Your search keyword '"Trabocchi, S."' showing total 9 results

1. Optically Pumped Polarized $^3$He$^{++}$ Ion Source Development for RHIC/EIC

Author

Zelenski, A., Atoian, G., Beebe, E., Ikeda, S., Kanesue, T., Kondrashev, S., Maxwell, J., Milner, R., Musgrave, M., Okamura, M., Poblaguev, A. A., Raparia, D., Ritter, J., Sukhanov, A., and Trabocchi, S.

Subjects

Physics - Instrumentation and Detectors

Abstract

The proposed polarized $^3$He$^{++}$ acceleration in RHIC and the future Electron-Ion Collider will require about $2\times10^{11}$ ions in the source pulse. A new technique had been proposed for production of high intensity polarized $^3$He$^{++}$ ion beams. It is based on ionization and accumulation of the $^3$He gas (polarized by metastability-exchange optical pumping and in the 5 T high magnetic field) in the existing Electron Beam Ion Source (EBIS). A novel $^3$He cryogenic purification and storage technique was developed to provide the required gas purity. An original gas refill and polarized $^3$He gas injection to the EBIS long drift tubes, (which serves as the storage cell) were developed to ensure polarization preservation. An infrared laser system for optical pumping and polarization measurements in the high 3--5 T field has been developed. The $^3$He polarization 80--85\% (and sufficiently long $\sim30$ min relaxation time) was obtained in the \lq\lq{open}\rq\rq\ cell configuration with refilling valve tube inlet and isolation valve closed. The development of the spin-rotator and $^3$He $^4$He absolute nuclear polarimeter at 6 MeV $^3$He$^{++}$ beam energy is also presented., Comment: 9 pages, 11 figures

Published

2023

2. CBETA Design Report, Cornell-BNL ERL Test Accelerator

Author

Hoffstaetter, G. H., Trbojevic, D., Mayes, C., Banerjee, N., Barley, J., Bazarov, I., Bartnik, A., Berg, J. S., Brooks, S., Burke, D., Crittenden, J., Cultrera, L., Dobbins, J., Douglas, D., Dunham, B., Eichhorn, R., Full, S., Furuta, F., Franck, C., Gallagher, R., Ge, M., Gulliford, C., Heltsley, B., Jusic, D., Kaplan, R., Kostroun, V., Li, Y., Liepe, M., Liu, C., Lou, W., Mahler, G., Meot, F., Michnoff, R., Minty, M., Patterson, R., Peggs, S., Ptitsyn, V., Quigley, P., Roser, T., Sabol, D., Sagan, D., Sears, J., Shore, C., Smith, E., Smolenski, K., Thieberger, P., Trabocchi, S., Tuozzolo, J., Tsoupas, N., Veshcherevich, V., Widger, D., Wang, G., Willeke, F., and Xu, W.

Subjects

Physics - Accelerator Physics

Abstract

This design report describes the construction plans for the world's first multi-pass SRF ERL. It is a 4-pass recirculating linac that recovers the beam's energy by 4 additional, decelerating passes. All beams are returned for deceleration in a single beam pipe with a large-momentum-aperture permanent magnet FFAG optics. Cornell University has been pioneering a new class of accelerators, Energy Recovery Linacs (ERLs), with a new characteristic set of beam parameters. Technology has been prototyped that is essential for any high brightness electron ERL. This includes a DC electron source and an SRF injector Linac with world-record current and normalized brightness in a bunch train, a high-current linac cryomodule, and a high-power beam stop, and several diagnostics tools for high-current and high-brightness beams. All these are now being used to construct a novel one-cryomodule ERL in Cornell's Wilson Lab. Brookhaven National Laboratory (BNL) has designed a multi-turn ERL for eRHIC, where beam is transported more than 20 times around the 4km long RHIC tunnel. The number of transport lines is minimized by using two arcs with strongly-focusing permanent magnets that can control many beams of different energies. A collaboration between BNL and Cornell has been formed to investigate this multi-turn eRHIC ERL design by building a 4-turn, one-cryomodule ERL at Cornell. It also has a return loop built with strongly focusing permanent magnets and is meant to accelerate 40mA beam to 150MeV. This high-brightness beam will have applications beyond accelerator research, in industry, in nuclear physics, and in X-ray science.

Published

2017

3. Optically pumped polarized 3He++ ion source development for RHIC/EIC

Author

Zelenski, A., primary, Atoian, G., additional, Beebe, E., additional, Ikeda, S., additional, Kanesue, T., additional, Kondrashev, S., additional, Maxwell, J., additional, Milner, R., additional, Musgrave, M., additional, Okamura, M., additional, Poblaguev, A.A., additional, Raparia, D., additional, Ritter, J., additional, Sukhanov, A., additional, and Trabocchi, S., additional

Published

2023

4. The dipole corrector magnets for the FFAG beam line of the CBETA accelerator

Author

Tsoupas, Nicholaos, primary, Berg, J. S., additional, Jain, A., additional, Meot, F., additional, Mahler, G., additional, Trabocchi, S., additional, Trbojevic, D., additional, and Tuozzolo, J., additional

Published

2019

5. Development of a polarized 3He++ ion source for the EIC

Author

Massachusetts Institute of Technology. Laboratory for Nuclear Science, Musgrave, Matthew, Milner, Richard G, Atoian, G, Beebe, E, Ikeda, S, Kondrashev, S, Okamura, M, Poblaguev, A, Raparia, D, Ritter, J, Trabocchi, S, Zelenski, A, Maxwell, J, Massachusetts Institute of Technology. Laboratory for Nuclear Science, Musgrave, Matthew, Milner, Richard G, Atoian, G, Beebe, E, Ikeda, S, Kondrashev, S, Okamura, M, Poblaguev, A, Raparia, D, Ritter, J, Trabocchi, S, Zelenski, A, and Maxwell, J

Abstract

© Owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0). The capability of accelerating a high-intensity polarized 3He ion beam would provide an effective polarized neutron beam for new high-energy QCD studies of nucleon structure. This development is essential for the future Electron Ion Collider, which could use a polarized 3He ion beam to probe the spin structure of the neutron. The proposed polarized 3He ion source is based on the Electron Beam Ion Source (EBIS) currently in operation at Brookhaven National Laboratory. 3He gas would be polarized within the 5 T field of the EBIS solenoid via Metastability Exchange Optical Pumping (MEOP) and then pulsed into the EBIS vacuum and drift tube system where the 3He will be ionized by the 10 Amp electron beam. The goal of the polarized 3He ion source is to achieve 2.5 × 1011 3He++/pulse at 70% polarization. An upgrade of the EBIS is currently underway. An absolute polarimeter and spin-rotator is being developed to measure the 3He ion polarization at 6 MeV after initial acceleration out of the EBIS. The source is being developed through collaboration between BNL and MIT.

Published

2022

6. The CBETA Fractional Arc Test

Author

Hoffstaetter, Georg, primary, Trbojevic, Dejan, additional, Gulliford, C., additional, Banerjee, N., additional, Barley, J., additional, Bartnik, A., additional, Bazarov, I., additional, Ben-Zvi, I., additional, Berg, J. S., additional, Brooks, S., additional, Burke, D., additional, Crittenden, J., additional, Dobbins, J., additional, Gallagher, R., additional, Heltsley, B., additional, Hulsart, R., additional, Jones, J., additional, Jusic, D., additional, Kaplan, R., additional, Kelliher, D., additional, Kostroun, V., additional, Kuske, B., additional, Li, Y., additional, Liepe, M., additional, Lou, W., additional, Mahler, G., additional, McAteer, M., additional, Meot, F., additional, Michnoff, R., additional, Minty, M., additional, Patterson, R., additional, Peggs, S., additional, Ptitsyn, V., additional, Quigley, P., additional, Roser, T., additional, Sabol, D., additional, Sagan, D., additional, Sears, J., additional, Smolenski, K., additional, Smith, E., additional, Trabocchi, S., additional, Tuozzolo, J., additional, Tsoupas, N., additional, Veshcherevich, V., additional, Voelker, J., additional, and Widger, D., additional

Published

2018

7. Design of a modified Halbach magnet for the CBETA Project

Author

Tsoupas, Nicholaos, primary, Berg, J. S., additional, Brooks, S., additional, Mahler, G., additional, Meot, F., additional, Peggs, S., additional, Ptitsyn, V., additional, Roser, T., additional, Trabocchi, S., additional, Trbojevic, D., additional, Tuozzolo, J., additional, Burke, D., additional, Crittenden, J., additional, and Mayes, C., additional

Published

2018

8. Development of a polarized 3He++ ion source for the EIC

Author

Musgrave, M, Milner, R, Atoian, G, Beebe, E, Ikeda, S, Kondrashev, S, Okamura, M, Poblaguev, A, Raparia, D, Ritter, J, Trabocchi, S, Zelenski, A, Maxwell, J, Musgrave, M, Milner, R, Atoian, G, Beebe, E, Ikeda, S, Kondrashev, S, Okamura, M, Poblaguev, A, Raparia, D, Ritter, J, Trabocchi, S, Zelenski, A, and Maxwell, J

Abstract

© Owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0). The capability of accelerating a high-intensity polarized 3He ion beam would provide an effective polarized neutron beam for new high-energy QCD studies of nucleon structure. This development is essential for the future Electron Ion Collider, which could use a polarized 3He ion beam to probe the spin structure of the neutron. The proposed polarized 3He ion source is based on the Electron Beam Ion Source (EBIS) currently in operation at Brookhaven National Laboratory. 3He gas would be polarized within the 5 T field of the EBIS solenoid via Metastability Exchange Optical Pumping (MEOP) and then pulsed into the EBIS vacuum and drift tube system where the 3He will be ionized by the 10 Amp electron beam. The goal of the polarized 3He ion source is to achieve 2.5 × 1011 3He++/pulse at 70% polarization. An upgrade of the EBIS is currently underway. An absolute polarimeter and spin-rotator is being developed to measure the 3He ion polarization at 6 MeV after initial acceleration out of the EBIS. The source is being developed through collaboration between BNL and MIT.

Published

2021

9. Experimental Demonstration of Hadron Beam Cooling Using Radio-Frequency Accelerated Electron Bunches

Author

Fedotov, A. V., primary, Altinbas, Z., additional, Belomestnykh, S., additional, Ben-Zvi, I., additional, Blaskiewicz, M., additional, Brennan, M., additional, Bruno, D., additional, Brutus, C., additional, Costanzo, M., additional, Drees, A., additional, Fischer, W., additional, Fite, J., additional, Gaowei, M., additional, Gassner, D., additional, Gu, X., additional, Halinski, J., additional, Hamdi, K., additional, Hammons, L., additional, Harvey, M., additional, Hayes, T., additional, Hulsart, R., additional, Inacker, P., additional, Jamilkowski, J., additional, Jing, Y., additional, Kewisch, J., additional, Kankiya, P., additional, Kayran, D., additional, Lehn, R., additional, Liaw, C. J., additional, Litvinenko, V., additional, Liu, C., additional, Ma, J., additional, Mahler, G., additional, Mapes, M., additional, Marusic, A., additional, Mernick, K., additional, Mi, C., additional, Michnoff, R., additional, Miller, T., additional, Minty, M., additional, Narayan, G., additional, Nayak, S., additional, Nguyen, L., additional, Paniccia, M., additional, Pinayev, I., additional, Polizzo, S., additional, Ptitsyn, V., additional, Rao, T., additional, Robert-Demolaize, G., additional, Roser, T., additional, Sandberg, J., additional, Schoefer, V., additional, Schultheiss, C., additional, Seletskiy, S., additional, Severino, F., additional, Shrey, T., additional, Smart, L., additional, Smith, K., additional, Song, H., additional, Sukhanov, A., additional, Than, R., additional, Thieberger, P., additional, Trabocchi, S., additional, Tuozzolo, J., additional, Wanderer, P., additional, Wang, E., additional, Wang, G., additional, Weiss, D., additional, Xiao, B., additional, Xin, T., additional, Xu, W., additional, Zaltsman, A., additional, Zhao, H., additional, and Zhao, Z., additional

Published

2020