Deficiencies in compression and yield in x-ray-driven implosions

Thomas, C.A.; Campbell, E.M.; Baker, K.L.; Casey, D.T.; Hohenberger, M.; Kritcher, A.L.; Spears, B.K.; Khan, S.F.; Nora, R.; Woods, D.T.; Milovich, J.L.; Berger, R.L.; Strozzi, D.; Ho, D.D.; Clark, D.; Bachmann, B.; Benedetti, L.R.; Bionta, R.; Celliers, P.M.; Fittinghoff, D.N.; Grim, G.; Hatarik, R.; Izumi, N.; Kyrala, G.; Ma, T.; Millot, M.; Nagel, S.R.; Patel, P.K.; Yeamans, C.; Nikroo, A.; Tabak, M.; Gatu Johnson, Maria; Volegov, P.L.; Finnegan, S.M.

Author(s)

Thomas, C.A.; Campbell, E.M.; Baker, K.L.; Casey, D.T.; Hohenberger, M.; ... Show more

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Abstract

This paper analyzes x-ray–driven implosions that are designed to be less sensitive to 2-D and 3-D effects in hohlraum and capsule physics. Key performance metrics including the burn-averaged ion temperature, hot-spot areal density, and fusion yield are found to agree with simulations where the design adiabat (internal pressure) is multiplied by a factor of 1.4. These results motivate the development of a simple model for interpreting experimental data, which is then used to quantify how improvements in compression could help achieve ignition.

Description

Submitted for publication in Physics of Plasmas

Date issued

2018-07

URI

https://hdl.handle.net/1721.1/158594

Department

Massachusetts Institute of Technology. Plasma Science and Fusion Center

Journal

Physics of Plasmas

Publisher

AIP

Other identifiers

18ja153

Collections

Journal Article Series (JA)
MIT Open Access Articles