Your search keyword '"Celeste JR"' showing total 3 results

1. Soft x-ray images of the laser entrance hole of ignition hohlraums.

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Author

Schneider MB, Meezan NB, Alvarez SS, Alameda J, Baker S, Bell PM, Bradley DK, Callahan DA, Celeste JR, Dewald EL, Dixit SN, Döppner T, Eder DC, Edwards MJ, Fernandez-Perea M, Gullikson E, Haugh MJ, Hau-Riege S, Hsing W, Izumi N, Jones OS, Kalantar DH, Kilkenny JD, Kline JL, Kyrala GA, Landen OL, London RA, MacGowan BJ, MacKinnon AJ, McCarville TJ, Milovich JL, Mirkarimi P, Moody JD, Moore AS, Myers MD, Palma EA, Palmer N, Pivovaroff MJ, Ralph JE, Robinson J, Soufli R, Suter LJ, Teruya AT, Thomas CA, Town RP, Vernon SP, Widmann K, and Young BK more...

Abstract

Hohlraums are employed at the national ignition facility to convert laser energy into a thermal x-radiation drive, which implodes a fusion capsule, thus compressing the fuel. The x-radiation drive is measured with a low spectral resolution, time-resolved x-ray spectrometer, which views the region around the hohlraum's laser entrance hole. This measurement has no spatial resolution. To convert this to the drive inside the hohlraum, the size of the hohlraum's opening ("clear aperture") and fraction of the measured x-radiation, which comes from this opening, must be known. The size of the clear aperture is measured with the time integrated static x-ray imager (SXI). A soft x-ray imaging channel has been added to the SXI to measure the fraction of x-radiation emitted from inside the clear aperture. A multilayer mirror plus filter selects an x-ray band centered at 870 eV, near the peak of the x-ray spectrum of a 300 eV blackbody. Results from this channel and corrections to the x-radiation drive are discussed. more...

Published

2012

2. X-ray bang-time and fusion reaction history at picosecond resolution using RadOptic detection.

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Vernon SP, Lowry ME, Baker KL, Bennett CV, Celeste JR, Cerjan C, Haynes S, Hernandez VJ, Hsing WW, LaCaille GA, London RA, Moran B, von Wittenau AS, Steele PT, and Stewart RE

Abstract

We report recent progress in the development of RadOptic detectors, radiation to optical converters, that rely upon x-ray absorption induced modulation of the optical refractive index of a semiconductor sensor medium to amplitude modulate an optical probe beam. The sensor temporal response is determined by the dynamics of the electron-hole pair creation and subsequent relaxation in the sensor medium. Response times of a few ps have been demonstrated in a series of experiments conducted at the LLNL Jupiter Laser Facility (JLF). This technology will enable x-ray bang-time and fusion burn-history measurements with ∼ ps resolution. more...

Published

2012

3. Images of the laser entrance hole from the static x-ray imager at NIF.

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Author

Schneider MB, Jones OS, Meezan NB, Milovich JL, Town RP, Alvarez SS, Beeler RG, Bradley DK, Celeste JR, Dixit SN, Edwards MJ, Haugh MJ, Kalantar DH, Kline JL, Kyrala GA, Landen OL, MacGowan BJ, Michel P, Moody JD, Oberhelman SK, Piston KW, Pivovaroff MJ, Suter LJ, Teruya AT, Thomas CA, Vernon SP, Warrick AL, Widmann K, Wood RD, and Young BK more...

Abstract

The static x-ray imager at the National Ignition Facility is a pinhole camera using a CCD detector to obtain images of Hohlraum wall x-ray drive illumination patterns seen through the laser entrance hole (LEH). Carefully chosen filters, combined with the CCD response, allow recording images in the x-ray range of 3-5 keV with 60 μm spatial resolution. The routines used to obtain the apparent size of the backlit LEH and the location and intensity of beam spots are discussed and compared to predictions. A new soft x-ray channel centered at 870 eV (near the x-ray peak of a 300 eV temperature ignition Hohlraum) is discussed. more...

Published

2010