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3. A Strategic Approach to Advance Magnet Technology for Next Generation Colliders

Author

Ambrosio, G., Amm, K., Anerella, M., Apollinari, G., Arbelaez, D., Auchmann, B., Balachandran, S., Baldini, M., Ballarino, A., Barua, S., Barzi, E., Baskys, A., Bird, C., Boerme, J., Bosque, E., Brouwer, L., Caspi, S., Cheggour, N., Chlachidze, G., Cooley, L., Davis, D., Dietderich, D., DiMarco, J., English, L., Fajardo, L. Garcia, Fernandez, J. L. Rudeiros, Ferracin, P., Gourlay, S., Gupta, R., Hafalia, A., Hellstrom, E., Higley, H., Hossain, I., Jewell, M., Jiang, J., Juchno, GM., Kametani, F., Kashikhin, V., Krave, S., Kumar, M., Kurian, F., Lankford, A., Larbalestier, D., Lee, P., Lee, G. S., Lombardo, V., Marchevsky, M., Marinozzi, V., Messe, C., Minervini, J., Myers, C., Naus, M., Novitski, I., Ogitsu, T., Palmer, M., Pong, I., Prestemon, S., Runyan, C., Sabbi, G. L., Shen, T., Stoynev, S., Strauss, T., Tarantini, C., Teyber, R., Trociewitz, U., Turqueti, M., Turenne, M., Turrioni, D., Vallone, G., Velev, G., Viarengo, S., Wang, L., Wang, X., Xu, X., Yamamoto, A., Yin, S., and Zlobin, A.

Subjects
Accelerator Physics (physics.acc-ph), FOS: Physical sciences, Physics::Accelerator Physics, Physics - Accelerator Physics, Accelerators and Storage Rings, physics.acc-ph
Abstract

Colliders are built on a foundation of superconducting magnet technology that provides strong dipole magnets to maintain the beam orbit and strong focusing magnets to enable the extraordinary luminosity required to probe physics at the energy frontier. The dipole magnet strength plays a critical role in dictating the energy reach of a collider, and the superconducting magnets are arguably the dominant cost driver for future collider facilities. As the community considers opportunities to explore new energy frontiers, the importance of advanced magnet technology - both in terms of magnet performance and in the magnet technology's potential for cost reduction - is evident, as the technology status is essential for informed decisions on targets for physics reach and facility feasibility., contribution to Snowmass 2021

Published
2022

5. AC losses and magnetic coupling in multifilamentary 2G HTS conductors and tape arrays

Author

Marchevsky, M., Ed Zhang, Yiyuan Xie, Selvamanickam, V., and Ganesan, P.G.

Subjects
Electric currents -- Measurement, High temperature superconductors -- Electric properties, High temperature superconductors -- Magnetic properties, Magnetization -- Analysis, Superconducting magnets -- Design and construction, Business, Electronics, Electronics and electrical industries
Published
2009

6. Second-generation HTS conductor design and engineering for electrical power applications

Author

Yi-Yuan Xie, Marchevsky, M., Xun Zhang, Lenseth, K., Yimin Chen, Xuming Xiong, Yunfei Qiao, Rar, A., Gogia, B., Schmidt, R., Knoll, A., Selvamanickam, V., Pethuraja, G.G., and Dutta, P.

Subjects
Superconducting magnets -- Usage, Alternating current -- Measurement, Electric power systems -- Design and construction, High temperature superconductors -- Design and construction, Business, Electronics, Electronics and electrical industries
Published
2009

7. High-Luminosity Large Hadron Collider (HL-LHC): Technical design report

Author

Aberle, O., Béjar Alonso, I, Brüning, O, Fessia, P, Rossi, L, Tavian, L, Zerlauth, M, Adorisio, C., Adraktas, A., Ady, M., Albertone, J., Alberty, L., Alcaide Leon, M., Alekou, A., Alesini, D., Ferreira, B. Almeida, Lopez, P. Alvarez, Ambrosio, G., Andreu Munoz, P., Anerella, M., Angal-Kalinin, D., Antoniou, F., Apollinari, G., Apollonio, A., Appleby, R., Arduini, G., Alonso, B. Arias, Artoos, K., Atieh, S., Auchmann, B., Badin, V., Baer, T., Baffari, D., Baglin, V., Bajko, M., Ball, A., Ballarino, A., Bally, S., Bampton, T., Banfi, D., Barlow, R., Barnes, M., Barranco, J., Barthelemy, L., Bartmann, W., Bartosik, H., Barzi, E., Battistin, M., Baudrenghien, P., Alonso, I. Bejar, Belomestnykh, S., Benoit, A., Ben-Zvi, I., Bertarelli, A., Bertolasi, S., Bertone, C., Bertran, B., Bestmann, P., Biancacci, N., Bignami, A., Bliss, N., Boccard, C., Body, Y., Borburgh, J., Bordini, B., Borralho, F., Bossert, R., Bottura, L., Boucherie, A., Bozzi, R., Bracco, C., Bravin, E., Bregliozzi, G., Brett, D., Broche, A., Brodzinski, K., Broggi, F., Bruce, R., Brugger, M., Brüning, O., Buffat, X., Burkhardt, H., Burnet, J., Burov, A., Burt, G., Cabezas, R., Cai, Y., Calaga, R., Calatroni, S., Capatina, O., Capelli, T., Cardon, P., Carlier, E., Carra, F., Carvalho, A., Carver, L.R., Caspers, F., Cattenoz, G., Cerutti, F., Chancé, A., Rodrigues, M. Chastre, Chemli, S., Cheng, D., Chiggiato, P., Chlachidze, G., Claudet, S., Coello De Portugal, JM., Collazos, C., Corso, J., Costa Machado, S., Costa Pinto, P., Coulinge, E., Crouch, M., Cruikshank, P., Cruz Alaniz, E., Czech, M., Dahlerup-Petersen, K., Dalena, B., Daniluk, G., Danzeca, S., Day, H., De Carvalho Saraiva, J., De Luca, D., De Maria, R., De Rijk, G., De Silva, S., Dehning, B., Delayen, J., Deliege, Q., Delille, B., Delsaux, F., Denz, R., Devred, A., Dexter, A., Di Girolamo, B., Dietderich, D., Dilly, J.W., Doherty, A., Dos Santos, N., Drago, A., D.Drskovic, Ramos, D. Duarte, Ducimetière, L., Efthymiopoulos, I., Einsweiler, K., Esposito, L., Esteban Muller, J., Evrard, S., Fabbricatore, P., Farinon, S., Fartoukh, S., Faus-Golfe, A., Favre, G., Felice, H., Feral, B., Ferlin, G., Ferracin, P., Ferrari, A., Ferreira, L., Fessia, P., Ficcadenti, L., Fiotakis, S., Fiscarelli, L., Fitterer, M., Fleiter, J., Foffano, G., Fol, E., Folch, R., Foraz, K., Foussat, A., Frankl, M., Frasciello, O., Fraser, M., Menendez, P. Freijedo, Fuchs, J-F., Furuseth, S., Gaddi, A., Gallilee, M., Gallo, A., Alia, R. Garcia, Gavela, H. Garcia, Matos, J. Garcia, Garcia Morales, H., Valdivieso, A. Garcia-Tabares, Garino, C., Garion, C., Gascon, J., Gasnier, Ch., Gentini, L., Gentsos, C., Ghosh, A., Giacomel, L., Hernandez, K. Gibran, Gibson, S., Ginburg, C., Giordano, F., Giovannozzi, M., Goddard, B., Gomes, P., Gonzalez De La Aleja Cabana, M., Goudket, P., Gousiou, E., Gradassi, P., Costa, A. Granadeiro, Grand-Clément, L., Grillot, S., Guillaume, JC., Guinchard, M., Hagen, P., Hakulinen, T., Hall, B., Hansen, J., Heredia Garcia, N., Herr, W., Herty, A., Hill, C., Hofer, M., Höfle, W., Holzer, B., Hopkins, S., Hrivnak, J., Iadarola, G., Infantino, A., Bermudez, S. Izquierdo, Jakobsen, S., Jebramcik, M.A., Jenninger, B., Jensen, E., Jones, M., Jones, R., Jones, T., Jowett, J., Juchno, M., Julie, C., Junginger, T., Kain, V., Kaltchev, D., Karastathis, N., Kardasopoulos, P., Karppinen, M., Keintzel, J., Kersevan, R., Killing, F., Kirby, G., Korostelev, M., Kos, N., Kostoglou, S., Kozsar, I., Krasnov, A., Krave, S., Krzempek, L., Kuder, N., Kurtulus, A., Kwee-Hinzmann, R., Lackner, F., Lamont, M., Lamure, A.L., m, L. Lari, Lazzaroni, M., Le Garrec, M., Lechner, A., Lefevre, T., Leuxe, R., Li, K., Li, Z., Lindner, R., Lindstrom, B., Lingwood, C., Löffler, C., Lopez, C., Lopez-Hernandez, LA., Losito, R., Maciariello, F., Macintosh, P., Maclean, E.H., Macpherson, A., Maesen, P., Magnier, C., Durand, H. Mainaud, Malina, L., Manfredi, M., Marcellini, F., Marchevsky, M., Maridor, S., Marinaro, G., Marinov, K., Markiewicz, T., Marsili, A., Martinez Urioz, P., Martino, M., Masi, A., Mastoridis, T., Mattelaer, P., May, A., Mazet, J., Mcilwraith, S., McIntosh, E., Medina Medrano, L., Mejica Rodriguez, A., Mendes, M., Menendez, P., Mensi, M., Mereghetti, A., Mergelkuhl, D., Mertens, T., Mether, L., Métral, E., Migliorati, M., Milanese, A., Minginette, P., Missiaen, D., Mitsuhashi, T., Modena, M., Mokhov, N., Molson, J., Monneret, E., Montesinos, E., Moron-Ballester, R., Morrone, M., Mostacci, A., Mounet, N., Moyret, P., Muffat, P., Muratori, B., Muttoni, Y., Nakamoto, T., Navarro-Tapia, M., Neupert, H., Nevay, L., Nicol, T., Nilsson, E., Ninin, P., Nobrega, A., Noels, C., Nolan, E., Nosochkov, Y., Nuiry, FX., Oberli, L., Ogitsu, T., Ohmi, K., Olave R., Oliveira, J., Orlandi, Ph., Ortega, P., Osborne, J., Otto, T., Palumbo, L., Papadopoulou, S., Papaphilippou, Y., Paraschou, K., Parente, C., Paret, S., Park, H., Parma, V., Pasquino, Ch., Patapenka, A., Patnaik, L., Pattalwar, S., Payet, J., Pechaud, G., Pellegrini, D., Pepinster, P., Perez, J., Espinos, J. Perez, Marcone, A. Perillo, Perin, A., Perini, P., Persson, T.H.B., Peterson, T., Pieloni, T., Pigny, G., Pinheiro de Sousa, J.P., Pirotte, O., Plassard, F., Pojer, M., Pontercorvo, L., Poyet, A., Prelipcean, D., Prin, H., Principe, R., Pugnat, T., Qiang, J., Quaranta, E., Rafique, H., Rakhno, I., Duarte, D. Ramos, Ratti, A., Ravaioli, E., Raymond, M., Redaelli, S., Renaglia, T., Ricci, D., Riddone, G., Rifflet, J., Rigutto, E., Rijoff, T., Rinaldesi, R., Riu Martinez, O., Rivkin, L., Rodriguez Mateos, F., Roesler, S., Romera Ramirez, I., Rossi, A., Rossi, L., Rude, V., Rumolo, G., Rutkovksi, J., Sabate Gilarte, M., Sabbi, G., Sahner, T., Salemme, R., Salvant, B., Galan, F. Sanchez, Santamaria Garcia, A., Santillana, I., Santini, C., Santos, O., Diaz, P. Santos, Sasaki, K., Savary, F., Sbrizzi, A., Schaumann, M., Scheuerlein, C., Schmalzle, J., Schmickler, H., Schmidt, R., Schoerling, D., Segreti, M., Serluca, M., Serrano, J., Sestak, J., Shaposhnikova, E., Shatilov, D., Siemko, A., Sisti, M., Sitko, M., Skarita, J., Skordis, E., Skoufaris, K., Skripka, G., Smekens, D., Sobiech, Z., Sosin, M., Sorbio, M., Soubelet, F., Spataro, B., Spiezia, G., Stancari, G., Staterao, M., Steckert, J., Steele, G., Sterbini, G., Struik, M., Sugano, M., Szeberenyi, A., Taborelli, M., Tambasco, C., Rego, R. Tavares, Tavian, L., Teissandier, B., Templeton, N., Therasse, M., Thiesen, H., Thomas, E., Toader, A., Todesco, E., Tomás, R., Toral, F., Torres-Sanchez, R., Trad, G., Triantafyllou, N., Tropin, I., Tsinganis, A., Tuckamantel, J., Uythoven, J., Valishev, A., Van Der Veken, F., Van Weelderen, R., Vande Craen, A., Vazquez De Prada, B., Velotti, F., Verdu Andres, S., Verweij, A., Shetty, N. Vittal, Vlachoudis, V., Volpini, G., Wagner, U., Wanderer, P., Wang, M., Wang, X., Wanzenberg, R., Wegscheider, A., Weisz, S., Welsch, C., Wendt, M., Wenninger, J., Weterings, W., White, S., Widuch, K., Will, A., Willering, G., Wollmann, D., Wolski, A., Wozniak, J., Wu, Q., Xiao, B., Xiao, L., Xu, Q., Yakovlev, Y., Yammine, S., Yang, Y., Yu, M., Zacharov, I., Zagorodnova, O., Zannini, C., Zanoni, C., Zerlauth, M., Zimmermann, F., Zlobin, A., Zobov, M., and Zurbano Fernandez, I.

Subjects
Accelerators and Storage Rings
Abstract

The Large Hadron Collider (LHC) is one of the largest scientific instruments ever built. Since opening up anew energy frontier for exploration in 2010, it has gathered a global user community of about 9000 scientists working in fundamental particle physics and the physics of hadronic matter at extreme temperature and density. To sustain and extend its discovery potential, the LHC will need a major upgrade in the 2020s. This will increase its instantaneous luminosity (rate of collisions) by a factor of five beyond the original design valueand the integrated luminosity (totalnumber of collisions) by a factor ten. The LHC is already a highly complexand exquisitely optimised machine so this upgrade must be carefully conceived and will require new infrastructures(underground and on surface)and over a decade to implement. The new configuration, known as High Luminosity LHC (HL-LHC), relies on a number of key innovations that push accelerator technology beyond its present limits. Among these are cutting-edge 11–12Tesla superconducting magnets, compact superconducting cavities for beam rotation with ultra-precise phase control, new technology and physical processes for beam collimation and 100 metre-long high-power superconducting links with negligible energy dissipation, all of which required several years of dedicated R&D; effort on a global international level. The present document describes the technologies and components that will be used to realise the projectand is intended to serve as the basis for the detailed engineering design of the HL-LHC.

Published
2020

8. Two coexisting vortex phases in the peak effect regime in a superconductor

Author

Marchevsky, M., Higgins, M. J., and Bhattacharya, S.

Subjects
Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): M. Marchevsky (corresponding author) [1]; M. J. Higgins [1]; S. Bhattacharya [1, 2] The critical current in the vortex phase of a type-II superconductor such as NbSe[sub.2] displays a [...]

Published
2001
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9. Progress on high luminosity LHC Nb$_{3}$Sn magnets

Author

Todesco, Ezio, Annarella, M, Ambrosio, Giorgio, Apollinari, Giorgio, Ballarino, Amalia, Bajas, H, Bajko, Marta, Bordini, Bernardo, Bossert, R, Bottura, Luca, Cavanna, E, Cheng, D, Chlachidze, G, De Rijk, Gijs, DiMarco, J, Ferracin, Paolo, Fleiter, Jerome, Guinchard, M, Hafalia, A, Holik, E, Izquierdo Bermudez, S, Lackner, F, Marchevsky, M, Loeffler, C, Nobrega, A, Perez, Juan Carlos, Prestemon, Soren, Ravaioli, E, Rossi, Lucio, Sabbi, GianLuca, Salmi, T, Savary, Frederic, Schmalzle, J, Stoynev, S, Strauss, T, Tartaglia, M, Vallone, Giorgio, Velev, Gueorgui, Wanderer, Peter, Wang, X, Willering, Gerard, and Yu, M

Subjects
Physics::Accelerator Physics, Accelerators and Storage Rings
Abstract

The HL-LHC project aims at allowing to increase the collisions in the Large Hadron Collider by a factor ten in the decade 2025 - 2035. One essential element are the superconducting magnets around the interaction region points, where large aperture magnets will be installed to allow to further reduce the beam size in the interaction point. The core of this upgrade is the Nb$_{3}$Sn triplet, made of 150 mm aperture quadrupoles of in the range of 7 - 8 m. The project is being shared between CERN and US Accelerator Upgrade Program, based on the same design, and on two strand technologies. The project is ending the short model phase, and entering the prototype construction. We will report on the main results of the short model program, including quench performance and field quality. A second important element is the 11 T dipole that replacing a standard dipole makes space for additional collimators. The magnet is also ending the model development and entering the prototype phase. A critical point in the design of this magnet is the large current density, allowing increasing the field from 8 to 11 T with the same coil cross - section as in the LHC dipoles. This is also the first two - in - one Nb$_{3}$Sn magnet developed so far. We will report the main results on the test and the critical aspects .

Published
2018

10. Insertion Magnets

Author

Ambrosio, G, Anerella, M, Bossert, R, Cheng, D, Chlachidze, G, Dietderich, D, Ramos, DD, Fabbricatore, P, Farinon, S, Felice, H, Ferracin, P, Fessia, P, Matos, JG, Ghosh, A, Hagen, P, Bermudez, SI, Juchno, M, Krave, S, Marchevsky, M, Nakamoto, T, Ogitsu, T, Perez, JC, Prin, H, Rifflet, JM, Sabbi, GL, Sasaki, K, Schmalzle, J, Segreti, M, Sugano, M, Todesco, E, Toral, F, Volpini, G, Wanderer, P, Wang, X, Weelderen, RV, Xu, Q, and Yu, M

Subjects
Accelerator Physics (physics.acc-ph), Physics::Instrumentation and Detectors, FOS: Physical sciences, Physics - Accelerator Physics, physics.acc-ph
Abstract

Chapter 3 in High-Luminosity Large Hadron Collider (HL-LHC) : Preliminary Design Report. The Large Hadron Collider (LHC) is one of the largest scientific instruments ever built. Since opening up a new energy frontier for exploration in 2010, it has gathered a global user community of about 7,000 scientists working in fundamental particle physics and the physics of hadronic matter at extreme temperature and density. To sustain and extend its discovery potential, the LHC will need a major upgrade in the 2020s. This will increase its luminosity (rate of collisions) by a factor of five beyond the original design value and the integrated luminosity (total collisions created) by a factor ten. The LHC is already a highly complex and exquisitely optimised machine so this upgrade must be carefully conceived and will require about ten years to implement. The new configuration, known as High Luminosity LHC (HL-LHC), will rely on a number of key innovations that push accelerator technology beyond its present limits. Among these are cutting-edge 11-12 tesla superconducting magnets, compact superconducting cavities for beam rotation with ultra-precise phase control, new technology and physical processes for beam collimation and 300 metre-long high-power superconducting links with negligible energy dissipation. The present document describes the technologies and components that will be used to realise the project and is intended to serve as the basis for the detailed engineering design of HL-LHC., 19 pages, Chapter 3 in High-Luminosity Large Hadron Collider (HL-LHC) : Preliminary Design Report

Published
2017
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11. Quench detection using Hall sensors in high-temperature superconducting CORC®-based cable-in-conduit-conductors for fusion applications.

Author

Weiss, J D, Teyber, R, Marchevsky, M, and van der Laan, D C

Subjects
ELECTRIC conduits, ELECTROMAGNETS, ELECTRIC potential measurement, FUSION reactors, DETECTORS, MAGNETIC fields
Abstract

Advanced magnet systems for fusion applications would greatly benefit from the use of high-temperature superconductors (HTS). These materials allow fusion magnets to operate at higher magnetic fields, allowing for more compact fusion machines, and allow for operation at elevated temperatures, enabling demountable coils that provide access for maintenance of the fusion reactor. Quench detection remains a major challenge in the protection of HTS magnets that are vulnerable to localized conductor burnout due to their low quench propagation velocities. One of the methods explored is the use of Hall sensors that are incorporated in or near the magnet terminations that can detect local field variations that occur as a result of current redistribution within the conductor to bypass a hotspot within the magnet winding. This method is potentially well suited for Cable in Conduit Conductors, such as those made from Conductor on Round Core (CORC) cables, in which sub-cables containing HTS tapes are connected to the terminations at a low resistance. To demonstrate the technique, a CORC® triplet consisting of three sub-cables, rated for 4 kA operation at 77 K, was manufactured and Hall sensors were used to measure local field variations next to the terminations due to current redistribution between the cables. The Hall response was compared to voltages that developed over the cables and terminations as a local hotspot was applied to different cables in the triplet. It was found that the Hall sensors were faster and more sensitive than voltage contact measurements and were able to reliably detect current redistribution of only a few amperes caused by a hotspot, well before the triplet exceeded its critical current. The method also allowed the detection of heater-induced hotspots during high ramp rates of 2 kA s−1 relevant for fusion applications. Hall sensors have a distinct benefit of being less sensitive to inductive pickup of AC interference compared to voltage contact measurements that make quench detection through voltage measurements in magnets especially challenging. The method can also be used for diagnostic measurements of current redistribution caused by other sources such as inhomogeneous current injection from faulty joints, or localized conductor damage. The Hall sensors are likely capable of detecting the onset of a quench that may occur a far distance away from the sensor location, presenting a breakthrough in HTS quench detection that potentially removes one of the remaining barriers to reliable operation of large HTS magnet systems. [ABSTRACT FROM AUTHOR]

Published
2020
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12. Development of MQXF: The Nb3Sn Low-β Quadrupole for the HiLumi LHC

Author

Ferracin, P, Ambrosio, G, Anerella, M, Ballarino, A, Bajas, H, Bajko, M, Bordini, B, Bossert, R, Cheng, DW, Dietderich, DR, Chlachidze, G, Cooley, L, Felice, H, Ghosh, A, Hafalia, R, Holik, E, Izquierdo Bermudez, S, Fessia, P, Grosclaude, P, Guinchard, M, Juchno, M, Krave, S, Lackner, F, Marchevsky, M, Marinozzi, V, Nobrega, F, Oberli, L, Pan, H, Perez, JC, Prin, H, Rysti, J, Rochepault, E, Sabbi, G, Salmi, T, Schmalzle, J, Sorbi, M, Sequeira Tavares, S, Todesco, E, Wanderer, P, Wang, X, and Yu, M

Abstract

© 2016 IEEE. The High Luminosity (HiLumi) Large Hadron Collider (LHC) project has, as the main objective, to increase the LHC peak luminosity by a factor five and the integrated luminosity by a factor ten. This goal will be achieved mainly with a new interaction region layout, which will allow a stronger focusing of the colliding beams. The target will be to reduce the beam size in the interaction points by a factor of two, which requires doubling the aperture of the low-β (or inner triplet) quadrupole magnets. The use of Nb3Sn superconducting material and, as a result, the possibility of operating at magnetic field levels in the windings higher than 11 T will limit the increase in length of these quadrupoles, called MQXF, to acceptable levels. After the initial design phase, where the key parameters were chosen and the magnet's conceptual design finalized, the MQXF project, a joint effort between the U.S. LHC Accelerator Research Program and the Conseil Europeén pour la Recherche Nucleaíre (CERN), has now entered the construction and test phase of the short models. Concurrently, the preparation for the development of the full-length prototypes has been initiated. This paper will provide an overview of the project status, describing and reporting on the performance of the superconducting material, the lessons learnt during the fabrication of superconducting coils and support structure, and the fine tuning of the magnet design in view of the start of the prototyping phase.

Published
2016
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13. Test Results of the LARP Nb3Sn Quadrupole HQ03a

Author

DiMarco, J, Ambrosio, G, Anerella, M, Bajas, H, Chlachidze, G, Borgnolutti, F, Bossert, R, Cheng, D, Dietderich, D, Felice, H, Holik, T, Pan, H, Ferracin, P, Ghosh, A, Godeke, A, Hafalia, AR, Marchevsky, M, Orris, D, Ravaioli, E, Sabbi, G, Salmi, T, Schmalzle, J, Stoynev, S, Strauss, T, Sylvester, C, Tartaglia, M, Todesco, E, Wanderer, P, Wang, X, and Yu, M

Subjects
Physics::Accelerator Physics
Abstract

© 2016 IEEE. The U.S. LHC Accelerator Research Program (LARP) has been developing Nb3Sn quadrupoles of increasing performance for the high-luminosity upgrade of the large hadron collider. The 120-mm aperture high-field quadrupole (HQ) models are the last step in the RD phase supporting the development of the new IR Quadrupoles (MQXF). Three series of HQ coils were fabricated and assembled in a shell-based support structure, progressively optimizing the design and fabrication process. The final set of coils consistently applied the optimized design solutions and was assembled in the HQ03a model. This paper reports a summary of the HQ03a test results, including training, mechanical performance, field quality, and quench studies.

Published
2016
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14. Design of the Nb$_{3}$Sn Inner Triplet: Deliverable: D3.2

Author

Cavanna, E, Ferracin, P, Izquierdo Bermudez, S, Juchno, M, Perez, J C, Todesco, E, Ambrosio, G, Bossert, R, Chlachidize, G, Cooley, L D, Holik, E F, Kashikhin, V V, Krave, S, Nobrega, F, Novitski, I, Yul, M, Zlobin, A V, Anerella, M, Ghosh, A, Muratore, J, Schmalzle, J, Wanderer, P, Borgnolutti, F, Cheng, D, Dietderich, D, Felice, H, Godeke, A, Hafalia, R, Marchevsky, M, Prestemon, S, Sabbi, G L, and Wang, X

Subjects
Magnets for Insertion Regions [3], Nb3Sn Quadrupoles for the Inner Triplet [3.2], Accelerators and Storage Rings
Published
2015

15. Chapter 3: Insertion Magnets

Author

Ambrosio, G, Anerella, M., Bossert, R., Cheng, D., Chlachidze, G., Dietderich, D., Duarte Ramos, D., Fabbricatore, P., Farinon, S., Felice, H., Ferracin, P., Fessia, P., Garcia Matos, J., Ghosh, A., Hagen, P., Izquierdo Bermudez, S., Juchno, M., Krave, S., Marchevsky, M., Nakamoto, T., Ogitsu, T., Perez, J. C., Prin, H., Rifflet, J. M., Sabbi, G. L., Sasaki, K., Schmalzle, J., Segreti, M., Sugano, M., Todesco, E., Toral, F., Volpini, G., Wanderer, P., Wang, X., Weelderen, R. V., Xu, Q., and Yu, M.

Subjects
Physics::Instrumentation and Detectors, Accelerators and Storage Rings
Abstract

Chapter 3 in High-Luminosity Large Hadron Collider (HL-LHC) : Preliminary Design Report. The Large Hadron Collider (LHC) is one of the largest scientific instruments ever built. Since opening up a new energy frontier for exploration in 2010, it has gathered a global user community of about 7,000 scientists working in fundamental particle physics and the physics of hadronic matter at extreme temperature and density. To sustain and extend its discovery potential, the LHC will need a major upgrade in the 2020s. This will increase its luminosity (rate of collisions) by a factor of five beyond the original design value and the integrated luminosity (total collisions created) by a factor ten. The LHC is already a highly complex and exquisitely optimised machine so this upgrade must be carefully conceived and will require about ten years to implement. The new configuration, known as High Luminosity LHC (HL-LHC), will rely on a number of key innovations that push accelerator technology beyond its present limits. Among these are cutting-edge 11-12 tesla superconducting magnets, compact superconducting cavities for beam rotation with ultra-precise phase control, new technology and physical processes for beam collimation and 300 metre-long high-power superconducting links with negligible energy dissipation. The present document describes the technologies and components that will be used to realise the project and is intended to serve as the basis for the detailed engineering design of HL-LHC.

Published
2015

16. Performance of HQ02, an optimized version of the 120 mm $Nb_3Sn$ LARP quadrupole

Author

Chlachidze, G, Ambrosio, G, Anerella, M, Borgnolutti, F, Bossert, R, Caspi, S, Cheng, D W, Dietderich, D, Felice, H, Ferracin, P, Ghosh, A, Godeke, A, Hafalia A R, Marchevsky, M, Orris, D, Roy, P K, Sabbi, G L, Salmi, T, Schmalzle, J, Sylvester, C, Tartaglia, M, Tompkins, J, Wanderer, P, Wang, X R, and Zlobin, A V

Subjects
Physics::Accelerator Physics, Accelerators and Storage Rings
Abstract

In preparation for the high luminosity upgrade of the Large Hadron Collider (LHC), the LHC Accelerator Research Program (LARP) is developing a new generation of large aperture high-field quadrupoles based on Nb$_{3}$Sn technology. One meter long and 120 mm diameter HQ quadrupoles are currently produced as a step toward the eventual aperture of 150 mm. Tests of the first series of HQ coils revealed the necessity for further optimization of the coil design and fabrication process. A new model (HQ02) has been fabricated with several design modifications, including a reduction of the cable size and an improved insulation scheme. Coils in this magnet are made of a cored cable using 0.778 mm diameter Nb$_{3}$Sn strands of RRP 108/127 sub-element design. The HQ02 magnet has been fabricated at LBNL and BNL, and then tested at Fermilab. This paper summarizes the performance of HQ02 at 4.5 K and 1.9 K temperatures. In preparation for the high luminosity upgrade of the Large Hadron Collider (LHC), the LHC Accelerator Research Program (LARP) is developing a new generation of large aperture high-field quadrupoles based on Nb_3Sn technology. One meter long and 120 mm diameter HQ quadrupoles are currently produced as a step toward the eventual aperture of 150 mm. Tests of the first series of HQ coils revealed the necessity for further optimization of the coil design and fabrication process. A new model (HQ02) has been fabricated with several design modifications, including a reduction of the cable size and an improved insulation scheme. Coils in this magnet are made of a cored cable using 0.778 mm diameter Nb_3Sn strands of RRP 108/127 subelement design. The HQ02 magnet has been fabricated at LBNL and BNL, and then tested at Fermilab. This paper summarizes the performance of HQ02 at 4.5 K and 1.9 K temperatures.

Published
2014

17. Accelerator Quality HTS Dipole Magnet Demonstrator designs for the EuCARD-2, 5 Tesla 40 mm Clear Aperture Magnet

Author

Kirby, G, van Nugteren, J, Ballarino, A, Bottura, L, Chouika, N, Clement, S, Datskov, V, Fajardo, L, Fleiter, J, Gauthier, R, Lambert, L, Lopes, M, Perez, J, DeRijk, G, Rijllart, A, Rossi, L, Ten Kate, H, Durante, M, Fazilleau, P, Lorin, C, Haro, E, Stenvall, A, Caspi, S, Marchevsky, M, Goldacker, W, and Kario, A

Subjects
5 T HTS Dipole Magnet Design and Construction [10.3], Future Magnets (MAG) [10], Accelerators and Storage Rings
Abstract

Future high-energy accelerators will need very high magnetic fields in the range of 20 T. The EuCARD-2 work-package-10 is a collaborative push to take HTS materials into an accelerator quality demonstrator magnet. The demonstrator will produce 5 T standalone and between 17 T and 20 T, when inserted into the 100 mm aperture of Fresca-2 high field out-sert magnet. The HTS magnet will demonstrate the field strength and field quality that can be achieved. An effective quench detection and protection system will have to be developed to operate with the HTS superconducting materials. This paper presents a ReBCO magnet design using multi strand Roebel cable that develops a stand-alone field of 5 T in a 40 mm clear aperture and discusses the challenges associated with good field quality using this type of material. A selection of magnet designs is presented as result of a first phase of development.

Published
2014

18. Field Quality Measurements of LARP Nb$_{3}$Sn Magnet HQ02

Author

DiMarco, J, Ambrosio, G, Buehler, M, Chlachidze, G, Orris, D, Sylvester, C, Tartaglia, M, Velev, G, Yu, M, Zlobin, AV, Ghosh, A, Schmalzle, J, Wanderer, P, Borgnolutti, F, Cheng, D, Dietderich, D, Felice, H, Godeke, A, Hafalia, R, Joseph, J, Lizarazo, J, Marchevsky, M, Prestemon, SO, Sabbi, GL, Salehi, A, Wang, X, Ferracin, P, and Todesco, E

Subjects
General Physics, Physics::Instrumentation and Detectors, Field quality, superconducting accelerator magnets, Physics::Accelerator Physics, Materials Engineering, Electrical and Electronic Engineering, Condensed Matter Physics, Accelerators and Storage Rings, magnetic measurement
Abstract

Large-aperture, high-field, Nb$_{3}$Sn quadrupoles are being developed by the US LHC accelerator research program (LARP) for the High luminosity upgrade of the Large Hadron Collider (HiLumi-LHC). The first 1 m long, 120 mm aperture prototype, HQ01, was assembled with various sets of coils and tested at LBNL and CERN. Based on these results, several design modifications have been introduced to improve the performance for HQ02, the latest model. From the field quality perspective, the most relevant improvements are a cored cable for reduction of eddy current effects, and more uniform coil components and fabrication processes. This paper reports on the magnetic measurements of HQ02 during recent testing at the Vertical Magnet Test Facility at Fermilab. Results of baseline measurements performed with a new multi-layer circuit board probe are compared with the earlier magnet. An analysis of probe and measurement system performance is also presented.

Published
2014

19. Test of Optimized 120-mm LARP $Nb_{3}S_n$ Quadrupole Coil Using Magnetic Mirror Structure

Author

Chlachidze, G, Ambrosio, G, Andreev, N, Anerella, M, Barzi, E, Bossert, R, Caspi, S, Cheng, D, Dietderich, D, Felice, H, Ferracin, P, Ghosh, A, Godeke, A, Hafalia, A R, Kashikhin, V V, Lamm, M, Marchevsky, M, Nobrega, A, Novitski, I, Orris, D, Sabbi, G L, Schmalzle, J, Wanderer, P, and Zlobin, A V

Subjects
Quantitative Biology::Biomolecules, Accelerators and Storage Rings
Abstract

The US LHC accelerator research program (LARP) is developing a new generation of large - aperture high - field quadrupoles based on Nb 3 Sn conductor for the High luminosity upgrade of Large Hadron Collider (HiLumi - LHC). Tests of the first series of 120 - mm aperture HQ coils revealed the necessity for further optimization of the coil design and fabrication process. Modifications in coil design were gradually implemented in two HQ coils previously tested at Fermi National Accelerato r Laboratory (Fermilab) using a magnetic mirror structure (HQM01 and HQM02). This paper describes the construction and test of an HQ mirror model with a coil of optimized design and with an interlayer resistive core in the conductor. The cable for this co il was made of a smaller diameter strand, providing more room for coil expansion during reaction. The 0.8 - mm strand, used in all previous HQ coils was replaced with a 0.778 - mm Nb 3 Sn strand of RRP 108/127 sub - element design. The coil was instrumented with voltage taps, heaters, and strain gauges to monitor mechanical and thermal properties and quench performance of the coil.

Published
2013

20. Test Result of the Short Models MQXFS3 and MQXFS5 for the HL-LHC Upgrade.

Author

Bajas, Hugues, Ambrosio, Giorgio, Ballarino, A., Bajko, Marta, Bordini, B., Bourcey, N., Cheng, D. W., Cabon, M., Chiuchiolo, A., Chlachidze, G., Felice, H., Fiscarelli, L., Juchno, M., Izquierdo Bermudez, Susana, Guinchard, M., Kopal, J., Lackner, F., Marchevsky, M., Nobrega, F., and Pan, H.

Subjects
LARGE Hadron Collider, COILS (Magnetism), MAGNETIC fields, LUMINOSITY
Abstract

In the framework of the High-Luminosity Large HadronCollider, the installation of a new generation of quadrupole magnets is foreseen on each side of ATLAS and CMS experiments. The new magnets are based on Nb3Sn technology and shall be able to reach an ultimate current of 17.9 kA with a peak field of 12.3 T in the coil. In 2016 and 2017, the first two short models, called MQXFS3 and MQXFS5, have been tested at 4.2 and 1.9 K in the two new test benches at the European Organization for Nuclear Research. This paper presents the result of the quench performance of the two models; the first magnet reached nominal but failed to reach ultimate, showing detraining in one coil. MQXFS5 reached ultimate performance without any detraining phenomena, validating the PIT conductor used for the first time in this magnet program. [ABSTRACT FROM AUTHOR]

Published
2018
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21. Improved Modeling of Canted-Cosine-Theta Magnets.

Author

Brouwer, L., Arbelaez, D., Caspi, S., Marchevsky, M., and Prestemon, S.

Subjects
THETA functions, COSINE function, MAGNETIC dipoles, MAGNETIC structure, CANTED spin arrangements
Abstract

The Canted-Cosine-Theta is a design option for the next generation of high field superconducting dipoles being pursued within the US Magnet Development Program. This paper presents new modeling techniques developed for design and analysis of CCT magnets. For mechanical modeling in ANSYS, three approaches with increasing accuracy are compared: 2-D symmetry models; 3-D periodic symmetry models; and full 3-D models. Methods for the static and transient magnetic simulation using ANSYS are presented with a focus on circuit-coupled models for predicting magnet behavior following quench. Where applicable, simulation results are compared to data from CCT magnet tests at Berkeley. [ABSTRACT FROM AUTHOR]

Published
2018
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22. Quench Location in the LARP MQXFS1 Prototype.

Author

Strauss, T., Ambrosio, G., Chlachidze, G., Ferracin, P., Marchevsky, M., Sabbi, G., and Stoynev, S.

Subjects
PROTOTYPES, LUMINOSITY, QUADRUPOLES, ELECTRIC potential, ELECTROMAGNETIC theory
Abstract

The high luminosity upgrade project U.S. LARP/HiLumi has successfully tested the first 1.5 m prototype quadrupole MQXFS1 at Fermilab' Magnet test facility. Several thermal cycles and test programs were performed, with different preload configurations. To localize and characterize quenches, a quench antenna and voltage taps are used. The quench antenna was placed inside a warm bore of an anticryostat centered in the magnet. We varied the length between quench antenna segments from 2.54 to 15.24 cm, and shifted the location of the antenna to localize the quench origin along the various wedge and spacers transitions in the lead end of the magnet. We present results on the identified quench locations for the second and third thermal cycle in this paper. [ABSTRACT FROM AUTHOR]

Published
2018
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23. Progress in the long $Nb_3Sn$ quadrupole R&D by LARP

Author

Ambrosio, G, Andreev, N, Anerella, M, Barzi, E, Bocian, D, Bossert, r, Buehler, M, Caspi, S, Chlachidze, G, Dietderich, D, DiMarco, J, Escallier, J, Felice, H, Ferracin, P, Ghosh, A, Godeke, A, Hafalia, A R, Hannaford, R, Jochen, G, Kim, M J, Kovach, P, Lamm, M, Marchevsky, M, McInturff, A, Nobrega, A, Orris, D, Prebys, E, Prestemon, G I, Sabbi, G L, Schmalzle, J, Sylvester, C, Tartaglia, M, Turroni, D, Velev, G, Wanderer, P, Whitson, G, and Zlobin, A V

Subjects
Accelerators and Storage Rings
Abstract

After the successful test of the first long quadrupole (LQS01) the US LHC Accelerator Research Program (LARP, a collaboration of BNL, FNAL, LBNL and SLAC) is assessing training memory, reproducibility, and other accelerator quality features of long quadrupole magnets. LQS01b (a reassembly of LQS01 with more uniform and higher pre-stress) was subjected to a full thermal cycle and reached the previous plateau of 222 T/m at 4.5 K in two quenches. A new set of four coils, made of the same type of conductor used in LQS01 (RRP 54/61 by Oxford Superconducting Technology), was assembled in the LQS01 structure and tested at 4.5 K and lower temperatures. The new magnet (LQS02) reached the target gradient (200 T/m) only at 2.6 K and lower temperatures, at inter- mediate ramp rates. The preliminary test analysis, here reported, showed a higher instability in the limiting coil than in the other coils of LQS01 and LQS02.

Published
2012

26. Characterization of Insulating Coatings for Wind-and-React Coil Fabrication.

Author

Cheng, D. W., Dietderich, D. R., Godeke, A., Hafalia, A. R., Marchevsky, M., Prestemon, S. O., Roy, P. K., Sabbi, G., and Swenson, C. A.

Subjects
SURFACE coatings, TORROIDAL coils, ELECTRIC insulators & insulation, BREAKDOWN voltage, LOW temperature engineering, NIOBIUM compounds, MICROFABRICATION, ELECTRICAL conductors
Abstract

Electrical insulation breakdown between conductor and coil parts and structures is a limiting factor in the performance of high-field magnets. We have evaluated various insulation coatings for possible application in both Nb3Sn and Bi-2212 coil fabrication. Such coatings must be robust to maintain structural integrity and provide adequate voltage standoff after the wind-and-react coil fabrication process. Such processes are characterized by reaction temperatures of 650°C in an inert atmosphere for Nb3Sn and 890°C in a pure oxygen atmosphere for Bi-2212, and down to cryogenic temperatures when coils are in service. We present a method of testing standardized samples and report the performance characteristics of oxide layers produced (or applied) by plasma-spray, surface conversion, and "paintable" coatings in common areas of voltage breakdown in coil parts. We also address material compatibility and durability during hightemperature heat treatment and cryogenic shock. Suitable coatings selected in the testing process will be instrumental in improving the performance of future wind-and-react coils. [ABSTRACT FROM AUTHOR]

Published
2014
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27. Flux droplet formation in NbSe2 single crystals observed by decoration

Author

Marchevsky, M., Gurevich, L.A., Kes, P.H., and Aarts, J.

Abstract

A potential barrier of geometrical origin, characterized by a barrier field Hp, governs vortex penetration in thin superconducting samples. We observed this effect by the decoration of crystals of NbSe2. Upon zero field cooling and applying a field Ha

Published
1995
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28. Design of an 18-T Canted Cosine–Theta Superconducting Dipole Magnet.

Author

Caspi, S., Brouwer, L., Lipton, T., Hafalia, A., Prestemon, S., Dietderich, D., Felice, H., Wang, X., Rochepault, E., Godeke, A., Gourlay, S., and Marchevsky, M.

Subjects
MAGNETIC dipoles, PARTICLE accelerators, ELECTROMAGNETS, LORENTZ force, SUPERCONDUCTORS
Abstract

A multilayer high field dipole magnet has been designed for future particle accelerators. The magnet has eight layers of a \Nb3\Sn outsert coil and four layers of a Bi-2212 insert coil (see Figs. 1 and 2). The layers are graded, delivering a short-sample field of 17.7 T in a 40-mm bore. The coil layers are of a canted cosine–theta design—with ribs and spars that guide and support the coil windings, shape the field, intercept Lorentz forces, and minimize conductor prestress. We present a general overview of the concept and report on the magnetic and mechanical design including an initial cost estimate and construction plan. [ABSTRACT FROM PUBLISHER]

Published
2015
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29. Quench protection challenges in long nb3sn accelerator magnets.

Author

Salmi, Tiina-Mari, Ambrosio, G., Caspi, S., Chlachidze, Guram, Dhallé, Marc, Felice, Helene, Ferracin, Paolo, Marchevsky, M., Sabbi, G. L., and ten Kate, H. H. J.

Subjects
SUPERCONDUCTING magnets, PHYSICAL measurements, TEMPERATURE effect, ENERGY consumption, HEATING, PHYSICS experiments, COMPUTER simulation
Abstract

The quench protection of the several meter long, large aperture high-field Nb3Sn quadrupoles that the LARP collaboration is developing for the LHC interaction region upgrade, requires efficient protection heaters to quickly generate large resistive segments across the windings. To support the protection design, experiments in the recently tested LARP R&D magnets are aimed to characterize the coil response to different protection schemes. In particular, the delay to quench and the final hotspot temperatures are evaluated after firing the heaters at different powering regimes and coverage. Also, the contribution of external energy extraction is investigated. Based on the performed studies and computer simulations, it seems that if the same protection efficiency per unit length that is measured in a 1 m long model magnet can be scaled to a 3.6 m long magnet, and the heater coverage can be improved, about 1 MJ/m of stored energy can be absorbed in the magnet after a quench. However, significant technology developments are needed to scale the protection heater efficiency to longer magnets and to increase the coverage. [ABSTRACT FROM AUTHOR]

Published
2012
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31. Test of the High-Field \Nb3\Sn Dipole Magnet HD3b.

Author

Marchevsky, M., Caspi, S., Cheng, D. W., Dietderich, D. R., DiMarco, J., Felice, H., Ferracin, P., Godeke, A., Hafalia, A. R., Joseph, J., Lizarazo, J., Roy, P. K., Sabbi, G., Salmi, T., Turqueti, M., Wang, X., and Prestemon, S.

Subjects
*MAGNETIC dipoles, *MAGNETS, *ELECTRIC insulators & insulation, *THERMOCYCLING, *ACOUSTIC emission
Abstract

We report test results for the one meter long dipole HD3b, a block-type accelerator quality \Nb3\Sn magnet built at LBNL with operational bore fields in the range of 13–15 T. The magnet is an upgrade of the previously reported HD2 and HD3a versions, with several modifications implemented to improve conductor positioning, reduce cable “hard-way” bending radius, and strengthen electrical insulation between cables and coil parts. The magnet exhibited long training behavior, but showed a good “memory” of the trained state upon thermal cycling. Ramp-rate dependence of the quench current, field quality performance characteristics, and protection heater studies were conducted. Quench propagation velocity and quench locations were determined based on the voltage signals; quench localization was further improved using inductive quench antenna and acoustic emission sensors. Short- and long-term acoustic precursors to quenching were observed. [ABSTRACT FROM PUBLISHER]

Published
2014
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32. Multipoles Induced by Inter-Strand Coupling Currents in LARP \Nb3\Sn Quadrupoles.

Author

Wang, X., Ambrosio, G., Borgnolutti, F., Buehler, M., Chlachidze, G., Dietderich, D. R., DiMarco, J., Felice, H., Ferracin, P., Ghosh, A., Godeke, A., Marchevsky, M., Orris, D., Prestemon, S. O., Sabbi, G.., Sylvester, C., Tartaglia, M., Todesco, E., Velev, G., and Wanderer, P.

Subjects
QUADRUPOLES, MAGNETS, MAGNETIC measurements, ELECTROMAGNETS, STAINLESS steel
Abstract

The U.S. LHC Accelerator Research Program has been developing \Nb3\Sn quadrupole magnets of progressively increasing performance and complexity for the High-Luminosity LHC project. The magnets are wound with Rutherford cables following the wind-and-react process. The resulting inter-strand coupling can generate strong field distortions during current ramp. The latest series of 120 mm aperture magnets (HQ) are designed and built for high field quality, offering an opportunity for detailed studies of these effects. Magnetic measurements of first-generation HQ magnets showed strong ramp-rate dependence. A stainless-steel core was introduced for the second generation of magnet coils to control the inter-strand coupling currents and the resulting dynamic multipoles. We report the observed dynamic effects and compare with calculations taking into account the coil geometry and cross-contact resistance in the Rutherford cable. In particular, the dependence of field quality on width and position of the stainless steel core is discussed. [ABSTRACT FROM PUBLISHER]

Published
2014
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33. Fabrication of a Second-Generation of \Nb3 \Sn Coils for the LARP HQ02 Quadrupole Magnet.

Author

Borgnolutti, F., Ambrosio, G., Bossert, R., Chlachidze, G., Cheng, D. W., Dietderich, D. R., Felice, H., Godeke, A., Hafalia, A. R., Marchevsky, M., Roy, P. K., Sabbi, G. L., Schmalzle, J., Wanderer, P., and Yu, M.

Subjects
LUMINOSITY, MAGNETS, SUPERCONDUCTING magnets, MAGNETISM, BIOMAGNETISM
Abstract

In the framework of the Large Hadron Collider Luminosity upgrade (HiLumi-LHC) project, the US LHC accelerator research program is developing high-gradient, large-aperture \Nb3 \Sn quadrupole magnets for the LHC interaction regions. The fabrication and tests of a first series of 120-mm-aperture “HQ01” coils revealed design issues that resulted in limited performance. A second series of coils was fabricated in which a number of improved features were implemented (HQ02 coils). The improvements were partly validated with the successful test of an HQ02 coil in a mirror structure, which reached 97% of the short sample. Here, we review the modifications in the coil design and the coil fabrication process, report the issues met during the fabrication, give details of the few differences that exist within the set of HQ02 coils, and discuss a list of further improvements that will be implemented in a third series of HQ coils. [ABSTRACT FROM PUBLISHER]

Published
2014
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34. A review of conductor performance for the LARP high-gradient quadrupole magnets.

Author

Godeke, A., Chlachidze, G., Dietderich, D. R., Ghosh, A. K., Marchevsky, M., Mentink, M. G. T ., and Sabbi, G. L.

Subjects
ELECTRIC current measurement, PARAMETERIZATION, QUADRUPOLES, CRITICAL current density (Superconductivity), CIPHER & telegraph codes, ELECTRICAL conductors
Abstract

We summarize critical current measurements and parameterizations of the data of 112 round wires and extracted strands that were reacted with the first 17 coils for the high-gradient quadrupole (HQ) magnets for the US LHC Accelerator Research Program (LARP). We standardize the strand parameterizations and coil 'short sample' calculations, and demonstrate that the entire critical current database can be captured in two scaling parameters per coil. These parameters summarize the short sample performance for each coil for either HQ magnet tests, or mirror tests of individual coils. We also demonstrate that for RRP R conductors, generic strain scaling parameters can be derived for at least four substantially different wire configurations, and standardize self-field corrections for LARP. The parameterized conductor performance is used to judge the performance of the HQ magnets and mirror tests. We find that although the HQ magnets reach around 86% of their short sample limitations, they are limited by factors other than the critical current of the conductor. Individual coils in mirror tests reach up to 98% of the expected performance, and do appear limited by the critical current of the conductor. Detailed analysis of short sample performance through accurate parameterizations simplifies the accessibility of short sample data, and enables accurate judgment of magnet performance as well as conductor and cable quality. [ABSTRACT FROM AUTHOR]

Published
2013
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35. Quench Performance of HQ01, a 120 mm Bore LARP Quadrupole for the LHC Upgrade.

Author

Marchevsky, M., Ambrosio, G., Bingham, B., Bossert, R., Caspi, S., Cheng, D. W., Chlachidze, G., Dietderich, D., DiMarco, J., Felice, H., Ferracin, P., Ghosh, A., Hafalia, A. R., Joseph, J., Lizarazo, J., Sabbi, G. L., Schmalzle, J., Wanderer, P., Wang, X., and Zlobin, A. V.

Subjects
*ELECTRIC insulators & insulation, *QUADRUPOLES, *ELECTRIC coils, *SUPERCONDUCTING magnets, *ACCELERATOR magnets, *NIOBIUM, *TIN
Abstract

We report quench test results for the 1-meter long, 120 mm aperture Nb3Sn quadrupole magnet, HQ01, designed, fabricated and tested for the LHC Accelerator Research Program (LARP). The magnet has a design gradient of 219 T/m at 1.9 K and peak field of \sim15 T. Earlier tests (HQ01a, b) showed peak gradients of 152 T/m at 4.4 K but also revealed electrical insulation weaknesses that ultimately led to coil damage. Structural and electrical improvements incorporated into HQ01c magnet have assured and tracked the electrical integrity of the coils. The most recent HQ01d and HQ01e tests demonstrated gradients of 170 T/m at 4.4 K (86% of short sample critical current) with moderate training. By analyzing magnet voltage test data, quench propagation velocities and quench locations were determined. Most of the quenches tended to cluster around the pole region of the coils. Eight PC-board quench antennas were installed to better identify quench locations. We monitored longitudinal propagation of pole-turn quenches and correlated inductive responses of the quench antennas with magnet voltages. On down-ramps, the HQ magnet exhibited no quenches at rates up 150 A/s; the experimental ramp-rate dependence was analyzed using a simple ‘loss model’. [ABSTRACT FROM PUBLISHER]

Published
2012
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36. Impact of Coil Compaction on \ Nb3{\ {Sn}} LARP HQ Magnet.

Author

Felice, H., Ambrosio, G., Anerella, M. D., Bocian, D., Bossert, R., Caspi, S., Collins, B., Cheng, D., Chlachidze, G., Dietderich, D. R., Ferracin, P., Godeke, A., Ghosh, A., Hafalia, A. R., Joseph, J. M., Krishnan, J., Marchevsky, M., Sabbi, G., Schmalzle, J., and Wanderer, P.

Subjects
ELECTRIC coils, LARGE Hadron Collider, RESEARCH & development, LUMINOSITY, ALUMINUM alloys
Abstract

In the past two years the US LARP program carried out five tests on a quadrupole magnet aimed at the high luminosity upgrade of Large Hadron Collider (HiLumi-LHC). The 1-meter long, 120 mm bore \ Nb3{\ {Sn}} IR quadrupole magnet (HQ) with a short sample gradient of 219 T/m at 1.9 K and a conductor peak field of 15 T is part of the US LHC Accelerator Research Program (LARP). In a series of tests, carried out at 4.4 K, the magnet reached a maximum “short-sample” performance of 86%. The tests exposed several shortcomings that are now being addressed in a Research & Development program. This paper summarizes the magnet test results, reveals findings, R&D actions and future improvements. [ABSTRACT FROM PUBLISHER]

Published
2012
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37. Design of LD1, a Large-Aperture High-Field Nb3Sn Dipole Magnet.

Author

Ferracin, P., Cheng, D. W., Dietderich, D. R., Felice, H., Godeke, A., Hafalia, A. R., Marchevsky, M., Sabbi, G., and Wang, X.

Subjects
MAGNETIC dipoles, ACCELERATOR magnets, SUPERCONDUCTING magnets, HIGH temperature superconductors, HOMOGENEITY
Abstract

In order to continue supporting the development of accelerator magnets for the next generation of particle colliders, the LBNL Superconducting Magnet Program has started the design and fabrication of the Nb3Sn Large-aperture Dipole LD1. The goal of the magnet is to generate a dipole field of 13 T to 15 T in a clear aperture of 144 mm \times 94 mm, enabling high-field tests of Rutherford cables and insert coils made of Nb3Sn or high temperature superconductors (HTS), like Bi-2212, YBCO, and Bi-2223. The bore size will also accommodate large Cable-In-Conduit Conductors (CICC's), including ITER cables. We describe in this paper the design of LD1, in particular cable geometry, coil lay-out and support structure. Operational conditions based on strand measurements will be discussed, focusing on coil peak fields in straight section and end region, bore field homogeneity, and stress on the conductor during assembly, cool-down and excitation. [ABSTRACT FROM PUBLISHER]

Published
2012
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38. Mechanical Behavior of HQ01, a \Nb3\Sn Accelerator-Quality Quadrupole Magnet for the LHC Luminosity Upgrade.

Author

Ferracin, P., Ambrosio, G., Anerella, M., Bossert, R., Caspi, S., Chlachidze, G., Cheng, D. W., Dietderich, D. R., Felice, H., Ghosh, A., Hafalia, A. R., Lizarazo, J., Marchevsky, M., Joseph, J., Sabbi, G., Schmalzle, J., Wanderer, P., Wang, X., and Zlobin, A. V.

Subjects
MECHANICAL behavior of materials, QUADRUPOLES, LARGE Hadron Collider, LUMINOSITY, FIELD emission electron microscopy
Abstract

HQ01 is a superconducting quadrupole magnet under development by the LHC Accelerator Research Program (LARP) as a part of an R&D effort to demonstrate that Nb3Sn magnet technology is a viable option for a future luminosity upgrade of the LHC. The design is characterized by a 120 mm bore, a maximum gradient of 219 T/m at 1.9 K, and a support structure based on an aluminum shell pre-tensioned by water-pressurized bladders. The shell-based structure concept has already been successfully implemented in previous LARP quadrupole magnets. In HQ01, the structure incorporates additional features designed to provide full alignment between the support structure components and the coils. Specifically, the coil azimuthal alignment is achieved through outer layer pole keys which, by intercepting part of the force applied by bladders and shell, remain clamped to bolted aluminum collars from assembly to full excitation. A sequence of assemblies and cool-downs were executed with different keys sizes to characterize the alignment system and its impact on coil pre-load, at both room temperature and at 4.5 K. This paper reports on the mechanical behavior of the HQ01, by summarizing the strain gauge data and comparing them with FEM model predictions. [ABSTRACT FROM PUBLISHER]

Published
2012
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39. Imaging of topological magnetic pinning in superconductor-ferrimagnet bilayer with scanning Hall microscopy.

Author

Marchevsky, M, Higgins, M J, Bhattacharya, S, and Fratello, V J

Subjects
*IMAGING systems, *FLUX pinning, *SUPERCONDUCTORS, *FERRIMAGNETISM, *SCANNING electron microscopy, *ELECTRIC properties of thin films, *ANISOTROPY, *SPUTTERING (Physics)
Abstract

In a superconducting film deposited on ferromagnetic substrate with perpendicular magnetic anisotropy, vortex matter is confined by the magnetic potential landscape. Using scanning Hall microscopy we visualize flux accumulation and removal in a superconductor-ferrimagnet (S/F) bilayer prepared by rf sputtering of thin niobium film on bismuth-doped rare-earth iron garnet. Penetration of the perpendicular magnetic field in the S/F bilayer follows magnetic domain boundaries and is laterally guided by the garnet magnetization component along the field direction. Upon field removal, localization of the remnant flux at the disclination points of the labyrinthine domain pattern is observed. Our experiments show evidence for strong vortex pinning due the special topology of the domain pattern. Ac magnetic imaging of the transport current distribution in the bilayer reveals complex flow paths commensurate with the magnetic domain boundaries. Topological magnetic pinning can be a useful tool for enhancement and control of critical current in thin film superconductors. [ABSTRACT FROM AUTHOR]

Published
2011
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43. Current distribution monitoring enables quench and damage detection in superconducting fusion magnets.

Author

Teyber R, Weiss J, Marchevsky M, Prestemon S, and van der Laan D

Abstract

Fusion magnets made from high temperature superconducting ReBCO CORC ®  cables are typically protected with quench detection systems that use voltage or temperature measurements to trigger current extraction processes. Although small coils with low inductances have been demonstrated, magnet protection remains a challenge and magnets are typically operated with little knowledge of the intrinsic performance parameters. We propose a protection framework based on current distribution monitoring in fusion cables with limited inter-cable current sharing. By employing inverse Biot-Savart techniques to distributed Hall probe arrays around CORC ®  Cable-In-Conduit-Conductor (CICC) terminations, individual cable currents are recreated and used to extract the parameters of a predictive model. These parameters are shown to be of value for detecting conductor damage and defining safe magnet operating limits. The trained model is then used to predict cable current distributions in real-time, and departures between predictions and inverse Biot-Savart recreated current distributions are used to generate quench triggers. The methodology shows promise for quality control, operational planning and real-time quench detection in bundled CORC ®  cables for compact fusion reactors., (© 2022. The Author(s).)

Published
2022
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44. Driven dynamics of the vortex-phase mixture near the peak effect: the "vortex capacitor".

Author

Marchevsky M, Higgins MJ, and Bhattacharya S

Abstract

A phenomenological model of vortex dynamics in the vicinity of the peak effect, which considers a coexistence of two vortex phases with different critical current densities, is proposed. It provides a quantitative description of the widely reported anomalous dynamic effects in terms of "contamination" and "annealing" of the vortex matter. Scanning ac Hall microscopy in the superconductor NbSe(2) is used to obtain the first real-space visualization of pinning in the driven vortex lattice. The results are consistent with the proposed scenario.

Published
2002
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