The velocity campaign for ignition on NIF

D A Callahan,S H Glenzer,L J Suter,L J Atherton,A J Mackinnon,S Glenn,E A Williams,M B Schneider,L R Benedetti,J E Ralph,H F Robey,R E Olson,J L Kline,D K Bradley,E G Dzentitis,D E Hinkel,A S Moore,P M Celliers,D J Strozzi,G A Kyrala,J D Lindl,S W Haan,M D Rosen,A Nikroo,K Widmann,N B Meezan,S P Regan,D G Hicks,B J Macgowan,R P J Town,M J Edwards,T Döppner,J D Kilkenny,O L Landen,S N Dixit,J D Moody,A G Macphee,P Michel ,C Haynam ,D H Edgell ,O Jones ,Richard A London ,J Celeste ,H.c Wilkins

doi:10.1063/1.3694840

Abstract

Achieving inertial confinement fusion ignition requires a symmetric, high velocity implosion. Experiments show that we can reach 95 ± 5% of the required velocity by using a 420 TW, 1.6 MJ laser pulse. In addition, experiments with a depleted uranium hohlraum show an increase in capsule performance which suggests an additional 18 ± 5 μm/ns of velocity with uranium hohlraums over gold hohlraums. Combining these two would give 99 ± 5% of the ignition velocity. Experiments show that we have the ability to tune symmetry using crossbeam transfer. We can control the second Legendre mode (P2) by changing the wavelength separation between the inner and outer cones of laser beams. We can control the azimuthal m = 4 asymmetry by changing the wavelength separation between the 23.5 and 30 degree beams on NIF. This paper describes our “first pass” tuning the implosion velocity and shape on the National Ignition Facility laser [Moses et al., Phys. Plasmas, 16, 041006 (2009)].

Full Text