Retrospective of the ARPA-E ALPHA Fusion Program

This paper provides a retrospective of the ALPHA (Accelerating Low-cost Plasma Heating and Assembly) fusion program of the Advanced Research Projects Agency-Energy (ARPA-E) of the U.S. Department of Energy. ALPHA's objective was to catalyze research and development efforts to enable substantially lower-cost pathways to economical fusion power. To do this in a targeted, focused program, ALPHA focused on advancing the science and technology of pulsed, intermediate-density fusion approaches, including magneto-inertial fusion and Z-pinch variants, that have the potential to scale to commercially viable fusion power plants. The paper includes a discussion of the origins and framing of the ALPHA program, a summary of project status and outcomes, a description of associated technology-transition activities, and thoughts on a potential follow-on ARPA-E fusion program.

[1]  Hoffman,et al.  Confinement and stability of plasmas in a field-reversed configuration. , 1992, Physical review letters.

[2]  George Marklin,et al.  The dynomak: An advanced spheromak reactor concept with imposed-dynamo current drive and next-generation nuclear power technologies , 2013 .

[3]  J. Slough,et al.  Creation of a high-temperature plasma through merging and compression of supersonic field reversed configuration plasmoids , 2011 .

[4]  S. Langendorf,et al.  Semi-analytic model of plasma-jet-driven magneto-inertial fusion , 2016, 1612.07368.

[5]  R. Samulyak,et al.  Simulation study of the influence of experimental variations on the structure and quality of plasma liners , 2018, Physics of Plasmas.

[6]  O A Hurricane,et al.  Fusion Energy Output Greater than the Kinetic Energy of an Imploding Shell at the National Ignition Facility. , 2018, Physical review letters.

[7]  D. Sinars,et al.  Magneto-Inertial Fusion , 2016 .

[8]  U. Shumlak,et al.  Kinetic simulations of sheared flow stabilization in high-temperature Z-pinch plasmas , 2019, Physics of Plasmas.

[9]  R. Mcbride,et al.  A semi-analytic model of gas-puff liner-on-target magneto-inertial fusion , 2019, Physics of Plasmas.

[10]  Shumlak,et al.  Sheared flow stabilization of the m=1 kink mode in Z pinches. , 1995, Physical review letters.

[11]  P. Stoltz,et al.  Experiment to Form and Characterize a Section of a Spherically Imploding Plasma Liner , 2017, IEEE Transactions on Plasma Science.

[12]  A. Lal,et al.  Multi-beam RF Accelerators for Ion Implantation , 2018, 2018 22nd International Conference on Ion Implantation Technology (IIT).

[13]  M. Glover,et al.  Wide Bandgap Technologies and Their Implications on Miniaturizing Power Electronic Systems , 2014, IEEE Journal of Emerging and Selected Topics in Power Electronics.

[14]  D. Sinars,et al.  Laser-driven magnetized liner inertial fusion , 2017 .

[15]  A. Glasser,et al.  Formation of collisionless high-beta plasmas by odd-parity rotating magnetic fields. , 2007, Physical review letters.

[16]  R. Mcbride,et al.  Experimental demonstration of fusion-relevant conditions in magnetized liner inertial fusion. , 2014, Physical review letters.

[17]  P. Stoltz,et al.  Plasma-Jet-Driven Magneto-Inertial Fusion , 2019, Fusion Science and Technology.

[18]  Lucas Spangher,et al.  Characterizing fusion market entry via an agent-based power plant fleet model , 2019, Energy Strategy Reviews.

[19]  S. Langendorf,et al.  Magnetized Plasma Target for Plasma-Jet-Driven Magneto-Inertial Fusion , 2018, Journal of Fusion Energy.

[20]  P. Turchi,et al.  Stabilized Liner Compressor for Low-Cost Controlled Fusion at Megagauss Field Levels , 2017, IEEE Transactions on Plasma Science.

[21]  T. Wangler Space-charge limits in linear accelerators , 1980 .

[22]  H. Rahman,et al.  Ar and Kr on deuterium gas-puff staged Z-pinch implosions on a 1-MA driver: Experiment and simulation , 2019, Physics of Plasmas.

[23]  M. Gilmore,et al.  Experimental Measurements of Ion Heating in Collisional Plasma Shocks and Interpenetrating Supersonic Plasma Flows. , 2018, Physical review letters.

[24]  U. Shumlak,et al.  Formation of a sheared flow Z pinch , 2005 .

[25]  D. Book,et al.  Theoretical studies of the formation and adiabatic compression of reversed-field configurations in imploding liners , 1978 .

[26]  M. Weis,et al.  The staged z-pinch as a potential high gain fusion energy source: An independent review, a negative conclusion , 2018, Physics of Plasmas.

[27]  M. Kaur,et al.  Magnetothermodynamics: Measurements of the thermodynamic properties in a relaxed magnetohydrodynamic plasma , 2018, 1802.00019.

[28]  Irvin R. Lindemuth,et al.  The fundamental parameter space of controlled thermonuclear fusion , 2009 .

[29]  P. Chang,et al.  Inertial confinement fusion implosions with imposed magnetic field compression using the OMEGA Laser , 2012 .

[30]  A. D. Stepanov,et al.  Sustained Neutron Production from a Sheared-Flow Stabilized Z Pinch. , 2018, Physical review letters.

[31]  Board on Physics Final Report of the Committee on a Strategic Plan for U.S. Burning Plasma Research , 2019 .

[32]  V. M. Ghete,et al.  Evidence of b-jet quenching in PbPb collisions at √(s(NN))=2.76  TeV. , 2013, Physical review letters.

[33]  F. Wessel,et al.  Shock waves in a Z-pinch and the formation of high energy density plasma , 2012 .

[34]  Stephen O. Dean A Piece of the Sun: The Quest for Fusion Energy by Daniel Clery , 2013 .

[35]  S. Ardanuc,et al.  A compact linear accelerator based on a scalable microelectromechanical-system RF-structure. , 2016, The Review of scientific instruments.

[36]  I. Lindemuth,et al.  Parameter space for magnetized fuel targets in inertial confinement fusion , 1983 .

[37]  J. Slough,et al.  Formation of a Stable Field Reversed Configuration through Merging , 2008 .

[38]  U. Shumlak,et al.  Evidence of stabilization in the Z-pinch. , 2001, Physical review letters.

[39]  M.G. Mazarakis,et al.  A New High Current Fast 100ns LTD Based Driver for Z-pinch IFE at Sandia , 2005, 21st IEEE/NPS Symposium on Fusion Engineering SOFE 05.

[40]  P. Bellan,et al.  Spatially translatable optical fiber-coupled heterodyne interferometer. , 2017, The Review of scientific instruments.

[41]  P. Turchi Imploding Liner Compression of Plasma: Concepts and Issues , 2008, IEEE Transactions on Plasma Science.

[42]  M. Mitchell Waldrop Plasma physics: The fusion upstarts , 2014, Nature.

[43]  Isik C. Kizilyalli,et al.  Keynotes: “Current and future directions in power electronic devices and circuits based on wide band-gap semiconductors” , 2017 .

[44]  S. Ardanuc,et al.  Demonstration of waferscale voltage amplifier and electrostatic quadrupole focusing array for compact linear accelerators , 2019, Journal of Applied Physics.

[45]  J. F. Camacho,et al.  Recent magneto-inertial fusion experiments on the field reversed configuration heating experiment , 2013 .

[46]  A. Hoffman,et al.  LINUS cycle calculations including plasma transport and resistive flux loss , 1980 .

[47]  Assessment of Inertial Confinement Fusion Targets , 2022 .

[48]  A. Persaud,et al.  Source-to-accelerator quadrupole matching section for a compact linear accelerator. , 2018, The Review of scientific instruments.

[49]  Mikhailov,et al.  Target Plasma Formation for Magnetic Compression/Magnetized Target Fusion. , 1995, Physical review letters.

[50]  M. Ross,et al.  1 EX / P 3-32 Results from the Sheared-Flow Stabilized Z-Pinch and Scaling to Fusion Conditions , 2016 .

[51]  R. Mcbride,et al.  Conceptual designs of two petawatt-class pulsed-power accelerators for high-energy-density-physics experiments , 2015 .

[52]  N. Augustine Rising Above The Gathering Storm: Energizing and Employing America for a Brighter Economic Future , 2006 .

[53]  D. Cunningham,et al.  Current and future directions in power electronic devices and circuits based on wide band-gap semiconductors , 2017, 2017 IEEE 5th Workshop on Wide Bandgap Power Devices and Applications (WiPDA).

[54]  F. MacKintosh,et al.  Normal stresses in semiflexible polymer hydrogels. , 2017, Physical review. E.

[55]  U. Shumlak Increasing Plasma Parameters using Sheared Flow Stabilization of a Z-Pinch , 2016 .

[56]  T Anklam LIFE Cost of Electricity, Capital and Operating Costs , 2011 .

[57]  John Slough,et al.  The Pulsed High Density Experiment: Concept, Design, and Initial Results , 2007 .

[58]  D. R. Welch,et al.  Spherically Imploding Plasma Liners as a Standoff Driver for Magnetoinertial Fusion , 2012, IEEE Transactions on Plasma Science.

[59]  A. Sefkow,et al.  Inferring fuel areal density from secondary neutron yields in laser-driven magnetized liner inertial fusion , 2019, Physics of Plasmas.

[60]  Alan L. Hoffman,et al.  Transport, energy balance, and stability of a large field‐reversed configuration , 1995 .

[61]  Shengtai Li,et al.  THREE-DIMENSIONAL MHD SIMULATION OF THE CALTECH PLASMA JET EXPERIMENT: FIRST RESULTS , 2014, 1407.3498.

[62]  J. Lawson SOME CRITERIA FOR A POWER PRODUCING THERMONUCLEAR REACTOR , 1957 .

[63]  M. Kaur,et al.  Measuring the equations of state in a relaxed magnetohydrodynamic plasma. , 2017, Physical review. E.

[64]  S. Slutz,et al.  Pulsed-power-driven cylindrical liner implosions of laser preheated fuel magnetized with an axial field , 2010 .

[65]  M. Kaur,et al.  Temperature and Lifetime Measurements in the SSX Wind Tunnel , 2018, Plasma.

[66]  M. Glinsky,et al.  Enhancing performance of magnetized liner inertial fusion at the Z facility , 2018, Physics of Plasmas.

[67]  M. Ross,et al.  Characterization of a Liner-on-Target Gas Injector for Staged Z-Pinch Experiments , 2018, IEEE Transactions on Plasma Science.

[68]  Stephen Odell Dean Search for the Ultimate Energy Source: A History of the U.S. Fusion Energy Program , 2013 .

[69]  P. Bellan,et al.  Experimental investigation of the compression and heating of an MHD-driven jet impacting a target cloud , 2018, Physics of Plasmas.