First implosion experiments with cryogenic thermonuclear fuel on the national ignition facility

Siegfried H. Glenzer; Brian K. Spears; M. John Edwards; Ethan T. Alger; Richard L. Berger; Darren L. Bleuel; David K. Bradley; Joseph A. Caggiano; Debra A. Callahan; Carlos Castro; Daniel T. Casey; Christine Choate; Daniel S. Clark; Charles J. Cerjan; Gilbert W. Collins; Eduard L. Dewald; Jean Michel G. Di Nicola; Pascale Di Nicola; Laurent Divol; Shamasundar N. Dixit; Tilo Döppner; Rebecca Dylla-Spears; Elizabeth G. Dzenitis; James E. Fair; Lars Johan Anders Frenje; M. Gatu Johnson; E. Giraldez; Vladimir Glebov; Steven M. Glenn; Steven W. Haan; Bruce A. Hammel; Stephen P. Hatchett; Christopher A. Haynam; Robert F. Heeter; Glenn M. Heestand; Hans W. Herrmann; Damien G. Hicks; Dean M. Holunga; Jeffrey B. Horner; Haibo Huang; Nobuhiko Izumi; Ogden S. Jones; Daniel H. Kalantar; Joseph D. Kilkenny; Robert K. Kirkwood; John L. Kline; James P. Knauer; Bernard Kozioziemski; Andrea L. Kritcher; Jeremy J. Kroll; George A. Kyrala; Kai N. Lafortune; Otto L. Landen; Douglas W. Larson; Ramon J. Leeper; Sebastien Le Pape; John D. Lindl; Tammy Ma; Andrew J. MacKinnon; Andrew G. MacPhee; Evan Mapoles; Patrick W. McKenty; Nathan B. Meezan; Pierre Michel; Jose L. Milovich; John D. Moody; Alastair S. Moore; Mike Moran; Kari Ann Moreno; David H. Munro; Bryan R. Nathan; Abbas Nikroo; Richard E. Olson; Charles D. Orth; Arthur Pak; Pravesh K. Patel; Tom Parham; Richard Petrasso; Joseph E. Ralph; Hans Rinderknecht; Sean P. Regan; Harry F. Robey; J. Steven Ross; Jay D. Salmonson; Craig Sangster; Jim Sater; Marilyn B. Schneider; F. H. Séguin; Michael J. Shaw; Milton J. Shoup; Paul T. Springer; Wolfgang Stoeffl; Larry J. Suter; Cliff Avery Thomas; Richard P.J. Town; Curtis Walters; Stephen V. Weber; Paul J. Wegner; Clay Widmayer; Pamela K. Whitman; Klaus Widmann; Douglas C. Wilson; Bruno M. Van Wonterghem; Brian J. MacGowan; L. Jeff Atherton; Edward I. Moses

doi:10.1088/0741-3335/54/4/045013

First implosion experiments with cryogenic thermonuclear fuel on the national ignition facility

Siegfried H. Glenzer
, Brian K. Spears
, M. John Edwards
, Ethan T. Alger
, Richard L. Berger
, Darren L. Bleuel
, David K. Bradley
, Joseph A. Caggiano
, Debra A. Callahan
, Carlos Castro
, Daniel T. Casey
, Christine Choate
, Daniel S. Clark
, Charles J. Cerjan
, Gilbert W. Collins
, Eduard L. Dewald
, Jean Michel G. Di Nicola
, Pascale Di Nicola
, Laurent Divol
, Shamasundar N. Dixit

Tilo Döppner, Rebecca Dylla-Spears, Elizabeth G. Dzenitis, James E. Fair, Lars Johan Anders Frenje, M. Gatu Johnson, E. Giraldez, Vladimir Glebov, Steven M. Glenn, Steven W. Haan, Bruce A. Hammel, Stephen P. Hatchett, Christopher A. Haynam, Robert F. Heeter, Glenn M. Heestand, Hans W. Herrmann, Damien G. Hicks, Dean M. Holunga, Jeffrey B. Horner, Haibo Huang, Nobuhiko Izumi, Ogden S. Jones, Daniel H. Kalantar, Joseph D. Kilkenny, Robert K. Kirkwood, John L. Kline, James P. Knauer, Bernard Kozioziemski, Andrea L. Kritcher, Jeremy J. Kroll, George A. Kyrala, Kai N. Lafortune, Otto L. Landen, Douglas W. Larson, Ramon J. Leeper, Sebastien Le Pape, John D. Lindl, Tammy Ma, Andrew J. MacKinnon, Andrew G. MacPhee, Evan Mapoles, Patrick W. McKenty, Nathan B. Meezan, Pierre Michel, Jose L. Milovich, John D. Moody, Alastair S. Moore, Mike Moran, Kari Ann Moreno, David H. Munro, Bryan R. Nathan, Abbas Nikroo, Richard E. Olson, Charles D. Orth, Arthur Pak, Pravesh K. Patel, Tom Parham, Richard Petrasso, Joseph E. Ralph, Hans Rinderknecht, Sean P. Regan, Harry F. Robey, J. Steven Ross, Jay D. Salmonson, Craig Sangster, Jim Sater, Marilyn B. Schneider, F. H. Séguin, Michael J. Shaw, Milton J. Shoup, Paul T. Springer, Wolfgang Stoeffl, Larry J. Suter, Cliff Avery Thomas, Richard P.J. Town, Curtis Walters, Stephen V. Weber, Paul J. Wegner, Clay Widmayer, Pamela K. Whitman, Klaus Widmann, Douglas C. Wilson, Bruno M. Van Wonterghem, Brian J. MacGowan, L. Jeff Atherton, Edward I. Moses

Lawrence Livermore National Laboratory
General Atomics
Plasma Science and Fusion Center
University of Rochester Laboratory for Laser Energetics
MST-8, Los Alamos National Laboratory
Sandia National Laboratories
AWE - Aldermaston

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Non-burning thermonuclear fuel implosion experiments have been fielded on the National Ignition Facility to assess progress toward ignition by indirect drive inertial confinement fusion. These experiments use cryogenic fuel ice layers, consisting of mixtures of tritium and deuterium with large amounts of hydrogen to control the neutron yield and to allow fielding of an extensive suite of optical, x-ray and nuclear diagnostics. The thermonuclear fuel layer is contained in a spherical plastic capsule that is fielded in the center of a cylindrical gold hohlraum. Heating the hohlraum with 1.3MJ of energy delivered by 192 laser beams produces a soft x-ray drive spectrum with a radiation temperature of 300eV. The radiation field produces an ablation pressure of 100Mbar which compresses the capsule to a spherical dense fuel shell that contains a hot plasma core 80νm in diameter. The implosion core is observed with x-ray imaging diagnostics that provide size, shape, the absolute x-ray emission along with bangtime and hot plasma lifetime. Nuclear measurements provide the 14.1MeV neutron yield from fusion of deuterium and tritium nuclei along with down-scattered neutrons at energies of 1012MeV due to energy loss by scattering in the dense fuel that surrounds the central hot-spot plasma. Neutron time-of-flight spectra allow the inference of the ion temperature while gamma-ray measurements provide the duration of nuclear activity. The fusion yield from deuteriumtritium reactions scales with ion temperature, which is in agreement with modeling over more than one order of magnitude to a neutron yield in excess of 10 ¹⁴ neutrons, indicating large confinement parameters on these first experiments.

langue originale	Anglais
Numéro d'article	045013
journal	Plasma Physics and Controlled Fusion
Volume	54
Numéro de publication	4
Les DOIs	https://doi.org/10.1088/0741-3335/54/4/045013
état	Publié - 1 avr. 2012
Modification externe	Oui

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10.1088/0741-3335/54/4/045013

Contient cette citation

Glenzer, S. H., Spears, B. K., Edwards, M. J., Alger, E. T., Berger, R. L., Bleuel, D. L., Bradley, D. K., Caggiano, J. A., Callahan, D. A., Castro, C., Casey, D. T., Choate, C., Clark, D. S., Cerjan, C. J., Collins, G. W., Dewald, E. L., Di Nicola, J. M. G., Di Nicola, P., Divol, L., ... Moses, E. I. (2012). First implosion experiments with cryogenic thermonuclear fuel on the national ignition facility. Plasma Physics and Controlled Fusion, 54(4), Article 045013. https://doi.org/10.1088/0741-3335/54/4/045013

@article{a7fb2f29599743b6be8c2fc41992604a,

title = "First implosion experiments with cryogenic thermonuclear fuel on the national ignition facility",

abstract = "Non-burning thermonuclear fuel implosion experiments have been fielded on the National Ignition Facility to assess progress toward ignition by indirect drive inertial confinement fusion. These experiments use cryogenic fuel ice layers, consisting of mixtures of tritium and deuterium with large amounts of hydrogen to control the neutron yield and to allow fielding of an extensive suite of optical, x-ray and nuclear diagnostics. The thermonuclear fuel layer is contained in a spherical plastic capsule that is fielded in the center of a cylindrical gold hohlraum. Heating the hohlraum with 1.3MJ of energy delivered by 192 laser beams produces a soft x-ray drive spectrum with a radiation temperature of 300eV. The radiation field produces an ablation pressure of 100Mbar which compresses the capsule to a spherical dense fuel shell that contains a hot plasma core 80νm in diameter. The implosion core is observed with x-ray imaging diagnostics that provide size, shape, the absolute x-ray emission along with bangtime and hot plasma lifetime. Nuclear measurements provide the 14.1MeV neutron yield from fusion of deuterium and tritium nuclei along with down-scattered neutrons at energies of 1012MeV due to energy loss by scattering in the dense fuel that surrounds the central hot-spot plasma. Neutron time-of-flight spectra allow the inference of the ion temperature while gamma-ray measurements provide the duration of nuclear activity. The fusion yield from deuteriumtritium reactions scales with ion temperature, which is in agreement with modeling over more than one order of magnitude to a neutron yield in excess of 10 14 neutrons, indicating large confinement parameters on these first experiments.",

author = "Glenzer, \{Siegfried H.\} and Spears, \{Brian K.\} and Edwards, \{M. John\} and Alger, \{Ethan T.\} and Berger, \{Richard L.\} and Bleuel, \{Darren L.\} and Bradley, \{David K.\} and Caggiano, \{Joseph A.\} and Callahan, \{Debra A.\} and Carlos Castro and Casey, \{Daniel T.\} and Christine Choate and Clark, \{Daniel S.\} and Cerjan, \{Charles J.\} and Collins, \{Gilbert W.\} and Dewald, \{Eduard L.\} and \{Di Nicola\}, \{Jean Michel G.\} and \{Di Nicola\}, Pascale and Laurent Divol and Dixit, \{Shamasundar N.\} and Tilo D{\"o}ppner and Rebecca Dylla-Spears and Dzenitis, \{Elizabeth G.\} and Fair, \{James E.\} and Frenje, \{Lars Johan Anders\} and Johnson, \{M. Gatu\} and E. Giraldez and Vladimir Glebov and Glenn, \{Steven M.\} and Haan, \{Steven W.\} and Hammel, \{Bruce A.\} and Hatchett, \{Stephen P.\} and Haynam, \{Christopher A.\} and Heeter, \{Robert F.\} and Heestand, \{Glenn M.\} and Herrmann, \{Hans W.\} and Hicks, \{Damien G.\} and Holunga, \{Dean M.\} and Horner, \{Jeffrey B.\} and Haibo Huang and Nobuhiko Izumi and Jones, \{Ogden S.\} and Kalantar, \{Daniel H.\} and Kilkenny, \{Joseph D.\} and Kirkwood, \{Robert K.\} and Kline, \{John L.\} and Knauer, \{James P.\} and Bernard Kozioziemski and Kritcher, \{Andrea L.\} and Kroll, \{Jeremy J.\} and Kyrala, \{George A.\} and Lafortune, \{Kai N.\} and Landen, \{Otto L.\} and Larson, \{Douglas W.\} and Leeper, \{Ramon J.\} and Pape, \{Sebastien Le\} and Lindl, \{John D.\} and Tammy Ma and MacKinnon, \{Andrew J.\} and MacPhee, \{Andrew G.\} and Evan Mapoles and McKenty, \{Patrick W.\} and Meezan, \{Nathan B.\} and Pierre Michel and Milovich, \{Jose L.\} and Moody, \{John D.\} and Moore, \{Alastair S.\} and Mike Moran and Moreno, \{Kari Ann\} and Munro, \{David H.\} and Nathan, \{Bryan R.\} and Abbas Nikroo and Olson, \{Richard E.\} and Orth, \{Charles D.\} and Arthur Pak and Patel, \{Pravesh K.\} and Tom Parham and Richard Petrasso and Ralph, \{Joseph E.\} and Hans Rinderknecht and Regan, \{Sean P.\} and Robey, \{Harry F.\} and Ross, \{J. Steven\} and Salmonson, \{Jay D.\} and Craig Sangster and Jim Sater and Schneider, \{Marilyn B.\} and S{\'e}guin, \{F. H.\} and Shaw, \{Michael J.\} and Shoup, \{Milton J.\} and Springer, \{Paul T.\} and Wolfgang Stoeffl and Suter, \{Larry J.\} and Thomas, \{Cliff Avery\} and Town, \{Richard P.J.\} and Curtis Walters and Weber, \{Stephen V.\} and Wegner, \{Paul J.\} and Clay Widmayer and Whitman, \{Pamela K.\} and Klaus Widmann and Wilson, \{Douglas C.\} and \{Van Wonterghem\}, \{Bruno M.\} and MacGowan, \{Brian J.\} and Atherton, \{L. Jeff\} and Moses, \{Edward I.\}",

year = "2012",

month = apr,

day = "1",

doi = "10.1088/0741-3335/54/4/045013",

language = "English",

volume = "54",

journal = "Plasma Physics and Controlled Fusion",

issn = "0741-3335",

number = "4",

}

Glenzer, SH, Spears, BK, Edwards, MJ, Alger, ET, Berger, RL, Bleuel, DL, Bradley, DK, Caggiano, JA, Callahan, DA, Castro, C, Casey, DT, Choate, C, Clark, DS, Cerjan, CJ, Collins, GW, Dewald, EL, Di Nicola, JMG, Di Nicola, P, Divol, L, Dixit, SN, Döppner, T, Dylla-Spears, R, Dzenitis, EG, Fair, JE, Frenje, LJA, Johnson, MG, Giraldez, E, Glebov, V, Glenn, SM, Haan, SW, Hammel, BA, Hatchett, SP, Haynam, CA, Heeter, RF, Heestand, GM, Herrmann, HW, Hicks, DG, Holunga, DM, Horner, JB, Huang, H, Izumi, N, Jones, OS, Kalantar, DH, Kilkenny, JD, Kirkwood, RK, Kline, JL, Knauer, JP, Kozioziemski, B, Kritcher, AL, Kroll, JJ, Kyrala, GA, Lafortune, KN, Landen, OL, Larson, DW, Leeper, RJ, Pape, SL, Lindl, JD, Ma, T, MacKinnon, AJ, MacPhee, AG, Mapoles, E, McKenty, PW, Meezan, NB, Michel, P, Milovich, JL, Moody, JD, Moore, AS, Moran, M, Moreno, KA, Munro, DH, Nathan, BR, Nikroo, A, Olson, RE, Orth, CD, Pak, A, Patel, PK, Parham, T, Petrasso, R, Ralph, JE, Rinderknecht, H, Regan, SP, Robey, HF, Ross, JS, Salmonson, JD, Sangster, C, Sater, J, Schneider, MB, Séguin, FH, Shaw, MJ, Shoup, MJ, Springer, PT, Stoeffl, W, Suter, LJ, Thomas, CA, Town, RPJ, Walters, C, Weber, SV, Wegner, PJ, Widmayer, C, Whitman, PK, Widmann, K, Wilson, DC, Van Wonterghem, BM, MacGowan, BJ, Atherton, LJ & Moses, EI 2012, 'First implosion experiments with cryogenic thermonuclear fuel on the national ignition facility', Plasma Physics and Controlled Fusion, VOL. 54, Numéro 4, 045013. https://doi.org/10.1088/0741-3335/54/4/045013

TY - JOUR

T1 - First implosion experiments with cryogenic thermonuclear fuel on the national ignition facility

AU - Glenzer, Siegfried H.

AU - Spears, Brian K.

AU - Edwards, M. John

AU - Alger, Ethan T.

AU - Berger, Richard L.

AU - Bleuel, Darren L.

AU - Bradley, David K.

AU - Caggiano, Joseph A.

AU - Callahan, Debra A.

AU - Castro, Carlos

AU - Casey, Daniel T.

AU - Choate, Christine

AU - Clark, Daniel S.

AU - Cerjan, Charles J.

AU - Collins, Gilbert W.

AU - Dewald, Eduard L.

AU - Di Nicola, Jean Michel G.

AU - Di Nicola, Pascale

AU - Divol, Laurent

AU - Dixit, Shamasundar N.

AU - Döppner, Tilo

AU - Dylla-Spears, Rebecca

AU - Dzenitis, Elizabeth G.

AU - Fair, James E.

AU - Frenje, Lars Johan Anders

AU - Johnson, M. Gatu

AU - Giraldez, E.

AU - Glebov, Vladimir

AU - Glenn, Steven M.

AU - Haan, Steven W.

AU - Hammel, Bruce A.

AU - Hatchett, Stephen P.

AU - Haynam, Christopher A.

AU - Heeter, Robert F.

AU - Heestand, Glenn M.

AU - Herrmann, Hans W.

AU - Hicks, Damien G.

AU - Holunga, Dean M.

AU - Horner, Jeffrey B.

AU - Huang, Haibo

AU - Izumi, Nobuhiko

AU - Jones, Ogden S.

AU - Kalantar, Daniel H.

AU - Kilkenny, Joseph D.

AU - Kirkwood, Robert K.

AU - Kline, John L.

AU - Knauer, James P.

AU - Kozioziemski, Bernard

AU - Kritcher, Andrea L.

AU - Kroll, Jeremy J.

AU - Kyrala, George A.

AU - Lafortune, Kai N.

AU - Landen, Otto L.

AU - Larson, Douglas W.

AU - Leeper, Ramon J.

AU - Pape, Sebastien Le

AU - Lindl, John D.

AU - Ma, Tammy

AU - MacKinnon, Andrew J.

AU - MacPhee, Andrew G.

AU - Mapoles, Evan

AU - McKenty, Patrick W.

AU - Meezan, Nathan B.

AU - Michel, Pierre

AU - Milovich, Jose L.

AU - Moody, John D.

AU - Moore, Alastair S.

AU - Moran, Mike

AU - Moreno, Kari Ann

AU - Munro, David H.

AU - Nathan, Bryan R.

AU - Nikroo, Abbas

AU - Olson, Richard E.

AU - Orth, Charles D.

AU - Pak, Arthur

AU - Patel, Pravesh K.

AU - Parham, Tom

AU - Petrasso, Richard

AU - Ralph, Joseph E.

AU - Rinderknecht, Hans

AU - Regan, Sean P.

AU - Robey, Harry F.

AU - Ross, J. Steven

AU - Salmonson, Jay D.

AU - Sangster, Craig

AU - Sater, Jim

AU - Schneider, Marilyn B.

AU - Séguin, F. H.

AU - Shaw, Michael J.

AU - Shoup, Milton J.

AU - Springer, Paul T.

AU - Stoeffl, Wolfgang

AU - Suter, Larry J.

AU - Thomas, Cliff Avery

AU - Town, Richard P.J.

AU - Walters, Curtis

AU - Weber, Stephen V.

AU - Wegner, Paul J.

AU - Widmayer, Clay

AU - Whitman, Pamela K.

AU - Widmann, Klaus

AU - Wilson, Douglas C.

AU - Van Wonterghem, Bruno M.

AU - MacGowan, Brian J.

AU - Atherton, L. Jeff

AU - Moses, Edward I.

PY - 2012/4/1

Y1 - 2012/4/1

N2 - Non-burning thermonuclear fuel implosion experiments have been fielded on the National Ignition Facility to assess progress toward ignition by indirect drive inertial confinement fusion. These experiments use cryogenic fuel ice layers, consisting of mixtures of tritium and deuterium with large amounts of hydrogen to control the neutron yield and to allow fielding of an extensive suite of optical, x-ray and nuclear diagnostics. The thermonuclear fuel layer is contained in a spherical plastic capsule that is fielded in the center of a cylindrical gold hohlraum. Heating the hohlraum with 1.3MJ of energy delivered by 192 laser beams produces a soft x-ray drive spectrum with a radiation temperature of 300eV. The radiation field produces an ablation pressure of 100Mbar which compresses the capsule to a spherical dense fuel shell that contains a hot plasma core 80νm in diameter. The implosion core is observed with x-ray imaging diagnostics that provide size, shape, the absolute x-ray emission along with bangtime and hot plasma lifetime. Nuclear measurements provide the 14.1MeV neutron yield from fusion of deuterium and tritium nuclei along with down-scattered neutrons at energies of 1012MeV due to energy loss by scattering in the dense fuel that surrounds the central hot-spot plasma. Neutron time-of-flight spectra allow the inference of the ion temperature while gamma-ray measurements provide the duration of nuclear activity. The fusion yield from deuteriumtritium reactions scales with ion temperature, which is in agreement with modeling over more than one order of magnitude to a neutron yield in excess of 10 14 neutrons, indicating large confinement parameters on these first experiments.

AB - Non-burning thermonuclear fuel implosion experiments have been fielded on the National Ignition Facility to assess progress toward ignition by indirect drive inertial confinement fusion. These experiments use cryogenic fuel ice layers, consisting of mixtures of tritium and deuterium with large amounts of hydrogen to control the neutron yield and to allow fielding of an extensive suite of optical, x-ray and nuclear diagnostics. The thermonuclear fuel layer is contained in a spherical plastic capsule that is fielded in the center of a cylindrical gold hohlraum. Heating the hohlraum with 1.3MJ of energy delivered by 192 laser beams produces a soft x-ray drive spectrum with a radiation temperature of 300eV. The radiation field produces an ablation pressure of 100Mbar which compresses the capsule to a spherical dense fuel shell that contains a hot plasma core 80νm in diameter. The implosion core is observed with x-ray imaging diagnostics that provide size, shape, the absolute x-ray emission along with bangtime and hot plasma lifetime. Nuclear measurements provide the 14.1MeV neutron yield from fusion of deuterium and tritium nuclei along with down-scattered neutrons at energies of 1012MeV due to energy loss by scattering in the dense fuel that surrounds the central hot-spot plasma. Neutron time-of-flight spectra allow the inference of the ion temperature while gamma-ray measurements provide the duration of nuclear activity. The fusion yield from deuteriumtritium reactions scales with ion temperature, which is in agreement with modeling over more than one order of magnitude to a neutron yield in excess of 10 14 neutrons, indicating large confinement parameters on these first experiments.

U2 - 10.1088/0741-3335/54/4/045013

DO - 10.1088/0741-3335/54/4/045013

M3 - Article

AN - SCOPUS:84863338296

SN - 0741-3335

VL - 54

JO - Plasma Physics and Controlled Fusion

JF - Plasma Physics and Controlled Fusion

IS - 4

M1 - 045013

ER -

First implosion experiments with cryogenic thermonuclear fuel on the national ignition facility

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