Your search keyword '"Superconducting"' showing total 27 results

1. Towards 20 T Hybrid Accelerator Dipole Magnets

Author

Ferracin, P, Ambrosio, G, Arbelaez, D, Brouwer, L, Barzi, E, Cooley, L, Fajardo, L Garcia, Gupta, R, Juchno, M, Kashikhin, V, Marinozzi, V, Novitski, I, Rochepault, E, Stern, J, Zlobin, A, and Zucchi, N

Subjects

Engineering, Electrical Engineering, Physical Sciences, Dipole magnets, hybrid magnets, HTS, Nb3Sn magnets, superconducting, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics, Electrical engineering, Condensed matter physics

Abstract

The most effective way to achieve very high collision energies in a circular particle accelerator is to maximize the field strength of the main bending dipoles. In dipole magnets using Nb-Ti superconductor the practical field limit is considered to be 8-9 T. When Nb3Sn superconductor material is utilized, a field level of 15-16 T can be achieved. To further push the magnetic field beyond the Nb3Sn limits, High Temperature Superconductors (HTS) need to be considered in the magnet design. The most promising HTS materials for particle accelerator magnets are Bi2212 and REBCO. However, their outstanding performance comes with a significantly higher cost. Therefore, an economically viable option towards 20 T dipole magnets could consist in an 'hybrid' solution, where both HTS and Nb3Sn materials are used. We discuss in this paper preliminary conceptual designs of various 20 T hybrid magnet concepts. After the definition of the overall design criteria, the coil dimensions and parameters are investigated with finite element models based on simple sector coils. Preliminary 2D cross-section computation results are then presented and three main layouts compared: cos-theta, block, and common-coil. Both traditional designs and more advanced stress-management options are considered.

Published

2022

2. The 16 T Dipole Development Program for FCC and HE-LHC

Author

Schoerling, D, Arbelaez, D, Auchmann, B, Bajko, M, Ballarino, A, Barzi, E, Bellomo, G, Benedikt, M, Bermudez, SI, Bordini, B, Bottura, L, Brouwer, L, Bruzzone, P, Caiffi, B, Caspi, S, Chakraborti, A, Coatanea, E, De Rijk, G, Dhalle, M, Durante, M, Fabbricatore, P, Farinon, S, Felice, H, Fernandez, A, Fernandez, IS, Gao, P, Gold, B, Gortsas, T, Gourlay, S, Juchno, M, Kashikhin, V, Kokkinos, C, Kokkinos, S, Koskinen, K, Lackner, F, Lorin, C, Loukas, K, Louzguiti, A, Lyytikainen, K, Mariotto, S, Marchevsky, M, Montenero, G, Munilla, J, Novitski, I, Ogitsu, T, Pampaloni, A, Perez, JC, Pes, C, Petrone, C, Polyzos, D, Prestemon, S, Prioli, M, Ricci, AM, Rifflet, JM, Rochepault, E, Russenschuck, S, Salmi, T, Santillana, IA, Savary, F, Scheuerlein, C, Segreti, M, Senatore, C, Sorbi, M, Statera, M, Stenvall, A, Tavian, L, Tervoort, T, Tommasini, D, Toral, F, Valente, R, Velev, G, Verweij, AP, Wessel, S, Wolf, F, Zimmermann, F, and Zlobin, AV

Subjects

FCC, Nb3Sn, superconducting, T, General Physics, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering

Abstract

A future circular collider (FCC) with a center-of-mass energy of 100 TeV and a circumference of around 100 km, or an energy upgrade of the LHC (HE-LHC) to 27 TeV require bending magnets providing 16 T in a 50-mm aperture. Several development programs for these magnets, based on Nb3Sn technology, are being pursued in Europe and in the U.S. In these programs, cos-theta, block-type, common-coil, and canted-cos-theta magnets are explored; first model magnets are under manufacture; limits on conductor stress levels are studied; and a conductor with enhanced characteristics is developed. This paper summarizes and discusses the status, plans, and preliminary results of these programs.

Published

2019

3. The 16 T Dipole Development Program for FCC and HE-LHC

Author

Schoerling, Daniel, Arbelaez, Diego, Auchmann, Bernhard, Bajko, Marta, Ballarino, Amalia, Barzi, Emanuela, Bellomo, Giovanni, Benedikt, Michael, Bermudez, Susana Izquierdo, Bordini, Bernardo, Bottura, Luca, Brouwer, Lucas, Bruzzone, Pierluigi, Caiffi, Barbara, Caspi, Shlomo, Chakraborti, Ananda, Coatanea, Eric, de Rijk, Gijs, Dhalle, Marc, Durante, Maria, Fabbricatore, Pasquale, Farinon, Stefania, Felice, Helene, Fernandez, Alejandro, Fernandez, Inigo Sancho, Gao, Peng, Gold, Barbara, Gortsas, Thodoris, Gourlay, Steve, Juchno, Mariusz, Kashikhin, Vadim, Kokkinos, Charilaos, Kokkinos, Sotiris, Koskinen, Kari, Lackner, Friedrich, Lorin, Clement, Loukas, Konstantinos, Louzguiti, Alexandre, Lyytikainen, Kari, Mariotto, Samuele, Marchevsky, Maxim, Montenero, Giuseppe, Munilla, Javier, Novitski, Igor, Ogitsu, Toru, Pampaloni, A, Perez, JC, Pes, C, Petrone, C, Polyzos, D, Prestemon, S, Prioli, M, Ricci, AM, Rifflet, JM, Rochepault, E, Russenschuck, S, Salmi, T, Santillana, IA, Savary, F, Scheuerlein, C, Segreti, M, Senatore, C, Sorbi, M, Statera, M, Stenvall, A, Tavian, L, Tervoort, T, Tommasini, D, Toral, F, Valente, R, Velev, G, Verweij, AP, Wessel, S, Wolf, F, Zimmermann, F, and Zlobin, AV

Subjects

Nuclear and Plasma Physics, Physical Sciences, FCC, Nb3Sn, superconducting, T, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics, Electrical engineering, Condensed matter physics

Abstract

A future circular collider (FCC) with a center-of-mass energy of 100 TeV and a circumference of around 100 km, or an energy upgrade of the LHC (HE-LHC) to 27 TeV require bending magnets providing 16 T in a 50-mm aperture. Several development programs for these magnets, based on Nb3Sn technology, are being pursued in Europe and in the U.S. In these programs, cos-theta, block-type, common-coil, and canted-cos-theta magnets are explored; first model magnets are under manufacture; limits on conductor stress levels are studied; and a conductor with enhanced characteristics is developed. This paper summarizes and discusses the status, plans, and preliminary results of these programs.

Published

2019

4. Status of the 16 T dipole development program for a future hadron collider

Author

Tommasini, D, Arbelaez, D, Auchmann, B, Bajas, H, Bajko, M, Ballarino, A, Barzi, E, Bellomo, G, Benedikt, M, Bermudez, SI, Bordini, B, Bottura, L, Brower, L, Buzio, M, Caiffi, B, Caspi, S, Dhalle, M, Durante, M, DeRijk, G, Fabbricatore, P, Farinon, S, Ferracin, P, Gao, P, Gourlay, S, Juchno, M, Kashikhin, V, Lackner, F, Lorin, C, Marchevsky, M, Marinozzi, V, Martinez, T, Munilla, J, Novitski, I, Ogitsu, T, Ortwein, R, Perez, JC, Petrone, C, Prestemon, S, Prioli, M, Rifflet, JM, Rochepault, E, Russenschuck, S, Salmi, T, Savary, F, Schoerling, D, Segreti, M, Senatore, C, Sorbi, M, Stenvall, A, Todesco, E, Toral, F, Verweij, AP, Wessel, S, Wolf, F, and Zlobin, AV

Subjects

Future circular collider, superconducting, Nb3Sn, T, General Physics, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering

Abstract

A next step of energy increase of hadron colliders beyond the LHC requires high-field superconducting magnets capable of providing a dipolar field in the range of 16 T in a 50-mm aperture with accelerator quality. These characteristics could meet the requirements for an upgrade of the LHC to twice the present beam energy or for a 100-TeV center of mass energy future circular collider. This paper summarizes the activities and plans for the development of these magnets, in particular within the 16 T Magnet Technology Program, the WP5 of the EuroCirCol, and the U.S. Magnet Development Program.

Published

2018

5. Status of the 16 T Dipole Development Program for a Future Hadron Collider

Author

Tommasini, Davide, Bermudez, Susana Izquierdo, Bordini, Bernardo, Bottura, Luca, Brower, Lucas, Buzio, Marco, Caiffi, Barbara, Caspi, Shlomo, Dhalle, Marc, Durante, Maria, deRijk, Gijs, Arbelaez, Diego, Fabbricatore, Pasquale, Farinon, Stefania, Ferracin, Paolo, Gao, Peng, Gourlay, Steve, Juchno, Mariusz, Kashikhin, Vadim, Lackner, Friedrich, Lorin, Clement, Marchevsky, Maxim, Auchmann, Bernhard, Marinozzi, Vittorio, Martinez, Teresa, Munilla, Javier, Novitski, Igor, Ogitsu, Toru, Ortwein, Rafal, Perez, Juan Carlos, Petrone, Carlo, Prestemon, Soren, Prioli, Marco, Bajas, Hugues, Rifflet, Jean-Michel, Rochepault, Etienne, Russenschuck, Stephan, Salmi, Tiina, Savary, Frederic, Schoerling, Daniel, Segreti, Michel, Senatore, Carmine, Sorbi, Massimo, Stenvall, Antti, Bajko, Marta, Todesco, Ezio, Toral, Fernando, Verweij, Arjan P, Wessel, Sander, Wolf, Felix, Zlobin, Alexander V, Ballarino, Amalia, Barzi, Emanuela, Bellomo, Giovanni, and Benedikt, Michael

Subjects

Nuclear and Plasma Physics, Particle and High Energy Physics, Physical Sciences, Affordable and Clean Energy, Future circular collider, superconducting, Nb3Sn, T, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics, Electrical engineering, Condensed matter physics

Abstract

A next step of energy increase of hadron colliders beyond the LHC requires high-field superconducting magnets capable of providing a dipolar field in the range of 16 T in a 50-mm aperture with accelerator quality. These characteristics could meet the requirements for an upgrade of the LHC to twice the present beam energy or for a 100-TeV center of mass energy future circular collider. This paper summarizes the activities and plans for the development of these magnets, in particular within the 16 T Magnet Technology Program, the WP5 of the EuroCirCol, and the U.S. Magnet Development Program.

Published

2018

6. Design of a canted-cosine-theta superconducting dipole magnet for future colliders

Author

Caspi, S, Arbelaez, D, Brouwer, L, Gourlay, S, Prestemon, S, and Auchmann, B

Subjects

CCT, Canted-Cosine-Theta, superconducting, magnet, high field, dipole, 16T, 2-in-1, General Physics, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering

Abstract

A four-layer canted-cosine-theta 16-T dipole has been designed as a possible candidate for future hadron colliders. The design maintains part of the future-circular-collider magnet requirements, i.e., a 50 mm clear bore and 16 T operating at 1.9 K. The magnet intercepts Lorentz forces with an internal structure of ribs and spars, minimizes conductor, and reduces the number of layers and magnet size by using wide cables. The role of iron and its impact on field and magnet size is discussed. A three-dimensional magnetic analysis was carried out for 1-in-1 and 2-in-1 designs including a structural analysis for the 1-in-1 case. Thoughts on future improvements during winding are also discussed.

Published

2017

7. Design of a Canted-Cosine-Theta Superconducting Dipole Magnet for Future Colliders

Author

Caspi, Shlomo, Arbelaez, Diego, Brouwer, Lucas, Gourlay, Steve, Prestemon, Soren, and Auchmann, Bernhard

Subjects

Engineering, Electrical Engineering, Physical Sciences, CCT, Canted-Cosine-Theta, superconducting, magnet, high field, dipole, 16T, 2-in-1, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics, Electrical engineering, Condensed matter physics

Abstract

A four-layer canted-cosine-theta 16-T dipole has been designed as a possible candidate for future hadron colliders. The design maintains part of the future-circular-collider magnet requirements, i.e., a 50 mm clear bore and 16 T operating at 1.9 K. The magnet intercepts Lorentz forces with an internal structure of ribs and spars, minimizes conductor, and reduces the number of layers and magnet size by using wide cables. The role of iron and its impact on field and magnet size is discussed. A three-dimensional magnetic analysis was carried out for 1-in-1 and 2-in-1 designs including a structural analysis for the 1-in-1 case. Thoughts on future improvements during winding are also discussed.

Published

2017

8. Superconducting Magnets for Particle Accelerators

Author

Bottura, Luca, Gourlay, Stephen A, Yamamoto, Akira, and Zlobin, Alexander V

Subjects

Accelerator, magnet, superconducting, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Biomedical Engineering, Nuclear & Particles Physics

Abstract

In this paper we summarize the evolution and contributions of superconducting magnets to particle accelerators as chronicled over the last 50 years of Particle Accelerator Conferences (PAC, NA-PAC and IPAC). We begin with an historical overview based primarily on PAC Proceedings augmented with references to key milestones in the development of superconducting magnets for particle accelerators. We then provide some illustrative examples of applications that have occurred over the past 50 years, focusing on those that have either been realized in practice or provided technical development for other projects, with discussion of possible future applications.

Published

2016

9. Superconducting Magnets for Particle Accelerators

Author

Bottura, L, Gourlay, SA, Yamamoto, A, and Zlobin, AV

Subjects

Accelerator, magnet, superconducting, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Biomedical Engineering, Other Physical Sciences, Nuclear & Particles Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

In this paper we summarize the evolution and contributions of superconducting magnets to particle accelerators as chronicled over the last 50 years of Particle Accelerator Conferences (PAC, NA-PAC and IPAC). We begin with an historical overview based primarily on PAC Proceedings augmented with references to key milestones in the development of superconducting magnets for particle accelerators. We then provide some illustrative examples of applications that have occurred over the past 50 years, focusing on those that have either been realized in practice or provided technical development for other projects, with discussion of possible future applications.

Published

2016

10. Multipartite Entanglement in Rabi Driven Superconducting Qubits

Author

Lu, Marie

Subjects

Quantum physics, Atomic physics, Condensed matter physics, benchmarking, entanglement, gate, qubit, randomized, superconducting

Abstract

In harnessing quantum advantages for computation, there is a need for developing high fidelity operations on qubits. An algorithm can be broken down into single qubit operations and multi-qubit entangling gates. However, as the leading quantum processors today are limited to 50-100 qubits and each qubit is sensitive to decoherence noise (often referred to as NISQ era devices), running algorithms with long gate depth is difficult. Understanding the errors that plague existing gates and also expanding the dictionary of available gates is an important part of building a quantum computer. In this thesis we demonstrate two multiqubit gate experiments.In the first experiment we demonstrate a multiqubit entangling gate for superconducting qubits on an all-to-all connected processor that draws upon the advantages of Rabi driven qubits. We also take inspiration from the ion qubit community by using a Mølmer-Sørensen-like interaction through the use of a shared coplanar waveguide (CPW) resonator driven superconducting qubits. We perform sensitivity analysis to understand the parameters that limit our gate fidelities. In the second experiment we introduce and demonstrate a technique for scalable RB of many universal and continuously parameterized gate sets, using a class of circuits called randomized mirror circuits. The technique can be applied to a gate set containing an entangling Clifford gate and the set of arbitrary single-qubit gates, as well as gate sets containing controlled rotations about the Pauli axes. We use our technique to benchmark universal gate sets on four qubits, including a gate set containing a controlled-S gate and its inverse, and we investigate how the observed error rate is impacted by the inclusion of non-Clifford gates. We also show that our technique scales to many qubits with experiments on a 27-qubit IBM Q processor. We use our technique to quantify the impact of crosstalk on this 27-qubit device, and we find that it contributes approximately 2/3 of the total error per gate in random many-qubit circuit layers.

Published

2022

11. Resolving correlated errors in superconducting quantum computers

Author

McEwen, Matthew James

Subjects

Quantum physics, Error Correction, Quantum Computing, Superconducting

Abstract

Quantum computers can provide new computational abilities, but only if their intrinsic noise can be suppressed.Quantum error correction (QEC) promises to suppress errors exponentially, provided they are sufficiently uncorrelated.Large arrays of superconducting qubits are a leading platform for implementing quantum error correction, but feature several sources of error that are highly correlated; a single physical process that produces the equivalent of many independent errors to be corrected. These correlated errors must be studied and mitigated in order for quantum error correction to succeed.This thesis addresses two correlated error sources in particular; leakage and impacts from high-energy radiation.Leakage of information out of the states selected for computation presents a significant challenge, as leakage populations spread virally through the device and induce a large pattern of errors if they are not suppressed. We develop several new techniques for removing leakage during QEC codes, eventually achieving regular leakage removal from all qubits, successfully curtailing the ability of leakage to spread. High-energy radiation impacting the device present another problematic error source, as the energies deposited are enough to cause significant error over the entire chip at current sizes. We present time-resolved measurements of such impacts and explain the underlying physical processes with a view toward future mitigation of this error source in hardware.This work understanding and suppressing these correlated errors in our hardware has run parallel to and been integrated into the development of the first scaling demonstrations of surface code quantum error correction.

Published

2022

12. 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

Canted cosine-theta, dipole, high field, magnet, superconducting, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics

Abstract

A multilayer high field dipole magnet has been designed for future particle accelerators. The magnet has eight layers of a Nb3Sn 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.

Published

2015

13. 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

Canted cosine-theta, dipole, high field, magnet, superconducting, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering, General Physics

Abstract

A multilayer high field dipole magnet has been designed for future particle accelerators. The magnet has eight layers of a Nb3Sn 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.

Published

2015

14. Test results of CCT1 - A 2.4 T canted-cosine-theta dipole magnet

Author

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

Subjects

Canted-Cosine-Theta, superconducting, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering, General Physics

Abstract

A two-layer Canted-Cosine-Theta (CCT) superconducting dipole magnet was built and tested. The magnet's unique mandrel design uses machined channels and spars to guide the windings, intercept Lorentz forces, and circumvent tangential stress accumulation. The CCT magnet design provides a "near-perfect" current density distribution and requires minimal coil prestress. The CCT magnet design, with these inherent features, makes it a desirable option for a high field accelerator magnet. A two layer dipole (CCT1) using NbTi cable and a 50.8-mm clear bore was built and tested generating a 2.4 T dipole field. We report on the winding experience, measured field quality and quench history.

Published

2015

15. Test Results of CCT1—A 2.4 T Canted-Cosine-Theta Dipole Magnet

Author

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

Subjects

Engineering, Electrical Engineering, Physical Sciences, Canted-Cosine-Theta, superconducting, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics, Electrical engineering, Condensed matter physics

Abstract

A two-layer Canted-Cosine-Theta (CCT) superconducting dipole magnet was built and tested. The magnet's unique mandrel design uses machined channels and spars to guide the windings, intercept Lorentz forces, and circumvent tangential stress accumulation. The CCT magnet design provides a "near-perfect" current density distribution and requires minimal coil prestress. The CCT magnet design, with these inherent features, makes it a desirable option for a high field accelerator magnet. A two layer dipole (CCT1) using NbTi cable and a 50.8-mm clear bore was built and tested generating a 2.4 T dipole field. We report on the winding experience, measured field quality and quench history.

Published

2015

16. Error Analysis and Field Correction Methods in Superconducting Undulators

Author

Rochepault, E, Arbelaez, D, Prestemon, SO, and Schlueter, RD

Subjects

Correction, free electron laser, magnetic design, superconducting, tuning, undulators, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics

Abstract

In Free Electron Lasers (FEL), the electron trajectory through the undulator must meet stringent requirements in terms of trajectory wander and phase variation. This paper analyzes the feasibility of using line current pairs as correctors for superconducting undulators given a set of expected fabrication errors. A tolerance study has first been performed to investigate the impact of geometrical errors on the field quality. These errors are corrected with line currents that increase or decrease the magnetic field locally. Once the uncorrected trajectory is known, an algorithm finds the minimum number of correctors required to fulfill the trajectory specifications, and gives the corrector locations. All the correctors can be powered with the same current, greatly simplifying the implementation. The current then offers a degree of freedom to correct the trajectory and can be tuned dynamically as a function of the magnetic deflection.

Published

2014

17. The Structural Design for a “Canted Cosine–Theta” Superconducting Dipole Coil and Magnet Structure—CCT1

Author

Hafalia, Aurelio, Caspi, Shlomo, Felice, Helene, Brouwer, Lucas, Prestemon, Soren, and Godeke, Arno

Subjects

Bladder & key, canted cosine-theta, dipole, superconducting, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics

Abstract

The Superconducting Magnet Group, at Lawrence Berkeley National Laboratory (LBNL), has been developing a canted cosine-theta (CCT) superconducting dipole coil as well as the coil's supporting magnet structure. This contribution reports on the progress in the development of the coil's winding mandrel and its fabrication options. A comprehensive study of the coil's Lorentz forces was performed to validate the winding mandrel's "stress interception" attributes. The design of the external structure and the application of the "Bladder & Key" technology is also discussed. Additionally, the application of these studies to a curved ion-therapy CCT dipole magnet is reported.

Published

2014

18. The structural design for a "canted cosine-theta" Superconducting dipole coil and magnet structure-CCT

Author

Hafalia, A, Caspi, S, Felice, H, Brouwer, L, Prestemon, S, and Godeke, A

Subjects

Bladder & key, canted cosine-theta, dipole, superconducting, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering, General Physics

Abstract

The Superconducting Magnet Group, at Lawrence Berkeley National Laboratory (LBNL), has been developing a canted cosine-theta (CCT) superconducting dipole coil as well as the coil's supporting magnet structure. This contribution reports on the progress in the development of the coil's winding mandrel and its fabrication options. A comprehensive study of the coil's Lorentz forces was performed to validate the winding mandrel's "stress interception" attributes. The design of the external structure and the application of the "Bladder & Key" technology is also discussed. Additionally, the application of these studies to a curved ion-therapy CCT dipole magnet is reported.

Published

2014

19. Error analysis and field correction methods in superconducting undulators

Author

Rochepault, E, Arbelaez, D, Prestemon, SO, and Schlueter, RD

Subjects

Correction, free electron laser, magnetic design, superconducting, tuning, undulators, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering, General Physics

Abstract

In Free Electron Lasers (FEL), the electron trajectory through the undulator must meet stringent requirements in terms of trajectory wander and phase variation. This paper analyzes the feasibility of using line current pairs as correctors for superconducting undulators given a set of expected fabrication errors. A tolerance study has first been performed to investigate the impact of geometrical errors on the field quality. These errors are corrected with line currents that increase or decrease the magnetic field locally. Once the uncorrected trajectory is known, an algorithm finds the minimum number of correctors required to fulfill the trajectory specifications, and gives the corrector locations. All the correctors can be powered with the same current, greatly simplifying the implementation. The current then offers a degree of freedom to correct the trajectory and can be tuned dynamically as a function of the magnetic deflection.

Published

2014

20. A superconducting magnet mandrel with minimum symmetry laminations for proton therapy

Author

Caspi, S, Arbelaez, D, Brouwer, L, Dietderich, DR, Felice, H, Hafalia, R, Prestemon, S, Robin, D, Sun, C, and Wan, W

Subjects

Curved dipole magnet, Superconducting, Gantry, Hadron therapy, Canted cosine-theta, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Nuclear & Particles Physics

Abstract

The size and weight of ion-beam cancer therapy gantries are frequently determined by a large aperture, curved, ninety degree, dipole magnet. The higher fields achievable with superconducting technology promise to greatly reduce the size and weight of this magnet and therefore also the gantry as a whole. This paper reports advances in the design of winding mandrels for curved, canted cosine-theta (CCT) magnets in the context of a preliminary magnet design for a proton gantry. The winding mandrel is integral to the CCT design and significantly affects the construction cost, stress management, winding feasibility, eddy current power losses, and field quality of the magnet. A laminated mandrel design using a minimum symmetry in the winding path is introduced and its feasibility demonstrated by a rapid prototype model. Piecewise construction of the mandrel using this laminated approach allows for increased manufacturing techniques and material choices. Sectioning the mandrel also reduces eddy currents produced during field changes accommodating the scan of beam energies during treatment. This symmetry concept can also greatly reduce the computational resources needed for 3D finite element calculations. It is shown that the small region of symmetry forming the laminations combined with periodic boundary conditions can model the entire magnet geometry disregarding the ends. © 2013 Elsevier B.V.

Published

2013

21. A superconducting magnet mandrel with minimum symmetry laminations for proton therapy

Author

Caspi, S, Arbelaez, D, Brouwer, L, Dietderich, DR, Felice, H, Hafalia, R, Prestemon, S, Robin, D, Sun, C, and Wan, W

Subjects

Curved dipole magnet, Superconducting, Gantry, Hadron therapy, Canted cosine-theta, Nuclear & Particles Physics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences

Abstract

The size and weight of ion-beam cancer therapy gantries are frequently determined by a large aperture, curved, ninety degree, dipole magnet. The higher fields achievable with superconducting technology promise to greatly reduce the size and weight of this magnet and therefore also the gantry as a whole. This paper reports advances in the design of winding mandrels for curved, canted cosine-theta (CCT) magnets in the context of a preliminary magnet design for a proton gantry. The winding mandrel is integral to the CCT design and significantly affects the construction cost, stress management, winding feasibility, eddy current power losses, and field quality of the magnet. A laminated mandrel design using a minimum symmetry in the winding path is introduced and its feasibility demonstrated by a rapid prototype model. Piecewise construction of the mandrel using this laminated approach allows for increased manufacturing techniques and material choices. Sectioning the mandrel also reduces eddy currents produced during field changes accommodating the scan of beam energies during treatment. This symmetry concept can also greatly reduce the computational resources needed for 3D finite element calculations. It is shown that the small region of symmetry forming the laminations combined with periodic boundary conditions can model the entire magnet geometry disregarding the ends. © 2013 Elsevier B.V.

Published

2013

22. Magnetic Field Correction Concepts for Superconducting Undulators

Author

Arbelaez, D, Lee, D, Pan, H, Koettig, T, Bish, P, Prestemon, SO, Dietderich, DR, and Schlueter, RD

Subjects

Shimming, superconducting, tuning, undulator, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics

Abstract

The ability to correct magnetic field errors in a superconducting undulator is critical for the successful application of these devices in future and existing light sources. These field errors, which can emanate from sources such as machining and coil winding imperfections, can lead to reduced light source performance by introducing errors in both the electron trajectory and the relative phase relationship between the oscillating electrons and the emitted photons. In this work, correction schemes are presented, which use a single power supply along with a superconducting switch network to define the path for the current during undulator tuning. The basic switching concept was previously designed and successfully tested at Lawrence Berkeley National Laboratory; the approach presented here is a significant advancement in generalizing and scaling that core concept. A new fabrication method is presented here, which uses lithographic methods to produce current paths and switch heaters on a superconducting film. The effect of an example corrector current path design on the magnetic field is investigated using the Finite Element Method, and the results at various undulator and corrector energization levels are presented. Experimental results from the heater switch concept are also presented. © 2002-2011 IEEE.

Published

2013

23. Magnetic field correction concepts for superconducting undulators

Author

Arbelaez, D, Lee, D, Pan, H, Koettig, T, Bish, P, Prestemon, SO, Dietderich, DR, and Schlueter, RD

Subjects

Shimming, superconducting, tuning, undulator, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering, General Physics

Abstract

The ability to correct magnetic field errors in a superconducting undulator is critical for the successful application of these devices in future and existing light sources. These field errors, which can emanate from sources such as machining and coil winding imperfections, can lead to reduced light source performance by introducing errors in both the electron trajectory and the relative phase relationship between the oscillating electrons and the emitted photons. In this work, correction schemes are presented, which use a single power supply along with a superconducting switch network to define the path for the current during undulator tuning. The basic switching concept was previously designed and successfully tested at Lawrence Berkeley National Laboratory; the approach presented here is a significant advancement in generalizing and scaling that core concept. A new fabrication method is presented here, which uses lithographic methods to produce current paths and switch heaters on a superconducting film. The effect of an example corrector current path design on the magnetic field is investigated using the Finite Element Method, and the results at various undulator and corrector energization levels are presented. Experimental results from the heater switch concept are also presented. © 2002-2011 IEEE.

Published

2013

24. Electronic Nano-device Fabrications and Measurements

Author

Ren, Haowen

Subjects

Materials Science, Physics, Energy, MRAM, Nanowire, Spintronic, Superconducting, TF-SOFC

Abstract

The first part of this dissertation mainly focus on thin film solid oxide fuel cells. In recent years, solid oxide fuel cells are becoming more popular as a green energy source of electricity due to their high efficiency and low carbon emission. However, high operation temperature and materials costs are the main issues impeding the application of this technique. In this presentation, by applying magnetron sputtering technique to fabricate thin film solid oxide fuel cell, we are able to operate the cells under much lower temperature with superior performance under hydrogen or hydrocarbon fuels. Different composite nano-porous cathodes and anodes are fabricated and characterized, all showing reliable, reproducible and scalable results. The second part of the dissertation focus on fabrication and characterizations of spintronic devices, including Si-doped single crystalline Ni nanowires, spin-triplet spintronic and SOT-MRAM devices. Spintronics has been widely applied in data storage applications such as hard disk drives, STT-MRAMs, and SOT-MRAMs, etc. Recently, development of spintronics theories and experiments has allowed it to expand to broader applications, such as domain wall MRAMs, neuromorphic computing and quantum computing. In this section, we will introduce the growth of Si-doped single crystalline Ni nanowires, the effects from AMR, OMR and domain wall MR at low magnetic fields and electron-magnon interaction at high magnetic fields. We studied superconducting triplet spin valve devices. In general, singlet Cooper pairs generated from superconducting layers cannot survive in magnetic layer. However, if we introduce an inhomogeneous moments between these two layers, triplets Cooper pair appeared and can survive much longer than singlet Cooper pair in ferromagnetic materials. In our study, we fabricated epitaxial Ni and Co superconducting spin-triplet spin valves to study this effect. By rotating the soft NiFe layer to break the linearity of magnetizations, inhomogeneous moments can be generated. Magnetization configurations are characterized by polarized neutron reflectometer. By measuring the change of superconducting critical temperature at different angles of external field, we observed that the behavior of spin valve is highly sensitive to the thickness of the inhomogeneous magnetic layers. Lastly, the SOT-MRAM project during the internship in IBM is presented. SOT-MRAM is a potential second generation MRAM compared to STT-MRAM due to its higher efficiency, stability and lower switching current. We fabricated single SOT-MRAM device using $\beta$-W as spin current source. Ion beam etching process, the most critical fabrication process, has been studied. Shapes and aspect ratio effects on nanopillars are discussed. We also introduced thin Hf interlayers in the heterostructure to further decrease the critical switching current. Simulations proves an enhancement in perpendicular anisotropy will lead to this reduction in critical switching current.

Published

2020

25. Electronic Nano-device Fabrications and Measurements

Author

Ren, Haowen

Subjects

Materials Science, Physics, Energy, MRAM, Nanowire, Spintronic, Superconducting, TF-SOFC

Abstract

The first part of this dissertation mainly focus on thin film solid oxide fuel cells. In recent years, solid oxide fuel cells are becoming more popular as a green energy source of electricity due to their high efficiency and low carbon emission. However, high operation temperature and materials costs are the main issues impeding the application of this technique. In this presentation, by applying magnetron sputtering technique to fabricate thin film solid oxide fuel cell, we are able to operate the cells under much lower temperature with superior performance under hydrogen or hydrocarbon fuels. Different composite nano-porous cathodes and anodes are fabricated and characterized, all showing reliable, reproducible and scalable results. The second part of the dissertation focus on fabrication and characterizations of spintronic devices, including Si-doped single crystalline Ni nanowires, spin-triplet spintronic and SOT-MRAM devices. Spintronics has been widely applied in data storage applications such as hard disk drives, STT-MRAMs, and SOT-MRAMs, etc. Recently, development of spintronics theories and experiments has allowed it to expand to broader applications, such as domain wall MRAMs, neuromorphic computing and quantum computing. In this section, we will introduce the growth of Si-doped single crystalline Ni nanowires, the effects from AMR, OMR and domain wall MR at low magnetic fields and electron-magnon interaction at high magnetic fields. We studied superconducting triplet spin valve devices. In general, singlet Cooper pairs generated from superconducting layers cannot survive in magnetic layer. However, if we introduce an inhomogeneous moments between these two layers, triplets Cooper pair appeared and can survive much longer than singlet Cooper pair in ferromagnetic materials. In our study, we fabricated epitaxial Ni and Co superconducting spin-triplet spin valves to study this effect. By rotating the soft NiFe layer to break the linearity of magnetizations, inhomogeneous moments can be generated. Magnetization configurations are characterized by polarized neutron reflectometer. By measuring the change of superconducting critical temperature at different angles of external field, we observed that the behavior of spin valve is highly sensitive to the thickness of the inhomogeneous magnetic layers. Lastly, the SOT-MRAM project during the internship in IBM is presented. SOT-MRAM is a potential second generation MRAM compared to STT-MRAM due to its higher efficiency, stability and lower switching current. We fabricated single SOT-MRAM device using $\beta$-W as spin current source. Ion beam etching process, the most critical fabrication process, has been studied. Shapes and aspect ratio effects on nanopillars are discussed. We also introduced thin Hf interlayers in the heterostructure to further decrease the critical switching current. Simulations proves an enhancement in perpendicular anisotropy will lead to this reduction in critical switching current.

Published

2020

26. Fault-tolerant superconducting qubits

Author

Kelly, Julian

Subjects

Quantum physics, Physics, Computer science, digital, quantum computing, quantum error correction, qubits, superconducting, surface code

Abstract

For quantum computing to become viable, the inherently fallible nature of qubits must be overcome with quantum error correction (QEC). QEC requires coherent qubits, in a configuration compatible with a given QEC scheme, and quantum logic operations with sufficiently low error. In this thesis, we perform a series of targeted experiments to achieve these goals on a path toward realizing the surface code QEC scheme. We first develop the Xmon variant of the transmon qubit, a highly coherent, planar, and frequency tunable superconducting qubit. With coherence demonstrated, we build an array of five Xmon qubits in a configuration compatible with the surface code, and demonstrate quantum logic operations with sufficiently low error to employ the surface code. These logic gates are characterized with randomized benchmarking, a protocol for determining gate error. We find applications of randomized benchmarking beyond the intended use in gate optimization and decoherence characterization, in addition to exploring the fundamental assumptions of randomized benchmarking. Lastly, we build a nine qubit Xmon transmon array and demonstrate correction of environmental bit-flip errors in a precursor to the surface code.

Published

2015

27. Investigation of Nb3Sn Based Superconductors Through Hierarchical Models

Author

Collins, Brett

Subjects

Mechanical engineering, FEM, Multiscale, Numerical, Superconducting

Abstract

The large range of length scales present within accelerator magnets suggests the incorporation of a hierarchical structure into computational models. Evaluation of the strain state present within the superconducting filaments is necessary in order to determine the critical current of Nb3Sn based magnets. As part of an ongoing investigation at LBNL, a three-dimensional nonlinear multiscale model is developed to investigate the behavior of Nb3Sn filaments due to macroscopic loading. The major building blocks within a superconducting magnet are used to represent each length scale within the multiscale model: Coil, Rutherford cable, strand, filament, Nb3Sn crystal lattice. Using the developed model, loads at the coil level due to precompression, thermal contraction, and Lorenz forces are translated into lattice strain within the Nb3Sn phase of the composite. Jc can then be calculated through use of measurements performed on bulk samples of Nb3Sn. In addition, the physical effects on each scale due to loading is examined. Each level of the hierarchical model is solved using Finite Element Methods, taking into account effects due to thermal contraction and plasticity. A conjugate gradient algorithm is coupled with a Netwon's method with line search in order to solve resulting systems of equations.

Published

2013