Your search keyword '"Sorbom, B. N."' showing total 8 results

1. An accelerator facility for intermediate energy proton irradiation and testing of nuclear materials

Author

Jepeal, S. J., Danagoulian, A., Kesler, L. A., Korsun, D. A., Lee, H. Y., Schwartz, N., Sorbom, B. N., Lopez, E. Velez, and Hartwig, Z. S.

Subjects

Condensed Matter - Materials Science

Abstract

The bulk irradiation of materials with 10-30 MeV protons promises to advance the study of radiation damage for fission and fusion power plants. Intermediate energy proton beams can now be dedicated to materials irradiation within university-scale laboratories. This paper describes the first such facility, with an Ionetix ION-12SC cyclotron producing 12 MeV proton beams. Samples are mm-scale tensile specimens with thicknesses up to 300 um, mounted to a cooled beam target with control over temperature. A specialized tensile tester for radioactive specimens at high temperature (500+ {\deg}C) and/or vacuum represents the conditions in fission and fusion systems, while a digital image correlation system remotely measures strain. Overall, the facility provides university-scale irradiation and testing capability with intermediate energy protons to complement traditional in-core fission reactor and micro-scale ion irradiation. This facility demonstrates that bulk proton irradiation is a scalable and effective approach for nuclear materials research, down-selection, and qualification., Comment: Submitted to NIM B journal

Published

2020

2. Neutron diagnostics for the physics of a high-field, compact, $Q\geq1$ tokamak

Author

Tinguely, R. A., Rosenthal, A., Simpson, R., Ballinger, S. B., Creely, A. J., Frank, S., Kuang, A. Q., Linehan, B. L., McCarthy, W., Milanese, L. M., Montes, K. J., Mouratidis, T., Picard, J. F., Rodriguez-Fernandez, P., Sandberg, A. J., Sciortino, F., Tolman, E. A., Zhou, M., Sorbom, B. N., Hartwig, Z. S., and White, A. E.

Subjects

Physics - Plasma Physics

Abstract

Advancements in high temperature superconducting technology have opened a path toward high-field, compact fusion devices. This new parameter space introduces both opportunities and challenges for diagnosis of the plasma. This paper presents a physics review of a neutron diagnostic suite for a SPARC-like tokamak [Greenwald et al 2018 doi:10.7910/DVN/OYYBNU]. A notional neutronics model was constructed using plasma parameters from a conceptual device, called the MQ1 (Mission $Q \geq 1$) tokamak. The suite includes time-resolved micro-fission chamber (MFC) neutron flux monitors, energy-resolved radial and tangential magnetic proton recoil (MPR) neutron spectrometers, and a neutron camera system (radial and off-vertical) for spatially-resolved measurements of neutron emissivity. Geometries of the tokamak, neutron source, and diagnostics were modeled in the Monte Carlo N-Particle transport code MCNP6 to simulate expected signal and background levels of particle fluxes and energy spectra. From these, measurements of fusion power, neutron flux and fluence are feasible by the MFCs, and the number of independent measurements required for 95% confidence of a fusion gain $Q \geq 1$ is assessed. The MPR spectrometer is found to consistently overpredict the ion temperature and also have a 1000$\times$ improved detection of alpha knock-on neutrons compared to previous experiments. The deuterium-tritium fuel density ratio, however, is measurable in this setup only for trace levels of tritium, with an upper limit of $n_T/n_D \approx 6\%$, motivating further diagnostic exploration. Finally, modeling suggests that in order to adequately measure the self-heating profile, the neutron camera system will require energy and pulse-shape discrimination to suppress otherwise overwhelming fluxes of low energy neutrons and gamma radiation. *Co-first-authorship

Published

2019

3. Conceptual design study for heat exhaust management in the ARC fusion pilot plant

Author

Kuang, A. Q., Cao, N. M., Creely, A. J., Dennett, C. A., Hecla, J., LaBombard, B., Tinguely, R. A., Tolman, E. A., Hoffman, H., Major, M., Ruiz, J. Ruiz, Brunner, D., Grover, P., Laughman, C., Sorbom, B. N., and Whyte, D. G.

Subjects

Physics - Instrumentation and Detectors, Physics - Applied Physics, Physics - Plasma Physics

Abstract

The ARC pilot plant conceptual design study has been extended beyond its initial scope [B. N. Sorbom et al., FED 100 (2015) 378] to explore options for managing ~525 MW of fusion power generated in a compact, high field (B_0 = 9.2 T) tokamak that is approximately the size of JET (R_0 = 3.3 m). Taking advantage of ARC's novel design - demountable high temperature superconductor toroidal field (TF) magnets, poloidal magnetic field coils located inside the TF, and vacuum vessel (VV) immersed in molten salt FLiBe blanket - this follow-on study has identified innovative and potentially robust power exhaust management solutions., Comment: Accepted by Fusion Engineering and Design

Published

2018

4. ARC: A compact, high-field, fusion nuclear science facility and demonstration power plant with demountable magnets

Author

Sorbom, B. N., Ball, J., Palmer, T. R., Mangiarotti, F. J., Sierchio, J. M., Bonoli, P., Kasten, C., Sutherland, D. A., Barnard, H. S., Haakonsen, C. B., Goh, J., Sung, C., and Whyte, D. G.

Subjects

Physics - Plasma Physics, Physics - Instrumentation and Detectors

Abstract

The affordable, robust, compact (ARC) reactor conceptual design study aims to reduce the size, cost, and complexity of a combined fusion nuclear science facility (FNSF) and demonstration fusion Pilot power plant. ARC is a 200-250 MWe tokamak reactor with a major radius of 3.3 m, a minor radius of 1.1 m, and an on-axis magnetic field of 9.2 T. ARC has rare earth barium copper oxide (REBCO) superconducting toroidal field coils, which have joints to enable disassembly. This allows the vacuum vessel to be replaced quickly, mitigating first wall survivability concerns, and permits a single device to test many vacuum vessel designs and divertor materials. The design point has a plasma fusion gain of Q_p~13.6, yet is fully non-inductive, with a modest bootstrap fraction of only ~63%. Thus ARC offers a high power gain with relatively large external control of the current profile. This highly attractive combination is enabled by the ~23 T peak field on coil with newly available REBCO superconductor technology. External current drive is provided by two innovative inboard RF launchers using 25 MW of lower hybrid and 13.6 MW of ion cyclotron fast wave power. The resulting efficient current drive provides a robust, steady state core plasma far from disruptive limits. ARC uses an all-liquid blanket, consisting of low pressure, slowly flowing fluorine lithium beryllium (FLiBe) molten salt. The liquid blanket is low-risk technology and provides effective neutron moderation and shielding, excellent heat removal, and a tritium breeding ratio >= 1.1. The large temperature range over which FLiBe is liquid permits blanket operation at 900 K with single phase fluid cooling and a high-efficiency Brayton cycle, allowing for net electricity generation when operating ARC as a Pilot power plant., Comment: 35 pages, 32 figures

Published

2014

5. SPARC as a platform to advance tokamak science

Author

Creely, A. J., primary, Brunner, D., additional, Mumgaard, R. T., additional, Reinke, M. L., additional, Segal, M., additional, Sorbom, B. N., additional, and Greenwald, M. J., additional

Published

2023

6. Overview of the SPARC tokamak

Author

Massachusetts Institute of Technology. Plasma Science and Fusion Center, Massachusetts Institute of Technology. Department of Nuclear Science and Engineering, Creeely, A. J., Greenwald, Martin J., Ballinger, Sean B, Brunner, D., Canik, J., Doody, Jeffrey, Fülöp, T., Garnier, D.T., Granetz, Robert S., Gray, T. K., Holland, C., Howard, N.T., Hughes, J.W., Irby, James Henderson, Izzo, Viviana A., Kramer, G. J., Kuang, Adam QingYang, Labombard, Brian, Lin, Y., Lipschultz, B., Logan, N. C., Lore, J. D., Marmar, Earl S., Montes, Kevin J., Mumgaard, R. T., Paz-Soldan, C., Rea, C., Reinke, M. L., Rodriguez Fernandez, Pablo, Särkimäki, K., Sciortino, Francesco, Scott, S. D., Snicker, A., Snyder, P. B., Sorbom, B. N., Sweeney, R., Tinguely, Roy Alexander, Tolman, Elizabeth Ann, Umansky, M., Vallhagen, O., Varje, J., Whyte, Dennis G, Wright, J.C., Wukitch, Stephen James, The SPARC Team, Zhu, Jiazhou, Massachusetts Institute of Technology. Plasma Science and Fusion Center, Massachusetts Institute of Technology. Department of Nuclear Science and Engineering, Creeely, A. J., Greenwald, Martin J., Ballinger, Sean B, Brunner, D., Canik, J., Doody, Jeffrey, Fülöp, T., Garnier, D.T., Granetz, Robert S., Gray, T. K., Holland, C., Howard, N.T., Hughes, J.W., Irby, James Henderson, Izzo, Viviana A., Kramer, G. J., Kuang, Adam QingYang, Labombard, Brian, Lin, Y., Lipschultz, B., Logan, N. C., Lore, J. D., Marmar, Earl S., Montes, Kevin J., Mumgaard, R. T., Paz-Soldan, C., Rea, C., Reinke, M. L., Rodriguez Fernandez, Pablo, Särkimäki, K., Sciortino, Francesco, Scott, S. D., Snicker, A., Snyder, P. B., Sorbom, B. N., Sweeney, R., Tinguely, Roy Alexander, Tolman, Elizabeth Ann, Umansky, M., Vallhagen, O., Varje, J., Whyte, Dennis G, Wright, J.C., Wukitch, Stephen James, The SPARC Team, and Zhu, Jiazhou

Abstract

© 2020 The Author(s). The SPARC tokamak is a critical next step towards commercial fusion energy. SPARC is designed as a high-field (T), compact (m, m), superconducting, D-T tokamak with the goal of producing fusion gain 2$]]> from a magnetically confined fusion plasma for the first time. Currently under design, SPARC will continue the high-field path of the Alcator series of tokamaks, utilizing new magnets based on rare earth barium copper oxide high-temperature superconductors to achieve high performance in a compact device. The goal of 2$]]> is achievable with conservative physics assumptions () and, with the nominal assumption of, SPARC is projected to attain and MW. SPARC will therefore constitute a unique platform for burning plasma physics research with high density (), high temperature (keV) and high power density () relevant to fusion power plants. SPARC's place in the path to commercial fusion energy, its parameters and the current status of SPARC design work are presented. This work also describes the basis for global performance projections and summarizes some of the physics analysis that is presented in greater detail in the companion articles of this collection.

Published

2022

7. Overview of the SPARC tokamak

Author

Creely, A. J., Greenwald, M. J., Ballinger, S. B., Brunner, D., Canik, J., Doody, J., Fulop, T., Garnier, D. T., Granetz, R., Gray, T. K., Holland, C., Howard, N. T., Hughes, J. W., Irby, J. H., Izzo, V. A., Kramer, G. J., Kuang, A. Q., LaBombard, B., Lin, Yijun, Lipschultz, B., Logan, N. C., Lore, J. D., Marmar, E. S., Montes, K., Mumgaard, R. T., Paz-Soldan, C., Rea, C., Reinke, M. L., Rodriguez-Fernandez, P., Sarkimaki, K., Sciortino, F., Scott, S. D., Snicker, A., Snyder, P. B., Sorbom, B. N., Sweeney, R., Tinguely, R. A., Tolman, E. A., Umansky, M., Vallhagen, O., Varje, J., Whyte, D. G., Wright, J. C., Wukitch, S. J., Zhu, J., SPARC Team, Department of Applied Physics, Aalto-yliopisto, and Aalto University

Subjects

Tokamak, DATABASE, fusion plasma, Fusion plasma, Plasma confinement, 01 natural sciences, 010305 fluids & plasmas, law.invention, PHYSICS, PLASMA-FACING COMPONENTS, DESIGN, law, 0103 physical sciences, 010306 general physics, PROGRESS, DEMO, Physics, plasma confinement, TUNGSTEN, CONSTRUCTION, Fusion power, Condensed Matter Physics, H-MODE CONFINEMENT, plasma devices, Systems engineering, CHAPTER 2

Abstract

The SPARC tokamak is a critical next step towards commercial fusion energy. SPARC is designed as a high-field ($B_0 = 12.2$T), compact ($R_0 = 1.85$m,$a = 0.57$m), superconducting, D-T tokamak with the goal of producing fusion gain$Q>2$from a magnetically confined fusion plasma for the first time. Currently under design, SPARC will continue the high-field path of the Alcator series of tokamaks, utilizing new magnets based on rare earth barium copper oxide high-temperature superconductors to achieve high performance in a compact device. The goal of$Q>2$is achievable with conservative physics assumptions ($H_{98,y2} = 0.7$) and, with the nominal assumption of$H_{98,y2} = 1$, SPARC is projected to attain$Q \approx 11$and$P_{\textrm {fusion}} \approx 140$MW. SPARC will therefore constitute a unique platform for burning plasma physics research with high density ($\langle n_{e} \rangle \approx 3 \times 10^{20}\ \textrm {m}^{-3}$), high temperature ($\langle T_e \rangle \approx 7$keV) and high power density ($P_{\textrm {fusion}}/V_{\textrm {plasma}} \approx 7\ \textrm {MW}\,\textrm {m}^{-3}$) relevant to fusion power plants. SPARC's place in the path to commercial fusion energy, its parameters and the current status of SPARC design work are presented. This work also describes the basis for global performance projections and summarizes some of the physics analysis that is presented in greater detail in the companion articles of this collection.

Published

2020

8. The engineering design of ARC: A compact, highfield, fusion nuclear science facility and demonstration power plant

Author

Sorbom, B. N., primary, Ball, J., additional, Palmer, T. R., additional, Mangiarotti, F. J., additional, Sierchio, J.M., additional, Bonoli, P., additional, Kasten, C., additional, Sutherland, D. A., additional, Barnard, H. S., additional, Haakonsen, C. B., additional, Goh, J., additional, Sung, C., additional, and Whyte, D. G., additional

Published

2015