Difference between revisions of "Resonant Polarimeter"
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= Meetings and Discussion = | = Meetings and Discussion = | ||
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+ | * Richard Talman's Stern-Gerlach report on (August 3, 2016): [[media:ResPolTest_Talman_03August2016.pdf]] – Updated the signal power estimate [[media:Revised-p14.pdf]] | ||
* Brock's progress on the 2.495 MHz I/Q receiver (August 3, 2016): [[media:Brock_Receiver_03August2016.JPG]] | * Brock's progress on the 2.495 MHz I/Q receiver (August 3, 2016): [[media:Brock_Receiver_03August2016.JPG]] | ||
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* Richard Talman's SLAC seminar (July 21, 2016): [[media:Talman_seminar_SLAC-July2016.pdf]] | * Richard Talman's SLAC seminar (July 21, 2016): [[media:Talman_seminar_SLAC-July2016.pdf]] |
Revision as of 14:48, 3 August 2016
Resonant polarimetry, first proposed by Derbenev in 1993, measures the spin-dependent energy deposited by a beam in cavity via the Stern-Gerlach interaction. This technique of fast non-destructive measurement of beam polarization has been never demonstrated experimentally. We are planning a proof-of-principle test using polarized electrons and a room temperature copper cavity.
Meetings and Discussion
- Richard Talman's Stern-Gerlach report on (August 3, 2016): media:ResPolTest_Talman_03August2016.pdf – Updated the signal power estimate media:Revised-p14.pdf
- Brock's progress on the 2.495 MHz I/Q receiver (August 3, 2016): media:Brock_Receiver_03August2016.JPG
- Richard Talman's SLAC seminar (July 21, 2016): media:Talman_seminar_SLAC-July2016.pdf
- Richard Talman's thoughts on resonant polarimetry (June 1, 2016): media:Talman_Stern_Gerlach_Resonance_Polarimeter.pdf
- Brock's prototype (June 9, 2016): media:Brock_resonant_cavity_prototype.jpg
- Brock's idea (April 27, 2016): media:Brock's_schematic.docx
- Local meeting with Juelich, Bonn and Cornell visitors to discuss resonant polarimeter (February 3-5, 2016): https://www.jlab.org/indico/event/142/
References
- The Stern-Gerlach interaction between a traveling particle and a time varying magnetic field
M. Conte, M. Ferro, G. Gemme, W.W. MacKay, R. Parodi, M. Pusterla, arXiv:physics/0003069v1 (March 24, 2000): [1] media:arXiv_physics_0003069v1.pdf
- Relativistic Stern-Gerlach Interaction in an RF Cavity
M. Conte, A. U. Luccio, and M. Pusterla, arXiv:physics/0907.2161v1 (February 22, 2013): [2] media:arXiv_physics_0907.2161v1.pdf
- RF-resonance beam polarimeter Part I. Fundamental concepts
Ya. S. Derbenev, Nucl. Inst. Meth. A 336, 12 (1993): [3] media:NuclInstMethA.336.12.pdf
- Lorentz Transform of an Arbitrary Force Field Acting on a Particle in its Rest Frame, using the Hamilton-Lagrangian Formalism
C. Tschalär, BIR#15-01, Bates Lab Report (June 24, 2016): media:Tschaller_Tech_Note_B-IR.pdf
- Proposal for a cavity polarimeter at MIT-Bates
P. Cameron et al., Proceedings of the Particle Accelerator Conference, Chicago (2001): [4] media:BATES_PAC2001.00987396.pdf
- Measuring the intensity and position of a pA electron beam with resonant cavities
Thorsten R. Pusch, F. Frommberger, W. C. A. Hillert, and B. Neff, Phys. Rev. ST Accel. Beams 15, 112801 (2012): [5] media:PhysRevSTAB.15.112801.pdf