Difference between revisions of "July 7, 2009 (11AM), Physics Simulations"
| Line 19: | Line 19: | ||
<i>Reaction:</i><br/> | <i>Reaction:</i><br/> | ||
| − | γ p --> pi+ pi+ pi- n | + | γ p --> π<sup>+</sup> π<sup>+</sup> π<sup>-</sup> n |
<i>Purpose:</i><br/> | <i>Purpose:</i><br/> | ||
| Line 36: | Line 36: | ||
<i>Purpose:</i><br/> | <i>Purpose:</i><br/> | ||
-- Look at "golden mode" final states involving many tracks.<br/> | -- Look at "golden mode" final states involving many tracks.<br/> | ||
| − | -- Update old simulations of the | + | -- Update old simulations of the 8γ final state and compare to the more realistic cases when tracks are used.<br/> |
Latest revision as of 11:05, 15 July 2009
Organizational meeting with Blake, Jake, and Seema.
Meson spectroscopy simulation work has been divided up into several pieces:
Blake:
Reaction:
γ p → η π0 p (η → γ γ)
Purpose:
-- Use the full calorimeter reconstruction code to study acceptances and resolutions.
-- Start thinking about how to use the recoil proton (e.g. Blake developed code to match tracks and showers).
-- Explore backgrounds.
-- Study PWA systematics.
Jake:
Reaction:
γ p --> π+ π+ π- n
Purpose:
-- Use HDParSim to study an all-charged track final state.
-- What can we do with the neutron? (e.g., start thinking about missing mass resolutions)
-- Study PWA systematics in the 3-pi system, a final state IU has studied with E852.
Seema:
Reaction:
γ p → b1 π+ n
γ p → f1 π+ n
(where b1 and f1 decay to charged particles).
Purpose:
-- Look at "golden mode" final states involving many tracks.
-- Update old simulations of the 8γ final state and compare to the more realistic cases when tracks are used.
