Your search keyword '"Plonka-Spehr, C."' showing total 37 results

1. Measurement of the permanent electric dipole moment of the neutron

Author

Abel, C., Afach, S., Ayres, N. J., Baker, C. A., Ban, G., Bison, G., Bodek, K., Bondar, V., Burghoff, M., Chanel, E., Chowdhuri, Z., Chiu, P. -J., Clement, B., Crawford, C. B., Daum, M., Emmenegger, S., Ferraris-Bouchez, L., Fertl, M., Flaux, P., Franke, B., Fratangelo, A., Geltenbort, P., Green, K., Griffith, W. C., van der Grinten, M., Grujić, Z. D., Harris, P. G., Hayen, L., Heil, W., Henneck, R., Hélaine, V., Hild, N., Hodge, Z., Horras, M., Iaydjiev, P., Ivanov, S. N., Kasprzak, M., Kermaidic, Y., Kirch, K., Knecht, A., Knowles, P., Koch, H. -C., Koss, P. A., Komposch, S., Kozela, A., Kraft, A., Krempel, J., Kuźniak, M., Lauss, B., Lefort, T., Lemière, Y., Leredde, A., Mohanmurthy, P., Mtchedlishvili, A., Musgrave, M., Naviliat-Cuncic, O., Pais, D., Piegsa, F. M., Pierre, E., Pignol, G., Plonka-Spehr, C., Prashanth, P. N., Quéméner, G., Rawlik, M., Rebreyend, D., Rienäcker, I., Ries, D., Roccia, S., Rogel, G., Rozpedzik, D., Schnabel, A., Schmidt-Wellenburg, P., Severijns, N., Shiers, D., Dinani, R. Tavakoli, Thorne, J. A., Virot, R., Voigt, J., Weis, A., Wursten, E., Wyszynski, G., Zejma, J., Zenner, J., and Zsigmond, G.

Subjects

High Energy Physics - Experiment, Nuclear Experiment, Physics - Instrumentation and Detectors

Abstract

We present the result of an experiment to measure the electric dipole moment (EDM) of the neutron at the Paul Scherrer Institute using Ramsey's method of separated oscillating magnetic fields with ultracold neutrons (UCN). Our measurement stands in the long history of EDM experiments probing physics violating time reversal invariance. The salient features of this experiment were the use of a Hg-199 co-magnetometer and an array of optically pumped cesium vapor magnetometers to cancel and correct for magnetic field changes. The statistical analysis was performed on blinded datasets by two separate groups while the estimation of systematic effects profited from an unprecedented knowledge of the magnetic field. The measured value of the neutron EDM is $d_{\rm n} = (0.0\pm1.1_{\rm stat}\pm0.2_{\rm sys})\times10^{-26}e\,{\rm cm}$., Comment: 5 pages, 4 figures, submitted to PRL on 18.12.2019

Published

2020

2. Gravitational Depolarization of Ultracold Neutrons: Comparison with Data

Author

Afach, S., Ayres, N. J., Baker, C. A., Ban, G., Bison, G., Bodek, K., Fertl, M., Franke, B., Geltenbort, P., Green, K., Griffith, W. C., van der Grinten, M., Grujic, Z. D., Harris, P. G., Heil, W., Helaine, V., Iaydjiev, P., Ivanov, S. N., Kasprzak, M., Kermaidic, Y., Kirch, K., Koch, H. -C., Komposch, S., Kozela, A., Krempel, J., Lauss, B., Lefort, T., Lemiere, Y., Musgrave, M., Naviliat-Cunic, O., Pendlebury, J. M., Piegsa, F. M., Pignol, G., Plonka-Spehr, C., Prashanth, P. N., Quemener, G., Rawlik, M., Rebreyend, D., Ries, D., Roccia, S., Rozpedzik, D., Schmidt-Wellenburg, P., Severijns, N., Shiers, D., Thorne, J. A., Weis, A., Wursten, E., Zejma, J., Zenner, J., and Zsigmond, G.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

We compare the expected effects of so-called gravitationally enhanced depolarization of ultracold neutrons to measurements carried out in a spin-precession chamber exposed to a variety of vertical magnetic-field gradients. In particular, we have investigated the dependence upon these field gradients of spin depolarization rates and also of shifts in the measured neutron Larmor precession frequency. We find excellent qualitative agreement, with gravitationally enhanced depolarization accounting for several previously unexplained features in the data., Comment: 10 pages, 6 figures. Updated: section added about implications for current nEDM limit

Published

2015

3. Observation of gravitationally induced vertical striation of polarized ultracold neutrons by spin-echo spectroscopy

Author

Afach, S., Ayres, N. J., Ban, G., Bison, G., Bodek, K., Chowdhuri, Z., Daum, M., Fertl, M., Franke, B., Griffith, W. C., Grujić, Z. D., Harris, P. G., Heil, W., Hélaine, V., Kasprzak, M., Kermaidic, Y., Kirch, K., Knowles, P., Koch, H. -C., Komposch, S., Kozela, A., Krempel, J., Lauss, B., Lefort, T., Lemière, Y., Mtchedlishvili, A., Musgrave, M., Naviliat-Cuncic, O., Pendlebury, J. M., Piegsa, F. M., Pignol, G., Plonka-Spehr, C., Prashanth, P. N., Quéméner, G., Rawlik, M., Rebreyend, D., Ries, D., Roccia, S., Rozpedzik, D., Schmidt-Wellenburg, P., Severijns, N., Thorne, J. A., Weis, A., Wursten, E., Wyszynski, G., Zejma, J., Zenner, J., and Zsigmond, G.

Subjects

Physics - Instrumentation and Detectors, Nuclear Experiment

Abstract

We describe a spin-echo method for ultracold neutrons (UCNs) confined in a precession chamber and exposed to a $|B_0|=1~\text{\mu T}$ magnetic field. We have demonstrated that the analysis of UCN spin-echo resonance signals in combination with knowledge of the ambient magnetic field provides an excellent method by which to reconstruct the energy spectrum of a confined ensemble of neutrons. The method takes advantage of the relative dephasing of spins arising from a gravitationally induced striation of stored UCN of different energies, and also permits an improved determination of the vertical magnetic-field gradient with an exceptional accuracy of $1.1~\text{pT/cm}$. This novel combination of a well-known nuclear resonance method and gravitationally induced vertical striation is unique in the realm of nuclear and particle physics and should prove to be invaluable for the assessment of systematic effects in precision experiments such as searches for an electric dipole moment of the neutron or the measurement of the neutron lifetime., Comment: 7 pages 5 figures, accepted by PRL, September, 08 2015

Published

2015

4. Dynamic stabilization of the magnetic field surrounding the neutron electric dipole moment spectrometer at the Paul Scherrer Institute

Author

Afach, S., Bison, G., Bodek, K., Burri, F., Chowdhuri, Z., Daum, M., Fertl, M., Franke, B., Grujic, Z., Helaine, V., Henneck, R., Kasprzak, M., Kirch, K., Koch, H. -C., Kozela, A., Krempel, J., Lauss, B., Lefort, T., Lemiere, Y., Meier, M., Naviliat-Cuncic, O., Piegsa, F. M., Pignol, G., Plonka-Spehr, C., Prashanth, P. N., Quemener, G., Rebreyend, D., Roccia, S., Schmidt-Wellenburg, P., Schnabel, A., Severijns, N., Voigt, J., Weis, A., Wyszynski, G., Zejma, J., Zenner, J., and Zsigmond, G.

Subjects

Physics - Instrumentation and Detectors, Nuclear Experiment, Physics - Atomic Physics

Abstract

The Surrounding Field Compensation (SFC) system described in this work is installed around the four-layer Mu-metal magnetic shield of the neutron electric dipole moment spectrometer located at the Paul Scherrer Institute. The SFC system reduces the DC component of the external magnetic field by a factor of about 20. Within a control volume of approximately 2.5m x 2.5m x 3m disturbances of the magnetic field are attenuated by factors of 5 to 50 at a bandwidth from $10^{-3}$ Hz up to 0.5 Hz, which corresponds to integration times longer than several hundreds of seconds and represent the important timescale for the nEDM measurement. These shielding factors apply to random environmental noise from arbitrary sources. This is achieved via a proportional-integral feedback stabilization system that includes a regularized pseudoinverse matrix of proportionality factors which correlates magnetic field changes at all sensor positions to current changes in the SFC coils., Comment: 33 pages, 18 figures

Published

2014

5. An Improved Search for the Neutron Electric Dipole Moment

Author

Burghoff, M., Schnabel, A., Ban, G., Lefort, T., Lemiere, Y., Naviliat-Cuncic, O., Pierre, E., Quemener, G., Zejma, J., Kasprzak, M., Knowles, P., Weis, A., Pignol, G., Rebreyend, D., Afach, S., Bison, G., Becker, J., Severijns, N., Roccia, S., Plonka-Spehr, C., Zennerz, J., Heil, W., Koch, H. C., Kraft, A., Lauer, T., Sobolev, Yu., Chowdhuri, Z., Krempel, J., Lauss, B., Mtchedlishvili, A., Schmidt-Wellenburg, P., Zsigmond, G., Fertl, M., Franke, B., Horras, M., Kirch, K., and Piegsa, F.

Subjects

Nuclear Experiment, Physics - Instrumentation and Detectors

Abstract

A permanent electric dipole moment of fundamental spin-1/2 particles violates both parity (P) and time re- versal (T) symmetry, and hence, also charge-parity (CP) symmetry since there is no sign of CPT-violation. The search for a neutron electric dipole moment (nEDM) probes CP violation within and beyond the Stan- dard Model. The experiment, set up at the Paul Scherrer Institute (PSI), an improved, upgraded version of the apparatus which provided the current best experimental limit, dn < 2.9E-26 ecm (90% C.L.), by the RAL/Sussex/ILL collaboration: Baker et al., Phys. Rev. Lett. 97, 131801 (2006). In the next two years we aim to improve the sensitivity of the apparatus to sigma(dn) = 2.6E-27 ecm corresponding to an upper limit of dn < 5E-27 ecm (95% C.L.), in case for a null result. In parallel the collaboration works on the design of a new apparatus to further increase the sensitivity to sigma(dn) = 2.6E-28 ecm., Comment: APS Division for particles and fields, Conference Proceedings, Two figures

Published

2011

6. Diffraction of slow neutrons by holographic SiO_2 nanoparticle-polymer composite gratings

Author

Klepp, J., Pruner, C., Tomita, Y., Plonka-Spehr, C., Geltenbort, P., Ivanov, S., Manzin, G., Andersen, K. H., Kohlbrecher, J., Ellabban, M. A., and Fally, M.

Subjects

Condensed Matter - Materials Science, Physics - Instrumentation and Detectors

Abstract

Diffraction experiments with holographic gratings recorded in SiO$_2$ nanoparticle-polymer composites have been carried out with slow neutrons. The influence of parameters such as nanoparticle concentration, grating thickness and grating spacing on the neutron-optical properties of such materials has been tested. Decay of the grating structure along the sample depth due to disturbance of the recording process becomes an issue at grating thicknesses of about 100 microns and larger. This limits the achievable diffraction efficiency for neutrons. As a solution to this problem, the Pendell\"{o}sung interference effect in holographic gratings has been exploited to reach a diffraction efficiency of 83% for very cold neutrons., Comment: 7 pages, 3 figures, submitted to Phys. Rev. A

Published

2011

7. An optical device for ultra-cold neutrons - Investigation of systematic effects and applications

Author

Plonka-Spehr, C., Kraft, A., Iaydjiev, P., Klepp, J., Nesvizhevsky, V., Geltenbort, P., and Lauer, Th.

Subjects

Physics - Instrumentation and Detectors

Abstract

We developed an optical device for ultra-cold neutrons and investigated the influence of a tilt of its guiding components. A measurement of the time-of-flight of the neutrons through the device by means of a dedicated chopper system was performed and a light-optical method for the alignment of the guiding components is demonstrated. A comparative analysis of former experiments with our results shows the potential of such a device to test the electrical neutrality of the free neutron on the $10^{-22} q_{\rm e}$ level and to investigate the interaction of neutrons with gravity.

Published

2009

8. Neutron to Mirror-Neutron Oscillations in the Presence of Mirror Magnetic Fields

Author

Altarev, I., Baker, C. A., Ban, G., Bodek, K., Daum, M., Fierlinger, P., Geltenbort, P., Green, K., van der Grinten, M. G. D., Gutsmiedl, E., Harris, P. G., Henneck, R., Horras, M., Iaydjiev, P., Ivanov, S., Khomutov, N., Kirch, K., Kistryn, S., Knecht, A., Knowles, P., Kozela, A., Kuchler, F., Kuźniak, M., Lauer, T., Lauss, B., Lefort, T., Mtchedlishvili, A., Naviliat-Cuncic, O., Paul, S., Pazgalev, A., Pendlebury, J. M., Petzoldt, G., Pierre, E., Plonka-Spehr, C., Quéméner, G., Rebreyend, D., Roccia, S., Rogel, G., Severijns, N., Shiers, D., Sobolev, Yu., Stoepler, R., Weis, A., Zejma, J., Zenner, J., and Zsigmond, G.

Subjects

Nuclear Experiment

Abstract

We performed ultracold neutron (UCN) storage measurements to search for additional losses due to neutron (n) to mirror-neutron (n') oscillations as a function of an applied magnetic field B. In the presence of a mirror magnetic field B', UCN losses would be maximal for B = B'. We did not observe any indication for nn' oscillations and placed a lower limit on the oscillation time of tau_{nn'} > 12.0 s at 95% C.L. for any B' between 0 and 12.5 uT., Comment: 4 pages, 2 figures. Accepted for publication in Phys. Rev. D

Published

2009

9. Experimental demonstration of the stability of Berry's phase for a spin-1/2 particle

Author

Filipp, S., Klepp, J., Hasegawa, Y., Plonka-Spehr, C., Schmidt, U., Geltenbort, P., and Rauch, H.

Subjects

Quantum Physics

Abstract

The geometric phase has been proposed as a candidate for noise resilient coherent manipulation of fragile quantum systems. Since it is determined only by the path of the quantum state, the presence of noise fluctuations affects the geometric phase in a different way than the dynamical phase. We have experimentally tested the robustness of Berry's geometric phase for spin-1/2 particles in a cyclically varying magnetic field. Using trapped polarized ultra-cold neutrons it is demonstrated that the geometric phase contributions to dephasing due to adiabatic field fluctuations vanish for long evolution times., Comment: 4 pages, 4 figures

Published

2008

10. An Improved Neutron Electric Dipole Moment Experiment

Author

Kuźniak, M., Altarev, I., Ban, G., Bison, G., Bodek, K., Burghoff, M., Daum, M., Eberhardt, K., Fierlinger, P., Gutsmiedl, E., Hampel, G., Heil, W., Henneck, R., Khomutov, N., Kirch, K., Kistryn, St., Knappe-Grueneberg, S., Knecht, A., Knowles, P., Kratz, J. V., Lauer, T., Lauss, B., Lefort, T., Mtchedlishvili, A., Naviliat-Cuncic, O., Paul, S., Pazgalev, A. S., Petzold, G., Plonka-Spehr, C., Quéméner, G., Rebreyend, D., Roccia, S., Rogel, G., Sander-Thoemmes, T., Schnabel, A., Severijns, N., Sobolev, Yu., Stoepler, R., Trahms, L., Tur, M., Weis, A., Wiehl, N., Zejma, J., and Zsigmond, G.

Subjects

Nuclear Experiment

Abstract

A new measurement of the neutron EDM, using Ramsey's method of separated oscillatory fields, is in preparation at the new high intensity source of ultra-cold neutrons (UCN) at the Paul Scherrer Institute, Villigen, Switzerland (PSI). The existence of a non-zero nEDM would violate both parity and time reversal symmetry and, given the CPT theorem, might lead to a discovery of new CP violating mechanisms. Already the current upper limit for the nEDM (|d_n|<2.9E-26 e.cm) constrains some extensions of the Standard Model. The new experiment aims at a two orders of magnitude reduction of the experimental uncertainty, to be achieved mainly by (1) the higher UCN flux provided by the new PSI source, (2) better magnetic field control with improved magnetometry and (3) a double chamber configuration with opposite electric field directions. The first stage of the experiment will use an upgrade of the RAL/Sussex/ILL group's apparatus (which has produced the current best result) moved from Institut Laue-Langevin to PSI. The final accuracy will be achieved in a further step with a new spectrometer, presently in the design phase., Comment: Flavor Physics & CP Violation Conference, Taipei, 2008

Published

2008

11. Improved instrument for the determination of the neutron electric charge

Author

Siemensen, C., Brose, D., Böhmer, L., Geltenbort, P., and Plonka-Spehr, C.

Published

2015

12. An improved measurement of the electric dipole moment of the neutron

Author

Altarev, I., Ban, G., Bison, G., Bodek, K., Burghoff, M., Chowdhuri, Z., Daum, M., Düsing, C., Fertl, M., Fierlinger, P., Franke, B., Grab, C., Gutsmiedl, E., Hampel, G., Heil, W., Henneck, R., Horras, M., Khomutov, N., Kirch, K., Kistryn, S., Knappe-Grüneberg, S., Knecht, A., Knowles, P., Kozela, A., Kraft, A., Kuchler, F., Kratz, J.V., Lauer, T., Lauss, B., Lefort, T., Lemiere, Y., Mtchedlishvili, A., Naviliat-Cuncic, O., Quéméner, G., Paul, S., Pazgalev, A.S., Petzoldt, G., Plonka-Spehr, C., Pierre, E., Pignol, G., Rebreyend, D., Roccia, S., Rogel, G., Schmidt-Wellenburg, P., Schnabel, A., Severijns, N., Sobolev, Yu., Stoepler, R., Weis, A., Wiehl, N., Zejma, J., Zenner, J., and Zsigmond, G.

Published

2010

13. An optical device for ultra-cold neutrons—Investigation of systematic effects and applications

Author

Plonka-Spehr, C., Kraft, A., Iaydjiev, P., Klepp, J., Nesvizhevsky, V.V., Geltenbort, P., and Lauer, Th.

Published

2010

14. Additional results from the first dedicated search for neutron–mirror neutron oscillations

Author

Bodek, K., Kistryn, St., Kuźniak, M., Zejma, J., Burghoff, M., Knappe-Grüneberg, S., Sander-Thoemmes, T., Schnabel, A., Trahms, L., Ban, G., Lefort, T., Naviliat-Cuncic, O., Khomutov, N., Knowles, P., Pazgalev, A.S., Weis, A., Rogel, G., Quéméner, G., Rebreyend, D., Roccia, S., Bison, G., Severijns, N., Eberhardt, K., Hampel, G., Heil, W., Kratz, J.V., Lauer, T., Plonka-Spehr, C., Sobolev, Yu., Wiehl, N., Altarev, I., Fierlinger, P., Gutsmiedl, E., Paul, S., Stoepler, R., Daum, M., Henneck, R., Kirch, K., Knecht, A., Lauss, B., Mtchedlishvili, A., Petzoldt, G., and Zsigmond, G.

Published

2009

15. Towards a new measurement of the neutron electric dipole moment

Author

Altarev, I., Ban, G., Bison, G., Bodek, K., Burghoff, M., Cvijovic, M., Daum, M., Fierlinger, P., Gutsmiedl, E., Hampel, G., Heil, W., Henneck, R., Horras, M., Khomutov, N., Kirch, K., Kistryn, St., Knappe-Grüneberg, S., Knecht, A., Knowles, P., Kozela, A., Kratz, J.V., Kuchler, F., Kuźniak, M., Lauer, T., Lauss, B., Lefort, T., Mtchedlishvili, A., Naviliat-Cuncic, O., Paul, S., Pazgalev, A.S., Petzoldt, G., Pierre, E., Plonka-Spehr, C., Quéméner, G., Rebreyend, D., Roccia, S., Rogel, G., Sander-Thoemmes, T., Schnabel, A., Severijns, N., Sobolev, Yu., Stoepler, R., Trahms, L., Weis, A., Wiehl, N., Zejma, J., and Zsigmond, G.

Published

2009

16. Position-sensitive spectroscopy of ultra-cold neutrons with Timepix pixel detector

Author

Jakubek, J., Platkevic, M., Schmidt-Wellenburg, P., Geltenbort, P., Plonka-Spehr, C., and Daum, M.

Published

2009

17. A coated pixel device TimePix with micron spatial resolution for UCN detection

Author

Jakubek, J., Schmidt-Wellenburg, P., Geltenbort, P., Platkevic, M., Plonka-Spehr, C., Solc, J., and Soldner, T.

Published

2009

18. Diffuse reflection of ultracold neutrons from low-roughness surfaces

Author

Atchison, F., Daum, M., Henneck, R., Heule, S., Horisberger, M., Kasprzak, M., Kirch, K., Knecht, A., Kużniak, M., Lauss, B., Mtchedlishvili, A., Meier, M., Petzoldt, G., Plonka-Spehr, C., Schelldorfer, R., Straumann, U., and Zsigmond, G.

Published

2010

19. Measurement of the Permanent Electric Dipole Moment of the Neutron

Author

Abel, C., primary, Afach, S., additional, Ayres, N. J., additional, Baker, C. A., additional, Ban, G., additional, Bison, G., additional, Bodek, K., additional, Bondar, V., additional, Burghoff, M., additional, Chanel, E., additional, Chowdhuri, Z., additional, Chiu, P.-J., additional, Clement, B., additional, Crawford, C. B., additional, Daum, M., additional, Emmenegger, S., additional, Ferraris-Bouchez, L., additional, Fertl, M., additional, Flaux, P., additional, Franke, B., additional, Fratangelo, A., additional, Geltenbort, P., additional, Green, K., additional, Griffith, W. C., additional, van der Grinten, M., additional, Grujić, Z. D., additional, Harris, P. G., additional, Hayen, L., additional, Heil, W., additional, Henneck, R., additional, Hélaine, V., additional, Hild, N., additional, Hodge, Z., additional, Horras, M., additional, Iaydjiev, P., additional, Ivanov, S. N., additional, Kasprzak, M., additional, Kermaidic, Y., additional, Kirch, K., additional, Knecht, A., additional, Knowles, P., additional, Koch, H.-C., additional, Koss, P. A., additional, Komposch, S., additional, Kozela, A., additional, Kraft, A., additional, Krempel, J., additional, Kuźniak, M., additional, Lauss, B., additional, Lefort, T., additional, Lemière, Y., additional, Leredde, A., additional, Mohanmurthy, P., additional, Mtchedlishvili, A., additional, Musgrave, M., additional, Naviliat-Cuncic, O., additional, Pais, D., additional, Piegsa, F. M., additional, Pierre, E., additional, Pignol, G., additional, Plonka-Spehr, C., additional, Prashanth, P. N., additional, Quéméner, G., additional, Rawlik, M., additional, Rebreyend, D., additional, Rienäcker, I., additional, Ries, D., additional, Roccia, S., additional, Rogel, G., additional, Rozpedzik, D., additional, Schnabel, A., additional, Schmidt-Wellenburg, P., additional, Severijns, N., additional, Shiers, D., additional, Tavakoli Dinani, R., additional, Thorne, J. A., additional, Virot, R., additional, Voigt, J., additional, Weis, A., additional, Wursten, E., additional, Wyszynski, G., additional, Zejma, J., additional, Zenner, J., additional, and Zsigmond, G., additional

Published

2020

20. Diffuse reflection of ultracold neutrons from low-roughness surfaces

Author

Atchison, F., Daum, M., Henneck, R., Heule, S., Horisberger, M., Kasprzak, M., Kirch, K., Knecht, A., Kużniak, M., Lauss, B., Mtchedlishvili, A., Meier, M., Petzoldt, G., Plonka-Spehr, C., Schelldorfer, R., Straumann, U., Zsigmond, G., Atchison, F., Daum, M., Henneck, R., Heule, S., Horisberger, M., Kasprzak, M., Kirch, K., Knecht, A., Kużniak, M., Lauss, B., Mtchedlishvili, A., Meier, M., Petzoldt, G., Plonka-Spehr, C., Schelldorfer, R., Straumann, U., and Zsigmond, G.

Abstract

We report a measurement of the reflection of ultracold neutrons from flat, large-area plates of different Fermi potential materials with low surface roughness. The results were used to test two diffuse reflection models, the well-known Lambert model and the micro-roughness model which is based on wave scattering. The Lambert model fails to reproduce the diffuse reflection data. The surface roughness b and correlation length w , obtained by fitting the micro-roughness model to the data are in the range 1$ \le$ b $ \le$3 nm and 10$ \le$ w $ \le$120 nm, in qualitative agreement with independent measurements using atomic force microscopy

Published

2018

21. Observation of Gravitationally Induced Vertical Striation of Polarized Ultracold Neutrons by Spin-Echo Spectroscopy

Author

Afach, S., primary, Ayres, N. J., additional, Ban, G., additional, Bison, G., additional, Bodek, K., additional, Chowdhuri, Z., additional, Daum, M., additional, Fertl, M., additional, Franke, B., additional, Griffith, W. C., additional, Grujić, Z. D., additional, Harris, P. G., additional, Heil, W., additional, Hélaine, V., additional, Kasprzak, M., additional, Kermaidic, Y., additional, Kirch, K., additional, Knowles, P., additional, Koch, H.-C., additional, Komposch, S., additional, Kozela, A., additional, Krempel, J., additional, Lauss, B., additional, Lefort, T., additional, Lemière, Y., additional, Mtchedlishvili, A., additional, Musgrave, M., additional, Naviliat-Cuncic, O., additional, Pendlebury, J. M., additional, Piegsa, F. M., additional, Pignol, G., additional, Plonka-Spehr, C., additional, Prashanth, P. N., additional, Quéméner, G., additional, Rawlik, M., additional, Rebreyend, D., additional, Ries, D., additional, Roccia, S., additional, Rozpedzik, D., additional, Schmidt-Wellenburg, P., additional, Severijns, N., additional, Thorne, J. A., additional, Weis, A., additional, Wursten, E., additional, Wyszynski, G., additional, Zejma, J., additional, Zenner, J., additional, and Zsigmond, G., additional

Published

2015

22. Gravitational depolarization of ultracold neutrons: Comparison with data

Author

Afach, S., primary, Ayres, N. J., additional, Baker, C. A., additional, Ban, G., additional, Bison, G., additional, Bodek, K., additional, Fertl, M., additional, Franke, B., additional, Geltenbort, P., additional, Green, K., additional, Griffith, W. C., additional, van der Grinten, M., additional, Grujić, Z. D., additional, Harris, P. G., additional, Heil, W., additional, Hélaine, V., additional, Iaydjiev, P., additional, Ivanov, S. N., additional, Kasprzak, M., additional, Kermaidic, Y., additional, Kirch, K., additional, Koch, H.-C., additional, Komposch, S., additional, Kozela, A., additional, Krempel, J., additional, Lauss, B., additional, Lefort, T., additional, Lemière, Y., additional, Musgrave, M., additional, Naviliat-Cuncic, O., additional, Pendlebury, J. M., additional, Piegsa, F. M., additional, Pignol, G., additional, Plonka-Spehr, C., additional, Prashanth, P. N., additional, Quéméner, G., additional, Rawlik, M., additional, Rebreyend, D., additional, Ries, D., additional, Roccia, S., additional, Rozpedzik, D., additional, Schmidt-Wellenburg, P., additional, Severijns, N., additional, Shiers, D., additional, Thorne, J. A., additional, Weis, A., additional, Wursten, E., additional, Zejma, J., additional, Zenner, J., additional, and Zsigmond, G., additional

Published

2015

23. Particle Physics with Slow Neutrons Institut Laue-Langevin, Grenoble, France 29-31 May 2009

Author

Soldner, T., Nesvizhevsky, V., Plonka-Spehr, C., Protasov, K., Schreckenbach, K., Zimmer, O., Laboratoire de Physique Subatomique et de Cosmologie (LPSC), and Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Centre National de la Recherche Scientifique (CNRS)

Subjects

[PHYS.HPHE]Physics [physics]/High Energy Physics - Phenomenology [hep-ph]

Published

2009

24. An Improved Neutron Electric Dipole Moment Experiment

Author

Bodek, K., Kistryn, St, Kuzniak, M., Zejma, J., Burghoff, M., Knappe-Gruneberg, S., Sander-Thoemmes, T., Schnabel, A., Trahms, L., Ban, G., Lefort, T., Naviliat-Cuncic, O., Khomutov, N., Knowles, P., Pazgalev, A. S., Weis, A., Rogel, G., Quemener, G., Rebreyend, D., Roccia, S., Tur, M., Bison, G., Severijns, N., Eberhardt, K., Hampel, G., Heil, W., Kratz, J. V., Lauer, T., Plonka-Spehr, C., Sobolev, Yu, Wiehl, N., Altarev, I., Fierlinger, P., Gutsmiedl, E., Stephan Paul, Stoepler, R., Daum, M., Henneck, R., Kirch, K., Knecht, A., Lauss, B., Mtchedlishvili, A., Petzold, G., Zsigmond, G., Vernay, Emmanuelle, Laboratoire de physique corpusculaire de Caen (LPCC), Université de Caen Normandie (UNICAEN), Normandie Université (NU)-Normandie Université (NU)-École Nationale Supérieure d'Ingénieurs de Caen (ENSICAEN), Normandie Université (NU)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3), Laboratoire de Physique Subatomique et de Cosmologie (LPSC), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Joseph Fourier - Grenoble 1 (UJF)-Centre National de la Recherche Scientifique (CNRS), Institut Laue-Langevin (ILL), and ILL

Subjects

[PHYS.NEXP] Physics [physics]/Nuclear Experiment [nucl-ex], FOS: Physical sciences, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], Nuclear Experiment (nucl-ex), Nuclear Experiment

Abstract

A new measurement of the neutron EDM, using Ramsey's method of separated oscillatory fields, is in preparation at the new high intensity source of ultra-cold neutrons (UCN) at the Paul Scherrer Institute, Villigen, Switzerland (PSI). The existence of a non-zero nEDM would violate both parity and time reversal symmetry and, given the CPT theorem, might lead to a discovery of new CP violating mechanisms. Already the current upper limit for the nEDM (|d_n, Flavor Physics & CP Violation Conference, Taipei, 2008

Published

2008

25. Dynamic stabilization of the magnetic field surrounding the neutron electric dipole moment spectrometer at the Paul Scherrer Institute

Author

Afach, S., primary, Bison, G., additional, Bodek, K., additional, Burri, F., additional, Chowdhuri, Z., additional, Daum, M., additional, Fertl, M., additional, Franke, B., additional, Grujic, Z., additional, Hélaine, V., additional, Henneck, R., additional, Kasprzak, M., additional, Kirch, K., additional, Koch, H.-C., additional, Kozela, A., additional, Krempel, J., additional, Lauss, B., additional, Lefort, T., additional, Lemière, Y., additional, Meier, M., additional, Naviliat-Cuncic, O., additional, Piegsa, F. M., additional, Pignol, G., additional, Plonka-Spehr, C., additional, Prashanth, P. N., additional, Quéméner, G., additional, Rebreyend, D., additional, Roccia, S., additional, Schmidt-Wellenburg, P., additional, Schnabel, A., additional, Severijns, N., additional, Voigt, J., additional, Weis, A., additional, Wyszynski, G., additional, Zejma, J., additional, Zenner, J., additional, and Zsigmond, G., additional

Published

2014

26. Absorber materials for low-energy neutrons—Theoretical and experimental studies

Author

Brose, D., primary, Geltenbort, P., additional, Plonka-Spehr, C., additional, and Reichert, Th., additional

Published

2012

27. Diffraction of slow neutrons by holographic SiO2nanoparticle-polymer composite gratings

Author

Klepp, J., primary, Pruner, C., additional, Tomita, Y., additional, Plonka-Spehr, C., additional, Geltenbort, P., additional, Ivanov, S., additional, Manzin, G., additional, Andersen, K. H., additional, Kohlbrecher, J., additional, Ellabban, M. A., additional, and Fally, M., additional

Published

2011

28. Neutron to mirror-neutron oscillations in the presence of mirror magnetic fields

Author

Altarev, I., primary, Baker, C. A., additional, Ban, G., additional, Bodek, K., additional, Daum, M., additional, Fierlinger, P., additional, Geltenbort, P., additional, Green, K., additional, van der Grinten, M. G. D., additional, Gutsmiedl, E., additional, Harris, P. G., additional, Henneck, R., additional, Horras, M., additional, Iaydjiev, P., additional, Ivanov, S., additional, Khomutov, N., additional, Kirch, K., additional, Kistryn, S., additional, Knecht, A., additional, Knowles, P., additional, Kozela, A., additional, Kuchler, F., additional, Kuźniak, M., additional, Lauer, T., additional, Lauss, B., additional, Lefort, T., additional, Mtchedlishvili, A., additional, Naviliat-Cuncic, O., additional, Paul, S., additional, Pazgalev, A., additional, Pendlebury, J. M., additional, Petzoldt, G., additional, Pierre, E., additional, Plonka-Spehr, C., additional, Quéméner, G., additional, Rebreyend, D., additional, Roccia, S., additional, Rogel, G., additional, Severijns, N., additional, Shiers, D., additional, Sobolev, Yu., additional, Stoepler, R., additional, Weis, A., additional, Zejma, J., additional, Zenner, J., additional, and Zsigmond, G., additional

Published

2009

29. Experimental Demonstration of the Stability of Berry’s Phase for a Spin-1/2Particle

Author

Filipp, S., primary, Klepp, J., additional, Hasegawa, Y., additional, Plonka-Spehr, C., additional, Schmidt, U., additional, Geltenbort, P., additional, and Rauch, H., additional

Published

2009

30. Energy (TOF) and position sensitive detection of ultra cold neutrons with micrometric resolution using the TimePix pixel detector

Author

Jakubek, J., primary, Jenke, T., additional, Geltenbort, P., additional, Platkevic, M., additional, Plonka-Spehr, C., additional, Schmidt-Wellenburg, P., additional, Solc, J., additional, and Soldner, T., additional

Published

2008

31. Observation of gravitationally induced vertical striation of polarized ultracold neutrons by spin-echo spectroscopy

Author

Afach, S., Ayres, N. J., Ban, G., Bison, Georg, Bodek, K., Chowdhuri, Z., Daum, M., Fertl, M., Franke, B., Griffith, W. C., Grujić, Z. D., Harris, P. G., Heil, W., Hélaine, V., Kasprzak, Malgorzata, Kermaidic, Y., Kirch, K., Knowles, Paul E., Koch, H.-C., Komposch, S., Kozela, A., Krempel, J., Lauss, B., Lefort, T., Lemière, Y., Mtchedlishvili, A., Musgrave, M., Naviliat-Cuncic, O., Pendlebury, J. M., Piegsa, F. M., Pignol, G., Plonka-Spehr, C., Prashanth, P. N., Quéméner, G., Rawlik, M., Rebreyend, D., Ries, D., Roccia, S., Rozpedzik, D., Schmidt-Wellenburg, P., Severijns, N., Thorne, J. A., Weis, Antoine, Wursten, E., Wyszynski, G., Zejma, J., Zenner, J., Zsigmond, G., Afach, S., Ayres, N. J., Ban, G., Bison, Georg, Bodek, K., Chowdhuri, Z., Daum, M., Fertl, M., Franke, B., Griffith, W. C., Grujić, Z. D., Harris, P. G., Heil, W., Hélaine, V., Kasprzak, Malgorzata, Kermaidic, Y., Kirch, K., Knowles, Paul E., Koch, H.-C., Komposch, S., Kozela, A., Krempel, J., Lauss, B., Lefort, T., Lemière, Y., Mtchedlishvili, A., Musgrave, M., Naviliat-Cuncic, O., Pendlebury, J. M., Piegsa, F. M., Pignol, G., Plonka-Spehr, C., Prashanth, P. N., Quéméner, G., Rawlik, M., Rebreyend, D., Ries, D., Roccia, S., Rozpedzik, D., Schmidt-Wellenburg, P., Severijns, N., Thorne, J. A., Weis, Antoine, Wursten, E., Wyszynski, G., Zejma, J., Zenner, J., and Zsigmond, G.

Abstract

We describe a spin-echo method for ultracold neutrons (UCNs) confined in a precession chamber and exposed to a |B0|=1 μT magnetic field. We have demonstrated that the analysis of UCN spin-echo resonance signals in combination with knowledge of the ambient magnetic field provides an excellent method by which to reconstruct the energy spectrum of a confined ensemble of neutrons. The method takes advantage of the relative dephasing of spins arising from a gravitationally induced striation of stored UCNs of different energies, and also permits an improved determination of the vertical magnetic-field gradient with an exceptional accuracy of 1.1 pT/cm. This novel combination of a well-known nuclear resonance method and gravitationally induced vertical striation is unique in the realm of nuclear and particle physics and should prove to be invaluable for the assessment of systematic effects in precision experiments such as searches for an electric dipole moment of the neutron or the measurement of the neutron lifetime.

32. Neutron to mirror-neutron oscillations in the presence of mirror magnetic fields

Author

Altarev, I., Baker, C. A., Ban, G., Bodek, K., Daum, M., Fierlinger, P., Geltenbort, P., Green, K., Grinten, M. G. D. van der, Gutsmiedl, E., Harris, P. G., Henneck, R., Horras, M., Iaydjiev, P., Ivanov, S., Khomutov, N., Kirch, K., Kistryn, S., Knecht, A., Knowles, Paul E., Kozela, A., Kuchler, F., Kuźniak, M., Lauer, T., Lauss, B., Lefort, T., Mtchedlishvili, A., Naviliat-Cuncic, O., Paul, S., Pazgalev, Anatoly, Pendlebury, J. M., Petzoldt, G., Pierre, E., Plonka-Spehr, C., Quéméner, G., Rebreyend, D., Roccia, S., Rogel, G., Severijns, N., Shiers, D., Sobolev, Yu., Stoepler, R., Weis, Antoine, Zejma, J., Zenner, J., Zsigmond, G., Altarev, I., Baker, C. A., Ban, G., Bodek, K., Daum, M., Fierlinger, P., Geltenbort, P., Green, K., Grinten, M. G. D. van der, Gutsmiedl, E., Harris, P. G., Henneck, R., Horras, M., Iaydjiev, P., Ivanov, S., Khomutov, N., Kirch, K., Kistryn, S., Knecht, A., Knowles, Paul E., Kozela, A., Kuchler, F., Kuźniak, M., Lauer, T., Lauss, B., Lefort, T., Mtchedlishvili, A., Naviliat-Cuncic, O., Paul, S., Pazgalev, Anatoly, Pendlebury, J. M., Petzoldt, G., Pierre, E., Plonka-Spehr, C., Quéméner, G., Rebreyend, D., Roccia, S., Rogel, G., Severijns, N., Shiers, D., Sobolev, Yu., Stoepler, R., Weis, Antoine, Zejma, J., Zenner, J., and Zsigmond, G.

Abstract

We performed ultracold neutron storage measurements to search for additional losses due to neutron (n) to mirror-neutron (n') oscillations as a function of an applied magnetic field B. In the presence of a mirror magnetic field B', ultracold neutron losses would be maximal for B~B'. We did not observe any indication for nn' oscillations and placed a lower limit on the oscillation time of taunn'>12.0 s at 95% C.L. for any B' between 0 and 12.5 µT.

33. Additional results from the first dedicated search for neutron–mirror–neutron oscillations

Author

Bodek, K., Kistryn, S., Kuźniak, M., Zejma, J., Burghoff, M., Knappe-Grüneberg, S., Sander-Thoemmes, T., Schnabel, A., Trahms, L., Ban, G., Lefort, T., Naviliat-Cuncic, O., Khomutov, N., Knowles, Paul E., Pazgalev, Anatoly S., Weis, Antoine, Rogel, G., Quéméner, G., Rebreyend, D., Roccia, S., Bison, Georg, Severijns, N., Eberhardt, K., Hampel, G., Heil, W., Kratz, J.V., Lauer, T., Plonka-Spehr, C., Sobolev, Yu., Wiehl, N., Altarev, I., Fierlinger, P., Gutsmiedl, E., Paul, S., Stoepler, R., Daum, M., Henneck, R., Kirch, K., Knecht, A., Lauss, B., Mtchedlishvili, A., Petzoldt, G., Zsigmond, G., Bodek, K., Kistryn, S., Kuźniak, M., Zejma, J., Burghoff, M., Knappe-Grüneberg, S., Sander-Thoemmes, T., Schnabel, A., Trahms, L., Ban, G., Lefort, T., Naviliat-Cuncic, O., Khomutov, N., Knowles, Paul E., Pazgalev, Anatoly S., Weis, Antoine, Rogel, G., Quéméner, G., Rebreyend, D., Roccia, S., Bison, Georg, Severijns, N., Eberhardt, K., Hampel, G., Heil, W., Kratz, J.V., Lauer, T., Plonka-Spehr, C., Sobolev, Yu., Wiehl, N., Altarev, I., Fierlinger, P., Gutsmiedl, E., Paul, S., Stoepler, R., Daum, M., Henneck, R., Kirch, K., Knecht, A., Lauss, B., Mtchedlishvili, A., Petzoldt, G., and Zsigmond, G.

Abstract

The existence of a mirror world holding a copy of our ordinary particle spectrum could lead to oscillations between the neutron (n) and its mirror partner (n′). Such oscillations could manifest themselves in storage experiments with ultracold neutrons whose storage lifetime would depend on the applied magnetic field. Here, extended details and measurements from the first dedicated experimental search for nn′ oscillations published in [G. Ban, K. Bodek, M. Daum, R. Henneck, S. Heule, M. Kasprzak, N. Khomutov, K. Kirch, S. Kistryn, A. Knecht, P. Knowles, M. Kuźniak, T. Lefort, A. Mtchedlishvili, O. Naviliat-Cuncic, C. Plonka, G. Quéméner, M. Rebetez, D. Rebreyend, S. Roccia, G. Rogel, M. Tur, A. Weis, J. Zejma, G. Zsigmond, Direct experimental limit on neutron mirror–neutron oscillations, Phys. Rev. Lett. 99 (2007) 161603] will be presented, focussing on a possible dependence of the UCN counts on the magnetic field and its direction. However, at present no significant change in the averaged UCN counts with respect to the applied magnetic field has been found.

34. Diffuse reflection of ultracold neutrons from low-roughness surfaces

Author

Atchison, F., Daum, M., Henneck, R., Heule, S., Horisberger, M., Kasprzak, M., Kirch, K., Knecht, A., Kużniak, M., Lauss, B., Mtchedlishvili, A., Meier, M., Petzoldt, G., Plonka-Spehr, C., Schelldorfer, R., Straumann, U., Zsigmond, G., Atchison, F., Daum, M., Henneck, R., Heule, S., Horisberger, M., Kasprzak, M., Kirch, K., Knecht, A., Kużniak, M., Lauss, B., Mtchedlishvili, A., Meier, M., Petzoldt, G., Plonka-Spehr, C., Schelldorfer, R., Straumann, U., and Zsigmond, G.

Abstract

We report a measurement of the reflection of ultracold neutrons from flat, large-area plates of different Fermi potential materials with low surface roughness. The results were used to test two diffuse reflection models, the well-known Lambert model and the micro-roughness model which is based on wave scattering. The Lambert model fails to reproduce the diffuse reflection data. The surface roughness b and correlation length w , obtained by fitting the micro-roughness model to the data are in the range 1$ \le$ b $ \le$3 nm and 10$ \le$ w $ \le$120 nm, in qualitative agreement with independent measurements using atomic force microscopy

35. Towards a new measurement of the neutron electric dipole moment

Author

Altarev, I., Ban, G., Bison, Georg, Bodek, K., Burghoff, M., Cvijovic, Milan, Daum, M., Fierlinger, P., Gutsmiedl, E., Hampel, G., Heil, W., Henneck, R., Horras, M., Khomutov, N., Kirch, K., Kistryn, S., Knappe-Grüneberg, S., Knecht, A., Knowles, Paul E., Kozela, A., Kratz, J. V., Kuchler, F., Kuźniak, M., Lauer, T., Lauss, B., Lefort, T., Mtchedlishvili, A., Naviliat-Cuncic, O., Paul, S., Pazgalev, Anatoly S., Petzoldt, G., Pierre, E., Plonka-Spehr, C., Quéméner, G., Rebreyend, D., Roccia, S., Rogel, G., Sander-Thoemmes, T., Schnabel, A., Severijns, N., Sobolev, Yu., Stoepler, R., Trahms, L., Weis, Antoine, Wiehl, N., Zejma, J., Zsigmond, G., Altarev, I., Ban, G., Bison, Georg, Bodek, K., Burghoff, M., Cvijovic, Milan, Daum, M., Fierlinger, P., Gutsmiedl, E., Hampel, G., Heil, W., Henneck, R., Horras, M., Khomutov, N., Kirch, K., Kistryn, S., Knappe-Grüneberg, S., Knecht, A., Knowles, Paul E., Kozela, A., Kratz, J. V., Kuchler, F., Kuźniak, M., Lauer, T., Lauss, B., Lefort, T., Mtchedlishvili, A., Naviliat-Cuncic, O., Paul, S., Pazgalev, Anatoly S., Petzoldt, G., Pierre, E., Plonka-Spehr, C., Quéméner, G., Rebreyend, D., Roccia, S., Rogel, G., Sander-Thoemmes, T., Schnabel, A., Severijns, N., Sobolev, Yu., Stoepler, R., Trahms, L., Weis, Antoine, Wiehl, N., Zejma, J., and Zsigmond, G.

Abstract

The effort towards a new measurement of the neutron electric dipole moment (nEDM) at the Paul Scherrer Institut's (PSI) new high intensity source of ultracold neutrons (UCN) is described. The experimental technique relies on Ramsey's method of separated oscillatory fields, using UCN in vacuum with the apparatus at ambient temperature. In the first phase, R&D towards the upgrade of the RAL/Sussex/ILL apparatus is being performed at the Institut Laue-Langevin (ILL). In the second phase the apparatus, moved from ILL to PSI, will allow an improvement in experimental sensitivity by a factor of 5. In the third phase, a new spectrometer should gain another order of magnitude in sensitivity. The improvements will be mainly due to (1) much higher UCN intensity, (2) improved magnetometry and magnetic field control, and (3) a double chamber configuration with opposite electric field directions.

36. Dynamic stabilization of the magnetic field surrounding the neutron electric dipole moment spectrometer at the Paul Scherrer Institute

Author

Afach, S., Bison, Georg, Bodek, K., Burri, F., Chowdhuri, Z., Daum, M., Fertl, M., Franke, B., Grujic, Z., Hélaine, V., Henneck, R., Kasprzak, Malgorzata, Kirch, K., Koch, H.-C., Kozela, A., Krempel, J., Lauss, B., Lefort, T., Lemière, Y., Meier, M., Naviliat-Cuncic, O., Piegsa, F. M., Pignol, G., Plonka-Spehr, C., Prashanth, P. N., Quéméner, G., Rebreyend, D., Roccia, S., Schmidt-Wellenburg, P., Schnabel, A., Severijns, N., Voigt, J., Weis, Antoine, Wyszynski, G., Zejma, J., Zenner, J., Zsigmond, G., Afach, S., Bison, Georg, Bodek, K., Burri, F., Chowdhuri, Z., Daum, M., Fertl, M., Franke, B., Grujic, Z., Hélaine, V., Henneck, R., Kasprzak, Malgorzata, Kirch, K., Koch, H.-C., Kozela, A., Krempel, J., Lauss, B., Lefort, T., Lemière, Y., Meier, M., Naviliat-Cuncic, O., Piegsa, F. M., Pignol, G., Plonka-Spehr, C., Prashanth, P. N., Quéméner, G., Rebreyend, D., Roccia, S., Schmidt-Wellenburg, P., Schnabel, A., Severijns, N., Voigt, J., Weis, Antoine, Wyszynski, G., Zejma, J., Zenner, J., and Zsigmond, G.

Abstract

The Surrounding Field Compensation (SFC) system described in this work is installed around the four-layer Mu-metal magnetic shield of the neutron electric dipole moment spectrometer located at the Paul Scherrer Institute. The SFC system reduces the DC component of the external magnetic field by a factor of about 20. Within a control volume of approximately 2.5 m × 2.5 m × 3 m, disturbances of the magnetic field are attenuated by factors of 5–50 at a bandwidth from 10−3 Hz up to 0.5 Hz, which corresponds to integration times longer than several hundreds of seconds and represent the important timescale for the neutron electric dipole moment measurement. These shielding factors apply to random environmental noise from arbitrary sources. This is achieved via a proportional-integral feedback stabilization system that includes a regularized pseudoinverse matrix of proportionality factors which correlates magnetic field changes at all sensor positions to current changes in the SFC coils.

37. Diffraction of slow neutrons by holographic SiO2 nanoparticle-polymer composite gratings.

Author

Klepp, J., Pruner, C., Tomita, Y., Plonka-Spehr, C., Geltenbort, P., Ivanov, S., Manzin, G., Andersen, K. H., Kohlbrecher, J., Ellabban, M. A., and Fally, M.

Subjects

*NEUTRON diffraction, *NANOPARTICLES, *HOLOGRAPHY, *OPTICAL properties of metals, *NEUTRON interferometry, *NANOCOMPOSITE materials

Abstract

Diffraction experiments with holographic gratings recorded in SiO2 nanoparticle-polymer composites have been carried out with slow neutrons. The influence of parameters such as nanoparticle concentration, grating thickness, and grating spacing on the neutron-optical properties of such materials has been tested. Decay of the grating structure along the sample depth due to disturbance of the recording process becomes an issue at grating thicknesses of about 100 microns and larger. This limits the achievable diffraction efficiency for neutrons. As a solution to this problem, the Pendellösung interference effect in holographic gratings has been exploited to reach a diffraction efficiency of 83% for very cold neutrons. [ABSTRACT FROM AUTHOR]

Published

2011