1. A Guide to Feynman Diagrams in the Many Body Problem”, R.D. Mattuck (Dover, New York, 1992), Second Edition.

  1. The Meson theory of nuclear forces and nuclear structure”, R. Machleidt, Adv. Nucl. Phys. 19 (1989) 189-376.

  1. Production, structure and decay of hypernuclei”, H. Bando, T. Motoba, J. Zofka, Int. J. Mod. Phys. A5 (1990) 4021-4198.

  1. In-medium nuclear interactions of low-energy hadrons”, E. Friedman, A. Gal, Phys. Rept. 452 (2007) 89-153.

  1. "Chiral Effective Field Theory and Nuclear Forces", R. Machleidt and D.R. Entem, Phys. Rept. 503, 1-75 (2011); arXiv:1105.2919

  1. "Lattice QCD for novices", G. Peter Lepage, Proceedings of HUGS 98, edited by J.L. Goity, World Scientific (2000); arXiv:hep-lat/0506036

  1. "Introduction to Lattice QCD", Rajan Gupta, arXiv:hep-lat/9807028