论文信息 - High-energy (>70 keV) x-ray conversion efficiency measurement on the ARC laser at the National Ignition Facility - 字舞流文

High-energy (>70 keV) x-ray conversion efficiency measurement on the ARC laser at the National Ignition Facility

The Advanced Radiographic Capability (ARC) laser system at the National Ignition Facility (NIF) is designed to ultimately provide eight beamlets with a pulse duration adjustable from 1 to 30 ps, and energies up to 1.5 kJ per beamlet. Currently, four beamlets have been commissioned. In the first set of 6 commissioning target experiments, the individual beamlets were fired onto gold foil targets with energy up to 1 kJ per beamlet at 20–30 ps pulse length. The x-ray energy distribution and pulse duration were measured, yielding energy conversion efficiencies of 4–9 × 10−4 for x-rays with energies greater than 70 keV. With greater than 3 J of such x-rays, ARC provides a high-precision x-ray backlighting capability for upcoming inertial confinement fusion and high-energy-density physics experiments on NIF.

V. J. Hernandez | Hui Chen | K. N. LaFortune | John Honig | Mark Bowers | Paul J. Wegner | John K. Crane | John E. Heebner | C. C. Widmayer | Charles D. Orth | Raluca A. Negres | Pamela K. Whitman | Janice K. Lawson | Daniel H. Kalantar | Wade H. Williams | D. Browning | John M. Halpin | Michael C. Rushford | Mark R. Hermann | David Alessi | M. J. Shaw | S. N. Dixit | D. Homoelle | M. A. Prantil | Otto L. Landen | T. Döppner | G Brunton | B Fishler | Gaylen V. Erbert | Michael J. Shaw | R. Tommasini | L. Pelz | Sabrina Nagel | J. M. Di Nicola | T. Budge | M. Hohenberger | Nobuhiko Izumi | O. Landen | D. Kalantar | R. Tommasini | S. Dixit | G. J. Williams | P. Wegner | M. Bowers | G. Erbert | M. Hermann | C. Orth | M. Shaw | W. Williams | C. Widmayer | P. Whitman | R. Negres | D. Alessi | J. Heebner | D. Browning | M. Hohenberger | J. Crane | M. Rushford | N. Izumi | K. LaFortune | W. Hsing | T. Döppner | Hui-Hwa Chen | J. Honig | M. Prantil | J. D. Nicola | S. Yang | D. Martinez | P. D. Nicola | G. Brunton | T. Budge | B. Fishler | J. Halpin | M. Hamamoto | V. Hernandez | D. Homoelle | W. Hsing | S. Khan | J. Lawson | S. Nagel | L. Novikova | L. Pelz | M. Sherlock | R. Sigurdsson | Steven T. Yang | Warren Hsing | D. Martinez | P. Di Nicola | M. Hamamoto | S. F. Khan | L. Novikova | M. Sherlock | R. Sigurdsson | S. Khan | K. Lafortune | G. Williams | Shahab F. Khan | W. W. Hsing | M. Shaw

[1] S. Wilks,et al. Fast-electron-relaxation measurement for laser-solid interaction at relativistic laser intensities. , 2007, Physical review. E, Statistical, nonlinear, and soft matter physics.

[2] C. Stoeckl,et al. Effects of electron recirculation on a hard x-ray source observed during the interaction of a high intensity laser pulse with thin Au targets , 2013 .

[3] Y. P. Opachich,et al. Measuring x-ray burn history with the Streaked Polar Instrumentation for Diagnosing Energetic Radiation (SPIDER) at the National Ignition Facility (NIF) , 2012, Other Conferences.

[4] M. J. Pivovaroff,et al. Images of the laser entrance hole from the static x-ray imager at NIF. , 2010, The Review of scientific instruments.

[5] John A. Caird,et al. An overview of LLNL high-energy short-pulse technology for advanced radiography of laser fusion experiments , 2004 .

[6] L. Divol,et al. Kα and bremsstrahlung x-ray radiation backlighter sources from short pulse laser driven silver targets as a function of laser pre-pulse energy , 2014 .

[7] M. Tarisien,et al. Effect of plasma density scale length on the properties of bremsstrahlung x-ray sources created by picosecond laser pulses , 2009 .

[8] A. MacPhee,et al. Study of silver Kα and bremsstrahlung radiation from short-pulse laser-matter interactions with applications for x-ray radiography , 2010 .

[9] Jay W. Dawson,et al. Performance measurements of the injection laser system configured for picosecond scale advanced radiographic capability , 2010 .

[10] John R. Celeste,et al. eHXI: A permanently installed, hard x-ray imager for the National Ignition Facility , 2016 .

[11] B Sammuli,et al. Dilation x-ray imager a new∕faster gated x-ray imager for the NIF. , 2012, The Review of scientific instruments.

[12] L. J. Atherton,et al. Overview: Development of the National Ignition Facility and the Transition to a User Facility for the Ignition Campaign and High Energy Density Scientific Research , 2016 .

[13] C. Sorce,et al. Development of Compton radiography of inertial confinement fusion implosionsa) , 2011 .

[14] Robert Heeter,et al. The scaling of electron and positron generation in intense laser-solid interactionsa) , 2015 .

[15] Farhat Beg,et al. Bremsstrahlung and Kα fluorescence measurements for inferring conversion efficiencies into fast ignition relevant hot electrons , 2009 .

[16] Rick Trebino,et al. Measuring ultrashort laser pulses in the time-frequency domain using frequency-resolved optical gating , 1997 .

[17] B. McHale,et al. Progress on converting a NIF quad to eight, petawatt beams for advanced radiography , 2010 .

[18] A. Awwal,et al. Front Matter: Volume 9345 , 2015 .

[19] T. Ma,et al. Development of backlighting sources for a Compton radiography diagnostic of inertial confinement fusion targets (invited). , 2008, The Review of scientific instruments.

[20] Erik Brambrink,et al. High-resolution 17-75 keV backlighters for high energy density experiments , 2008 .

[21] C Stoeckl,et al. Time-resolved measurements of hot-electron equilibration dynamics in high-intensity laser interactions with thin-foil solid targets. , 2012, Physical review letters.