Experiment Overview¶
The pion occupies a special place in nature as one of the lightest hadrons, with one valence quark, and one valence antiquark. Small as it might be, the pion is also responsible for the long range character of the strong interaction that binds the atomic nucleus together. If chiral symmetry (left-right symmetry of rules governing strong interactions) were an exact global symmetry of strong interactions then pions would be massless. Through gluon-quark interaction and by explicit inclusion of light quark masses, chiral symmetry of massless QCD undergoes explicit symmetry breaking, thus giving the pion its mass. This puts the pion at the core of the mechanism that dynamically generates all the mass of the hadrons and makes it a crucial element in understanding hadron structure. E12-07-105 and E12-06-101 joint experiment allows for the measurement of the pion longitudinal and transverse separated cross section and pion form factor respectively at the highest Q 2 achievable at a 12 GeV Jefferson Lab. Carrying out this experiment at high values of Q2 can allow us to study nonperturbative dynamics of QCD wile also searching for a transition to the perturbative regime. In addition, the data obtained will provide us with information important in understanding reaction mechanisms and a benchmark for the models used to calculate the structure of light hadrons.
Data Analysis¶
- PionLT Physics Analysis List pionLT_physics_list.pdf
- Analysis Tasks
- JLab Farm Information
- Software Git Repos
- SIMC
- Hall C Analyzer
- Online Replay Histograms
- Joint Hall A & C Data Analysis
- L/T Separation Software (see Sec 4.2 of https://misportal.jlab.org/ul/publications/view_pub.cfm?pub_id=15234 for description)
- Alma9 Setup on ifarm
Meetings¶
- Hall C Commissioning Analysis Meetings
- Detector Working Group Meetings
- Pion LT Analysis Meetings
- Pion LT Meetings
- Pion LT Software Meetings
- BlueJeans Information
2022 Summer Run Information¶
- 2022_Run_Plans_and_Run_Sheets
- PionLT 2022 Physics Status
- PionLT Specific Shift Instructions
- Online Analysis Instructions
- Information for Shift Takers
- Documentation for Running Hall C
- Conduct of Operations
- Experimental Safety Assessment
- Radiation Safety Assessment
- Emergency Response Guidelines
- 2022 Beam Schedule
- 2022 Shift Signup
- 2022 Shift Signup, read only
- Hall C How-Tos: 1 , 2
- Analysis on Cdaq
- Contact Experts
- Target Configuration
- Special low current BCM calibration
2021 Fall Run Information¶
- 2021 Run Plans and Run Sheets
- PionLT 2021 Physics Status
- PionLT Specific Shift Instructions
- Online Analysis Instructions
- Information for Shift Takers
- Documentation for Running Hall C
- Conduct of Operations
- Experimental Safety Assessment
- Radiation Safety Assessment
- Emergency Response Guidelines
- 2021 Beam Schedule
- 2021 Shift Signup
- 2021 Shift Signup, read only
- Hall C How-Tos: 1 , 2
- Analysis on Cdaq
- Contact Experts
- Target Configuration
- Fall 2021 Trigger Configuration
2019 Summer Run Information¶
- 2019 Run Plans and Run Sheets
- PionLT 2019 Physics Status
- PionLT Specific Shift Instructions
- Online Analysis Instructions
- Summer 2019 Experimental Safety Assessment
- Summer 2019 Conduct of Operations
- Information for Shift Takers
- Documentation for Running Hall C
- 2019 Beam Schedule
- 2019 Shift Signup
- 2019 Shift Signup, read only
- Hall C How-Tos: 1 , 2
- Analysis on Cdaq
- Contact Experts
- Fall 2018-Summer 2019 Trigger Configurations
Collaboration¶
PAC Documents¶
- Proposals:
KaonLT¶
Updated by Muhammad Junaid 5 months ago ยท 134 revisions