Your search keyword '"MESONS"' showing total 14 results

1. Mu2e Transport Solenoid Cold-Mass Alignment Issues.

Author

Lopes, Mauricio, Ambrosio, Giorgio, Badgley, Karie E., Bradascio, Federica, Brandt, Jeffrey, Evbota, Daniel, Hocker, Andy, Lamm, Michael, Lombardo, Vito, Nicol, Thomas H., Kutschke, Robert, Vellidis, Costas, Wands, Bob, Wenk, Elizabeth, and Miller, James

Subjects

*SUPERCONDUCTING magnets, *MUONS, *ELECTRONS, *SOLENOIDS, *LEPTONS (Nuclear physics), *ELECTROMAGNETS

Abstract

The muon-to-electron conversion experiment (Mu2e) at Fermilab is designed to explore charged lepton flavor violation. It is composed of three large superconducting solenoids: the production solenoid, the transport solenoid (TS), and the detector solenoid. The TS is formed by two magnets: TS upstream and TS downstream. Each has its own cryostat and power supply. Tolerance sensitivity studies of the position and angular alignment of each coil in this magnet system were performed in the past with the objective to demonstrate that the magnet design meets all the field requirements. The alignment of the cold masses is critical to maximize the transmission of muons and to avoid possible backgrounds that would reduce the sensitivity of the experiment. Each TS magnet cold mass can be individually aligned. In this paper, we discuss the implications of the alignment of the TS cold masses in terms of the displacement of the magnetic center. Consideration of the practical mechanical limits is also presented. [ABSTRACT FROM PUBLISHER]

Published

2017

2. Mechanical Analysis of Pion Capture Superconducting Solenoid System for COMET Experiment at J-PARC.

Author

Iio, Masami, Yoshida, Makoto, Ki, Taekyung, Okamura, Takahiro, Sasaki, Ken-ichi, Makida, Yasuhiro, Ogitsu, Toru, Mihara, Satoshi, Nakamoto, Tatsushi, Sugano, Michinaka, Terashima, Akio, Kawamata, Hiroshi, and Yang, Ye

Subjects

*SOLENOIDS, *PIONS, *SUPERCONDUCTING magnets, *DYNAMIC mechanical analysis, *FINITE element method, *MAGNETIC fields, *RADIATION shielding, *NIOBIUM compounds, CAPTURE

Abstract

KEK is currently constructing a long series of superconducting solenoid beamline for the COMET Phase-I experiment at the Hadron facility of J-PARC. The magnet system consists of a 5-T pion capture solenoid, a curved muon transport solenoid, and a large bore detector solenoid. The pion capture solenoid system consists of a large cold mass including four coils with an inner diameter of 1340 mm and a small cold mass including six small coils with an inner diameter of 500 mm. The peak magnetic field on the conductor reaches to 5.4 T at an operation current of 2700 A. This paper presents the design and structural details of a magnet, radiation-resistant coil, cold mass and vacuum vessel, apart from the results of the electromagnetic analysis in two-dimensional (2-D) and 3-D. [ABSTRACT FROM PUBLISHER]

Published

2017

3. Mu2e Magnetic Measurement Studies.

Author

Buehler, M., Gluchko, S., Lopes, M. L., Orozco, C., Tartaglia, M., and Tompkins, J.

Subjects

*MAGNETICS, *SOLENOIDS, *MAGNETIC fields, *MAGNETISM, *SUPERCONDUCTING magnets

Abstract

The Mu2e experiment at Fermilab is designed to explore charged lepton flavor violation by searching for muon-to-electron conversion. The magnetic field generated by a system of solenoids is a crucial component of Mu2e and requires accurate characterization to detect any potential flaws and to produce a detailed field map. In order to design and build a precise field mapping system consisting of Hall and NMR probes, tolerances and precision for such a system need to be evaluated. To generate a final magnetic field map of the Mu2e solenoids, a continuous field has to be extracted from a discrete set of measurement points. A design for the Mu2e field mapping hardware, and results from simulations to specify parameters for Hall and NMR probes are presented. A fitting procedure for the analytical treatment of our expected magnetic measurements is introduced. [ABSTRACT FROM PUBLISHER]

Published

2014

4. Reference Design of the Mu2e Detector Solenoid.

Author

Feher, S., Andreev, N., Brandt, J., Cheban, S., Coleman, R., Dhanaraj, N., Fang, I., Lamm, M., Lombardo, V., Lopes, M., Miller, J., Ostojic, R., Orris, D., Page, T., Peterson, T., Tang, Z., and Wands, R.

Subjects

*SOLENOIDS, *COILS (Magnetism), *SUPERCONDUCTING magnets, *DETECTORS, *DESIGN

Abstract

The Mu2e experiment at Fermilab has been approved by the Department of Energy to proceed with the development of the preliminary design. Integral to the success of Mu2e is the superconducting solenoid system. One of the three major solenoids is the detector solenoid that houses the stopping target and the detectors. The goal of the detector solenoid team is to produce detailed design specifications that are sufficient for vendors to produce the final design drawings, tooling and fabrication procedures and proceed to production. In this paper we summarize the reference design of the detector solenoid. [ABSTRACT FROM PUBLISHER]

Published

2014

5. Studies on the Magnetic Center of the Mu2e Solenoid System.

Author

Lopes, M. L., Ambrosio, G., Buehler, M., Coleman, R., Evbota, D., Khalatian, V., Lamm, M., Miller, J., Moretti, G., Page, T., and Tartaglia, M.

Subjects

*MAGNETICS, *SOLENOIDS, *SUPERCONDUCTING magnets, *CHARGED particle accelerators, *CENTROID

Abstract

The definition of the magnetic center in the Mu2e solenoid system is not trivial given the S-shaped nature of the transport solenoid. Moreover, due to the fringe field of the larger bore adjacent magnets—production solenoid and the detector solenoid—the magnetic center does not coincide with the geometric center of the system. The reference magnetic center can be obtained by tracking a low-momentum charged particle through the whole system. This paper will discuss this method and will evaluate the deviations from the nominal magnetic center given the tolerances in the manufacturing and the alignment of the coils. Methods for the correction of the magnetic center will also be presented. [ABSTRACT FROM PUBLISHER]

Published

2014

6. Solenoid Magnet System for the Fermilab Mu2e Experiment.

Author

Lamm, M. J., Andreev, N., Ambrosio, G., Brandt, J., Coleman, R., Evbota, D., Kashikhin, V. V., Lopes, M., Miller, J., Nicol, T., Ostojic, R., Page, T., Peterson, T., Popp, J., Pronskikh, V., Tang, Z., Tartaglia, M., Wake, M., Wands, R., and Yamada, R.

Subjects

*SOLENOIDS, *MAGNETIC fields, *PIONS, *MAGNETIC coupling, *PARTICLE detectors

Abstract

The Fermilab Mu2e experiment seeks to measure the rare process of direct muon to electron conversion in the field of a nucleus. Key to the design of the experiment is a system of three superconducting solenoids; a muon production solenoid (PS) which is a 1.8 m aperture axially graded solenoid with a peak field of 5 T used to focus secondary pions and muons from a production target located in the solenoid aperture; an “S shaped” transport solenoid (TS) which selects and transports the subsequent muons towards a stopping target; a detector solenoid (DS) which is an axially graded solenoid at the upstream end to focus transported muons to a stopping target, and a spectrometer solenoid at the downstream end to accurately measure the momentum of the outgoing conversion electrons. The magnetic field requirements, the significant magnetic coupling between the solenoids, the curved muon transport geometry and the large beam induced energy deposition into the superconducting coils pose significant challenges to the magnetic, mechanical, and thermal design of this system. In this paper a conceptual design for the magnetic system which meets the Mu2e experiment requirements is presented. [ABSTRACT FROM PUBLISHER]

Published

2012

7. Model NbTi Helical Solenoid Fabrication and Test Results.

Author

Andreev, N., Barzi, E., Chlachidze, G., Evbota, D., Kashikhin, V. S., Kashikhin, V. V., Lamm, M. J., Makarov, A., Novitski, I., Orris, D. F., Tartaglia, M. A., Tompkins, J. C., Turrioni, D., Walbridge, D., Yu, M., and Zlobin, A. V.

Subjects

*SOLENOIDS, *SUPERCONDUCTING magnets, *ELECTRIC coils, *NIOBIUM compounds

Abstract

A program to develop model magnets for a helical cooling channel is under way at Fermilab. In the first steps of a planned sequence of magnets, two four-coil helical solenoid models with 300 mm aperture have been fabricated and tested. These two models, HSM01 and HSM02, used insulated NbTi Rutherford cable wound onto stainless steel rings with spliceless transitions between coils. Strip heaters were included for quench protection of each coil, and the coils were epoxy-impregnated after winding inside the support structures. Based on the results of the first model the second model was made using a cable with optimized cross-section, improved winding and epoxy-impregnation procedures, enhanced ground insulation, and included heat exchange tubing for a test of conduction cooling. We report on the results and lessons learned from fabrication and tests of these two models. [ABSTRACT FROM PUBLISHER]

Published

2012

8. Design of a Magnet for the Spin-Rotator Device for the High Magnetic Field \muSR Instrument at Paul Scherrer Institute.

Author

Vrankovic, V., Gabard, A., Meier, I., Stutz, R., Deckardt, R., Sanfilippo, S., Scheuermann, R., Sedlak, K., Reggiani, D., Deiters, K., Rauber, T., Kaufmann, P., and Walther, H.

Subjects

*MAGNETIC moments, *MUONS, *SPECTROMETERS, *LORENTZ force, *ELECTRIC fields

Abstract

In this work we present the design, the construction and the measurements of the magnet for a so-called spin-rotator (Wien filter), a beam line device used to rotate the spin direction (and the associated magnetic moment) of muons in a beam used for condensed matter research at the Swiss Muon Source at the Paul Scherrer Institute. The design parameters—originating both from the properties of the preferred particle beam as well as the technological constraints for the high-voltage components generating the necessary electric field—were optimized for device compactness, cost and high beam transmission. [ABSTRACT FROM PUBLISHER]

Published

2012

9. Quench Protection of Curved Solenoids for High Intensity Muon Beamlines.

Author

Adachi, Taihei, Ikedo, Yutaka, Makida, Yasuhiro, Yoshida, Makoto, Sasaki, Kenichi, Nakamoto, Tatsushi, Ogitsu, Toru, Yamamoto, Akira, Miyake, Yasuhiro, Sato, Akira, and Kuno, Yoshitaka

Subjects

*SOLENOIDS, *MUONS, *ELECTRIC coils, *HEAT treatment, *MESONS, *SUPERCONDUCTING magnets, *ELECTRIC resistance, *WIRE

Abstract

A quench protection system for superconducting curved segmented solenoids has been experimentally studied. The curved solenoids consist of short straight solenoids aligned along a curved beamline axis. The quench propagation between the short solenoids may not naturally occur because of the separation between the solenoids, and an artificial quench need to be induced by a protection heater for each short solenoid to boost the quench propagation. A protection heater driven by the coil self current was tested with a model coil. [ABSTRACT FROM AUTHOR]

Published

2011

10. Progress and Prospect of Superconducting Magnet Systems in J-PARC.

Author

Ogitsu, Toru

Subjects

*SUPERCONDUCTING magnets, *SUPERCONDUCTORS, *SUPERCONDUCTIVITY, *PARTICLE beams, *MAGNETS, *SOLENOIDS, *MAGNETICS, *PARTICLE accelerators

Abstract

The construction of the 1st phase Japan Proton Accelerator Research Complex (J-PARC) was completed. Three major experimental facilities, which have been utilized by users, are instrumented with the superconducting magnet systems; a muon transport solenoid in Materials and Life Science Experimental Facility, a superconducting spectrometer in Hadron Experimental Facility, and a 150 m superconducting beam line in Neutrino Experimental Facility. There are also several superconducting magnet systems proposed as part of future experiments at J-PARC. The paper briefly summarizes the current status of the superconducting magnet systems currently in operation, and introduces the superconducting magnet systems associated with the new proposals. [ABSTRACT FROM AUTHOR]

Published

2011

11. Conceptual Design of a Superconducting Solenoid System for the Super Omega Muon Beam Line at J-PARC.

Author

Makida, Yasuhiro, Ikedo, Yutaka, Ogitsu, Toru, Adachi, Taihei, Shimomura, Koichiro, Miyake, Yasuhiro, Kawamura, Naritoshi, Strasser, Patrick, Koda, Akihiro, Nakahara, Kazutaka, Nakamoto, Tatsushi, Okamura, Takahiro, Sasaki, Ken-ichi, and Yoshida, Makoto

Subjects

*SUPERCONDUCTORS, *SOLENOIDS, *MUONS, *SYNCHROTRONS, *MAGNETIC materials, *PARTICLE beams, *ELECTRIC coils, *PROTONS

Abstract

A 3-GeV (333 \muA, 1.0 MW) proton beam from the J-PARC Rapid Cycle Synchrotron passes through a graphite target producing muons in the Materials and Life Science Facility. Muons of various momenta of up to 50 MeV/c and of both electric charges are captured and transported to an experimental area by using an axial magnetic field in the bore of solenoid magnets. This beam line, named Super Omega, is composed of a normal conducting MIC (Mineral Insulation Cable) magnet for capture, a curved superconducting solenoid system for transportation, and an axial focusing magnet system. Once in the experimental area, the muon beam is focused onto an experimental target for various purposes. The superconducting solenoid system is composed of one 6-m long straight section and two 45-degree segmented curved sections at both ends of the straight section. A magnetic field of about 2 T is applied in the transportation channel of 300 mm in diameter. The conceptual design of this solenoid system is reported. [ABSTRACT FROM AUTHOR]

Published

2011

12. Superconducting Solenoid Magnets for the MuSIC Project.

Author

Yoshida, M., Fukuda, M., Hatanaka, K., Kuno, Y., Ogitsu, T., Sato, A., and Yamamoto, A.

Subjects

*SUPERCONDUCTING magnets, *SOLENOIDS, *MUONS, *ELECTRON beams, *MAGNETIC dipoles, *NOISE, *PARTICLE accelerators, *PIONS

Abstract

The new muon beamline, MuSIC, is being constructed at the Research Center for Nuclear Physics (RCNP) at Osaka University in Japan. The project utilizes superconducting solenoid magnets to collect pions and to transport muons with the ultimate efficiency by putting pion-production target inside the solenoid magnet. This is the first of such a novel method to produce intense muon beams. All the superconducting coils are cooled with conduction cooling using Gifford-McMahon cryocoolers. A large superconducting coil with the diameter of 90 cm encloses the pion-production target and thick shielding to protect the coil against severe radiation from the target, so that energy deposit by particles on the coil should be less than 1 W. Pions are captured in a 3.5 T magnetic field and are injected into the subsequent toroidal magnets with the magnetic field of 2 T. Superconducting dipole coils are equipped on each solenoid coil of the transport solenoid to correct the particle trajectory in the toroidal field. The design and construction status of the solenoid channel are described in this paper. [ABSTRACT FROM AUTHOR]

Published

2011

13. Study on Field Measurement and Ground Vibration for Superconducting Solenoid of New g-2 Experiment at J-PARC.

Author

Sasaki, Ken-ichi, Iinuma, Hiromi, Kimura, Nobuhiro, Ogitsu, Toru, Yamamoto, Akira, Nakayama, Hisayoshi, Mibe, Tsutomu, Saito, Naohito, and Obata, Takayuki

Subjects

*VIBRATION (Mechanics), *SUPERCONDUCTORS, *SOLENOIDS, *SUPERCONDUCTIVITY, *MAGNETIC fields, *MAGNETIC resonance imaging, *SUPERCONDUCTING magnets, *NUCLEAR magnetic resonance

Abstract

Basic R&Ds of a superconducting solenoid for a new g-2 experiment at J-PARC are on going. High uniformity of magnetic field below 0.1 ppm is required for the g-2 experiment within a storage region of 33.3 \pm5 cm in radius and \pm10 cm in height. Two R&Ds have been started to develop the magnet with such high uniformity; a development of a precise field monitoring system and a study of seismic ground vibration. The prototype monitoring system using continuous wave type NMR probe for horizontal MRI solenoid has been built and tested. Cross-check between NMR and Hall probe has been also carried out. The seismic ground vibration has been measured at Materials and Life science Facility, MLF, in J-PARC. Based on the measured results, the spectrum analysis of the iron yoke has been performed using ANSYS. [ABSTRACT FROM AUTHOR]

Published

2011

14. Superconducting Solenoid Magnets for the COMET Experiment.

Author

Yoshida, M., Nakamoto, T., Ogitsu, T., Tanaka, K., Yamamoto, A., Aoki, M., Kuno, Y., and Sato, A.

Subjects

*SUPERCONDUCTING magnets, *SOLENOIDS, *SUPERCONDUCTIVITY, *MUONS, *LEPTONS (Nuclear physics), *ELECTRONS, *MAGNETIC shielding, *ALUMINUM

Abstract

An intense muon beam is mandatory for next-generation experiments to search for lepton flavor violating processes in the muon sector. The COMET experiment, J-PARC E21, aims to search for muon to electron conversion with an unprecedented sensitivity. All the components of the experiment, such as the pion production target, the muon stopping target and the tracker are embedded in superconducting solenoids, resulting in a total length longer than 30 m. The pions are captured in a 5 T solenoid magnet with a diameter of 1.3 m, and decay to muons in the subsequent 3 T toroidal magnets over a length of 10 m. The pion capture solenoid is designed to be as small as possible, however, thick shielding is necessary within the solenoid to avoid severe radiation from the target. Aluminum-stabilized NbTi superconducting wire is employed to reduce the cold mass and energy deposited in it. The damage of the conductor of the coils should be estimated carefully, since the expected neutron fluence reaches 10^22\ neutrons/m^2. This paper describes the design of the solenoid magnets and R&D programs. [ABSTRACT FROM AUTHOR]

Published

2011