Difference between revisions of "Resonant Polarimeter"

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Ronald Lorenz, DESY Zeuthen, Platanenallee 6, D-15738 Zeuthen: [[media:lorenz_CBPM.pdf]]
 
Ronald Lorenz, DESY Zeuthen, Platanenallee 6, D-15738 Zeuthen: [[media:lorenz_CBPM.pdf]]
  
* Measuring the intensity and position of a pA electron beam with resonant cavities''
+
* ''Measuring the intensity and position of a pA electron beam with resonant cavities''
T. Pusch et al., PRST-AB 15, 112801, 2012
+
T. Pusch et al., Phys. Rev. Accel. Beams '''15''', 112801 (2012): [https://doi.org/10.1103/PhysRevSTAB.15.112801] [[media:PhysRevSTAB.15.112801.pdf]]
  
 
* ''Direct demoonstration of the transverse Stern-Gerlach effect''
 
* ''Direct demoonstration of the transverse Stern-Gerlach effect''
 
J. Porter, R. Pettifer, and D. Leadly, American Journal of Physics, 71, 1103, 2003
 
J. Porter, R. Pettifer, and D. Leadly, American Journal of Physics, 71, 1103, 2003

Revision as of 09:51, 10 January 2017

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.


 Phone number: 1-888-240-2560
 Meeting ID: 149332993#
 Meeting URL: http://bluejeans.com/149332993

Meetings and Discussion

  • Sateesh Mane, "Relativistic Stern-Gerlach Deflection: Hamiltonian Formulation", arXiv:1611.07326v1 [Accelerator Physics] (November 22, 2016): [1] media:1611.07326v1.pdf
  • Richard Talman's final Spin 2016 paper (November 16, 2016):
media:Talman_Spin2016-paper_final_16Nov2016.pdf
A theoretical paper, arXiv:1611.03810v1 [Accelerator Physics] : [2] media:RelativisticStern-Gerlach_16Nov2016.pdf
  • Richard Talman's talk at SPIN 2016: [3]
  • Richard Talman, The CEBAF Injection Line as Stern-Gerlach Polarimeter, Spin 2016 Conference (September 22, 2016):
Abstract: media:Talman_SG_Polarimeter_Spin2016_abstract.txt
Paper: media:Talman_SG_Polarimeter_Spin2016.pdf
Beam Position Monitors (Peter Forck, Piotr Kowina, Dmitry Liakin - GSI, Darmstadt, Germany): media:Cas_bpm_main.pdf


References

  • On Stern-Gerlach forces allowed by special relativity and the special case of the classical spinning particle of Derbenev-Kondratenko

K. Heinemann, arXiv:9611001v1 [physics] (July 22, 2013): [4] media:9611001.pdf

  • Stern-Gerlach Forces and Spin Splitters

D. P. Barber, AIP Conf. Proc. 1008, 56 (2008) (29–31 August 2007): [5] media:Barber_SG_1.2932267.pdf

  • Polarization kinetics of particles in storage rings

Ya. S. Derbenev, A.M. Kondratenko, Sov. Phys. JETP, 37, p.968 (1973): [6] media:e_037_06_0968.pdf

  • 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:0003069v1 [physics] (March 24, 2000): [7] 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): [8] media:arXiv_physics_0907.2161v1.pdf

  • RF-resonance beam polarimeter Part I. Fundamental concepts

Ya. S. Derbenev, Nucl. Inst. Meth. A 336, 12 (1993): [9] 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): [10] 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): [11] media:PhysRevSTAB.15.112801.pdf

  • Single-Shot MeV Transmission Electron Microscopy with Picosecond Temporal Resolution

R. K. Li and P. Musumeci, Phys. Rev. Applied 2, 024003 (2014): [12] media:PhysRevApplied.2.024003.pdf

  • Development of a high-resolution cavity-beam position monitor

Y. Inoue et al., Phys. Rev. ST Accel. Beams 11, 062801 (2008): [13] media:PhysRevSTAB.11.062801.pdf

  • Performance of a high resolution cavity beam position monitor system

S. Walston, Nucl. Inst. Meth A 578, 1 (2008): [14] media:NuclInstMethA.578.1.pdf

  • Development of a cavity-type beam position monitor with high resolution for ATF2

S. Jang et al., Proceedings of IPAC2013, Shanghai, China, 2013: media:mopme058.pdf

  • Multiple harmonic frequencies resonant cavity design and half-scale prototype measurements for a fast kicker

Y. Huang et al., Phys. Rev. Accel. Beams 19, 122001 (2016): [15] media:PhysRevAccelBeams.19.122001.pdf

  • Cavity Beam Position Monitors

Ronald Lorenz, DESY Zeuthen, Platanenallee 6, D-15738 Zeuthen: media:lorenz_CBPM.pdf

  • Measuring the intensity and position of a pA electron beam with resonant cavities

T. Pusch et al., Phys. Rev. Accel. Beams 15, 112801 (2012): [16] media:PhysRevSTAB.15.112801.pdf

  • Direct demoonstration of the transverse Stern-Gerlach effect

J. Porter, R. Pettifer, and D. Leadly, American Journal of Physics, 71, 1103, 2003