J. Glister, Saint Mary's University
G. Ron, Tel Aviv University
B. W. Lee, Seoul National University
R. Gilman, Thomas Jefferson National Accelerator Facility
A. J. Sarty, Saint Mary's University
S. Strauch, University of South Carolina
D. W. Higinbotham, Thomas Jefferson National Accelerator Facility
E. Piasetzky, Tel Aviv University
K. Allada, University of Kentucky
W. Armstrong, Temple University
J. Arrington, Argonne National Laboratory
H. Arenhövel, Institut für Kenphysik
A. Beck, NRCN
F. Benmokhtar, University of Maryland
B. L. Berman, George Washington University
W. Boeglin, Florida International University
E. Brash, Christopher Newport University
A. Camsonne, Thomas Jefferson National Accelerator Facility
J. Calarco, University of New Hampshire
J. P. Chen, Thomas Jefferson National Accelerator Facility
S. Choi, Seoul National University
E. Chudakov, Thomas Jefferson National Accelerator Facility
L. Coman, University of Virginia
B. Craver, University of Virginia
F. Cusanno, INFN
J. Dumas, Rutgers
C. Dutta, University of South Carolina
R. Feuerbach, Thomas Jefferson National Accelerator Facility
A. Freyberger, Thomas Jefferson National Accelerator Facility
S. Frullani, INFN
F. Garibaldi, INFN
J. -O. Hansen, Thomas Jefferson National Accelerator Facility
T. Holmstrom, Longwood University
C. E. Hyde, Old Dominion UniversityFollow
H. Ibrahim, Old Dominion University
Y. Ilieva, George Washington University
C. W. de Jager, Thomas Jefferson National Accelerator Facility
X. Jiang, Rutgers, The State University of New Jersey
M. K. Jones, Thomas Jefferson National Accelerator Facility
Hyekoo Kang, Seoul National University
A. Kelleher, College of William and Mary
E. Khrosinkova, Kent State University
E. Kuchina, Rutgers
G. Kumbartzki, Rutgers
J. J. LeRose, Thomas Jefferson National Accelerator Facility
R. Lindgren, University of Virginia
P. Markowitz, Florida International University
S. May-Tal Beck, NRCN
E. McCullough, Saint Mary's University
D. Meekins, Thomas Jefferson National Accelerator Facility
M. Meziane, William & Mary
Z. -E. Meziani, Temple University
R. Michaels, Thomas Jefferson National Accelerator Facility
B. Moffit, William & Mary
B. E. Norum, University of Virginia - Main Campus
Y. Oh, Seoul National University
M. Olson, Saint Norbert College
M. Paolone, University of South Carolina
K. Paschke, University of Virginia
C. F. Perdrisat, William & Mary
M. Potokar, Saint Mary's University
R. Pomatsalyuk, University of Virginia
I. Pomerantz, Tel Aviv University
A. Puckett, Massachusetts Institute of Technology
V. Punjabi, Norfolk State University
X. Qian, Duke University
Y. Qiang, Massachusetts Institute of Technology
R. D. Ransome, Rutgers
M. Reyhan, Rutgers
J. Roche, Ohio University
Y. Rousseau, Rutgers
A. Saha, Thomas Jefferson National Accelerator Facility
B. Sawatzky, University of Virginia
E. Schulte, Rutgers
M. Schwamb, Institut für Kenphysik
M. Shabestari, University of Virginia
A. Shahinyan, Yerevan Physics Institute
R. Shneor, Tel Aviv University
S. Širca, Jožef Stefan Institute
K. Slifer, University of Virginia
P. Solvignon, Argonne National Laboratory
J. Song, Seoul National University
R. Sparks, Thomas Jefferson National Accelerator Facility
R. Subedi, Kent State University
G. M. Urciuoli, INFN
K. Wang, University of Virginia
B. Wojtsekhowski, Thomas Jefferson National Accelerator Facility
X. Yan, Seoul National University
H. Yao, Temple University
X. Zhan, Massachusetts Institute of Technology
X. Zhu, Duke University

Document Type

Article

Publication Date

2011

DOI

10.1016/j.physletb.2011.01.061

Publication Title

Physics Letters B

Volume

697

Issue

3

Pages

194-198

Abstract

High precision measurements of induced and transferred recoil proton polarization in d(γ→,p→)n have been performed for photon energies of 277–357 MeV and θcm = 20°–120°. The measurements were motivated by a longstanding discrepancy between meson–baryon model calculations and data at higher energies. At the low energies of this experiment, theory continues to fail to reproduce the data, indicating that either something is missing in the calculations and/or there is a problem with the accuracy of the nucleon–nucleon potential being used.

Rights

© 2011 The Authors. This manuscript version is made available under the CC-BY-NC-ND 4.0 license https://creativecommons.org/licenses/by-nc-nd/4.0/.

Open Access via SCOAP³.

Original Publication Citation

Glister, J., Ron, G., Lee, B. W., Gilman, R., Sarty, A. J., Strauch, S., Higinbotham, D. W., Piasetzky, E., Allada, K., Armstrong, W., Arrington, J., Arenhövel, H., Beck, A., Benmokhtar, F., Berman, B. L., Boeglin, W., Brash, E., Camsonne, A., Calarco, J.,…Zhu, X. (2011). Polarization observables in deuteron photodisintegration below 360 MeV. Physics Letters B, 697(3), 194-198. https://doi.org/https://doi.org/10.1016/j.physletb.2011.01.061

ORCID

0000-0001-7282-8120 (Hyde)

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