Phenomenology (particle physics)

Particle physics phenomenology is the part of theoretical particle physics that deals with the application of theoretical physics to high-energy particle physics experiments. Phenomenology forms a bridge between the mathematical models of theoretical physics (such as quantum field theories and theories of the structure of space-time) and experimental particle physics. Within the Standard Model, phenomenology is the calculating of detailed predictions for experiments, usually at high precision (e.g., including radiative corrections). Beyond the Standard Model, phenomenology addresses the experimental consequences of new models: how their new particles could be searched for, how the model parameters could be measured, and how the model could be distinguished from other, competing models.

Some examples

Monte Carlo simulation studies of physics processes at colliders.
Next-to-leading order calculations of particle production rates and distributions.
Extraction of parton distribution functions from data.
Application of heavy quark effective field theory to extract CKM matrix elements.
Using lattice QCD to extract quark masses and CKM matrix elements from experiment.
"Phenomenological analyses," in which one studies the experimental consequences of adding the most general set of beyond-the-Standard-Model effects in a given sector of the Standard Model, usually parameterized in terms of anomalous couplings and higher-dimensional operators. In this case, the term "phenomenological" is being used more in its philosophy of science sense.

External links

Papers on phenomenology are available on the hep-ph archive of the ArXiv.org e-print archive
List of topics on phenomenology from IPPP, the Institute for Particle Physics Phenomenology at University of Durham, UK
Collider Phenomenology: Basic knowledge and techniques, lectures by Tao Han
Pheno '08 Symposium on particle physics phenomenology, including slides from the talks linked from the symposium program.

Branches of physics

Divisions	Applied Experimental Theoretical

Energy Motion	Thermodynamics Mechanics Classical Lagrangian Hamiltonian Continuum Celestial Statistical Fluid Quantum

Waves Fields	Gravitation Electromagnetism Quantum field theory Relativity Special General

By speciality	Accelerator Acoustics Astrophysics Nuclear Stellar Heliophysics Solar Space Astroparticle Atomic–molecular–optical (AMO) Communication Computational Condensed matter Solid-state Soft Digital Engineering Material Mathematical Nuclear Optics Geometrical Physical Nonlinear Quantum Particle Phenomenology Plasma Polymer Statistical

Physics in life science	Biophysics Virophysics Biomechanics Medical physics Cardiophysics Health physics Laser medicine Medical imaging‎ Nuclear medicine Neurophysics Psychophysics

Physics with other sciences	Agrophysics Soil Atmospheric Chemical Econophysics Geophysics

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Phenomenology (particle physics)

Some examples

See also

External links