Difference between revisions of "CPS Summary 1/23/18"
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| + | COMPACT PHOTON SOURCE: SCIENCE OPPORTUNITIES AND CONCEPT | ||
| + | |||
| + | * Polarized Wide Angle Compton Scattering - much interesting science, but limitation in current for target (90nA electron beam) | ||
| + | |||
| + | * CPS concept: dump electrons and use photons (bremsstrahlung) | ||
| + | |||
| + | * CPS challenge is to control radiation, but our studies have shown that is works! - photon flux is ~30 times higher (equivalent photon rate 1x10^12 gamma/s) and opens a new range of polarized physics opportunities at JLab | ||
| + | |||
| + | * CPS details: | ||
| + | ::* magnet with tapered pole gap, radiation hard, space between poles filled with copper (Cu core), main shielding is tungsten powder | ||
| + | ::* shielding logic: design so that have radiation dose comparable to that with that of number of photons on target | ||
| + | |||
| + | * Discussion of CPS simulation results | ||
| + | ::* comparative study of 90nA electron beam and a pure photon beam producded from 2.7nA electron beam on a 10% radiator (CPS) | ||
| + | ::* Studies included: heat load on target, accumulated damage from neutron/photon, activation dose rate around the target, impact of CPS (radiation and damage due to CPS) | ||
| + | ::* Result of simulation studies show that CPS concept design works. Some additional shielding in backward region is needed to keep the dose rate <5mrem/hr - currently have 100 mrem/hr in the backward region. Additional shielding may affect placement of diagnostics girder and instrumentation | ||
| + | |||
| + | |||
ROTATING TARGET | ROTATING TARGET | ||
| Line 21: | Line 39: | ||
::* for proposal may include for CPS: tagger area, first engineering changes for Hall D, simulations with CPS only | ::* for proposal may include for CPS: tagger area, first engineering changes for Hall D, simulations with CPS only | ||
::* evaluate different configurations for different number of days to address questions about required beam time | ::* evaluate different configurations for different number of days to address questions about required beam time | ||
| + | |||
| + | |||
| + | DISCUSSION ABOUT ACTION ITEMS | ||
| + | |||
| + | * Remove condition from polarized WACS experiment | ||
| + | ::* requires a lab internal review | ||
| + | ::* aim is to have the required documentation from PAC by November 2018, so CPS collaboration has to have the document ready in ~5 months from January 2018 | ||
| + | |||
| + | * Get PAC approval for KLong experiment | ||
| + | ::* need documentation of basic CPS features by June | ||
| + | |||
| + | * To be done for CPS HC in next 6-9 weeks: | ||
| + | ::* Add polarized target and check shielding optimization, e.g. how much W and how much Pb etc. | ||
| + | ::* Determine what engineering items to include in internal review document, e.g., temperature, pressure drop, power | ||
| + | ::* Meet every 3 weeks | ||
Revision as of 19:02, 28 January 2018
COMPACT PHOTON SOURCE: SCIENCE OPPORTUNITIES AND CONCEPT
- Polarized Wide Angle Compton Scattering - much interesting science, but limitation in current for target (90nA electron beam)
- CPS concept: dump electrons and use photons (bremsstrahlung)
- CPS challenge is to control radiation, but our studies have shown that is works! - photon flux is ~30 times higher (equivalent photon rate 1x10^12 gamma/s) and opens a new range of polarized physics opportunities at JLab
- CPS details:
- magnet with tapered pole gap, radiation hard, space between poles filled with copper (Cu core), main shielding is tungsten powder
- shielding logic: design so that have radiation dose comparable to that with that of number of photons on target
- Discussion of CPS simulation results
- comparative study of 90nA electron beam and a pure photon beam producded from 2.7nA electron beam on a 10% radiator (CPS)
- Studies included: heat load on target, accumulated damage from neutron/photon, activation dose rate around the target, impact of CPS (radiation and damage due to CPS)
- Result of simulation studies show that CPS concept design works. Some additional shielding in backward region is needed to keep the dose rate <5mrem/hr - currently have 100 mrem/hr in the backward region. Additional shielding may affect placement of diagnostics girder and instrumentation
ROTATING TARGET
- Discussion about rotation scheme and mechanical movement and material
PION-KAON PHYSICS
- Discussion about new physics with a K-long beam
K-LONG BEAM EXPERIMENT
- Experiment will access KLp --> Ksp and KLp --> pi+Lambda at a KL rate of 10^4 KL/s - this is 2500 times SLAC
- Main background is from neutrons, key goal for radcon is a dose rate of 1mrem/hr at the ceiling above the Gluex detector
- Discussion about the number of days required (currently 100 days in proposal)
- Next steps:
- get PAC approval
- for proposal may include for CPS: tagger area, first engineering changes for Hall D, simulations with CPS only
- evaluate different configurations for different number of days to address questions about required beam time
DISCUSSION ABOUT ACTION ITEMS
- Remove condition from polarized WACS experiment
- requires a lab internal review
- aim is to have the required documentation from PAC by November 2018, so CPS collaboration has to have the document ready in ~5 months from January 2018
- Get PAC approval for KLong experiment
- need documentation of basic CPS features by June
- To be done for CPS HC in next 6-9 weeks:
- Add polarized target and check shielding optimization, e.g. how much W and how much Pb etc.
- Determine what engineering items to include in internal review document, e.g., temperature, pressure drop, power
- Meet every 3 weeks