reaction

Deprecated since version 0.7.3: Use QRules and AmpForm instead

import expertsystem.reaction

Definition and solving of particle reaction problems.

This is the core component of the expertsystem: it defines the StateTransitionGraph data structure that represents a specific particle reaction. The solving submodule is responsible for finding solutions for particle reaction problems.

check_reaction_violations(initial_state: Union[str, Tuple[str, Sequence[float]], Sequence[Union[str, Tuple[str, Sequence[float]]]]], final_state: Sequence[Union[str, Tuple[str, Sequence[float]]]], mass_conservation_factor: Optional[float] = 3.0)Set[FrozenSet[str]][source]

Determine violated interaction rules for a given particle reaction.

Warning

This function only guarantees to find P, C and G parity violations, if it’s a two body decay. If all initial and final states have the C/G parity defined, then these violations are also determined correctly.

Parameters
  • initial_state – Shortform description of the initial state w/o spin projections.

  • final_state – Shortform description of the final state w/o spin projections.

  • mass_conservation_factor – Factor with which the width is multiplied when checking for MassConservation. Set to None in order to deactivate mass conservation.

Returns

Set of least violating rules. The set can have multiple entries, as several quantum numbers can be violated. Each entry in the frozenset represents a group of rules that together violate all possible quantum number configurations.

generate(initial_state: Union[str, Tuple[str, Sequence[float]], Sequence[Union[str, Tuple[str, Sequence[float]]]]], final_state: Sequence[Union[str, Tuple[str, Sequence[float]]]], allowed_intermediate_particles: Optional[List[str]] = None, allowed_interaction_types: Optional[Union[str, List[str]]] = None, formalism_type: str = 'helicity', particles: Optional[ParticleCollection] = None, mass_conservation_factor: Optional[float] = 3.0, topology_building: str = 'isobar', number_of_threads: Optional[int] = None)Result[source]

Generate allowed transitions between an initial and final state.

Serves as a facade to the StateTransitionManager (see Generate transitions).

Parameters
  • initial_state (list) – A list of particle names in the initial state. You can specify spin projections for these particles with a tuple, e.g. ("J/psi(1S)", [-1, 0, +1]). If spin projections are not specified, all projections are taken, so the example here would be equivalent to "J/psi(1S)".

  • final_state (list) – Same as initial_state, but for final state particles.

  • allowed_intermediate_particles (list, optional) – A list of particle states that you want to allow as intermediate states. This helps (1) filter out resonances in the eventual HelicityModel and (2) speed up computation time.

  • allowed_interaction_types (str, optional) – Interaction types you want to consider. For instance, both "strong and EM" and ["s", "em"] results in EM and STRONG.

  • formalism_type (str, optional) – Formalism that you intend to use in the eventual HelicityModel.

  • particles (ParticleCollection, optional) – The particles that you want to be involved in the reaction. Uses load_pdg by default. It’s better to use a subset for larger reactions, because of the computation times. This argument is especially useful when you want to use your own particle definitions (see Particle database).

  • mass_conservation_factor – Width factor that is taken into account for for the MassConservation rule.

  • topology_building (str) –

    Technique with which to build the Topology instances. Allowed values are:

    • "isobar": Isobar model (each state decays into two states)

    • "nbody": Use one central node and connect initial and final states to it

  • number_of_threads (int) – Number of cores with which to compute the allowed transitions. Defaults to all cores on the system.

An example (where, for illustrative purposes only, we specify all arguments) would be:

>>> import expertsystem as es
>>> result = es.reaction.generate(
...     initial_state="D0",
...     final_state=["K~0", "K+", "K-"],
...     allowed_intermediate_particles=["a(0)(980)", "a(2)(1320)-"],
...     allowed_interaction_types="ew",
...     formalism_type="helicity",
...     particles=es.reaction.load_pdg(),
...     topology_building="isobar",
... )
>>> len(result.transitions)
4

Submodules and Subpackages