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Robinson, Allen C.; Petney, Sharon P.; Drake, Richard R.; Weirs, Vincent G.; Adams, Brian M.; Vigil, Dena V.; Carpenter, John H.; Garasi, Christopher J.; Wong, Michael K.; Robbins, Joshua R.; Siefert, Christopher S.; Strack, Otto E.; Wills, Ann E.; Trucano, Timothy G.; Bochev, Pavel B.; Summers, Randall M.; Stewart, James R.; Ober, Curtis C.; Rider, William J.; Haill, Thomas A.; Lemke, Raymond W.; Cochrane, Kyle C.; Desjarlais, Michael P.; Love, Edward L.; Voth, Thomas E.; Mosso, Stewart J.; Niederhaus, John H.
Riford, Lauren S.; Lemke, Raymond W.; Cochrane, Kyle C.
Dolan, Daniel H.; Lemke, Raymond W.; Harding, Eric H.; McBride, Ryan D.; Martin, Matthew; Dalton, Devon D.
Ao, Tommy A.; Geissel, Matthias G.; Harding, Eric H.; Bailey, James E.; Desjarlais, Michael P.; Hansen, Stephanie B.; Lemke, Raymond W.; Sinars, Daniel S.; Rochau, G.A.
Root, Seth R.; Lemke, Raymond W.; Mattsson, Thomas M.
Brown, Justin L.; Lemke, Raymond W.; Knudson, Marcus D.
Root, Seth R.; Shulenburger, Luke N.; Lemke, Raymond W.; Cochrane, Kyle C.; Mattsson, Thomas M.
Cuneo, M.E.; Davis, Jean-Paul D.; Lemke, Raymond W.; McBride, Ryan D.; Stygar, William A.
Cuneo, M.E.; Davis, Jean-Paul D.; Lemke, Raymond W.; McBride, Ryan D.; Stygar, William A.
Root, Seth R.; Magyar, Rudolph J.; Lemke, Raymond W.; Mattsson, Thomas M.
Lemke, Raymond W.
Mattsson, Thomas M.; Desjarlais, Michael P.; Dolan, Daniel H.; Flicker, Dawn G.; Knudson, Marcus D.; Lemke, Raymond W.; Root, Seth R.; Seagle, Christopher T.; Shulenburger, Luke N.
Science
Root, Seth R.; Lemke, Raymond W.; Mattsson, Thomas M.
Science
Root, Seth R.; Lemke, Raymond W.; Mattsson, Thomas M.
Lemke, Raymond W.; Dolan, Daniel H.; McBride, Ryan D.; Martin, Matthew; Davis, Jean-Paul D.; Dalton, Devon D.
Lemke, Raymond W.
Ao, Tommy A.; Smith, Ian C.; Geissel, Matthias G.; Harding, Eric H.; Bailey, James E.; Hansen, Stephanie B.; Sefkow, Adam B.; Desjarlais, Michael P.; Lemke, Raymond W.; Sinars, Daniel S.; Rochau, G.A.
Sinars, Daniel S.; Jobe, Marc R.; Lamppa, Derek C.; Lemke, Raymond W.; Martin, Matthew; Mckenney, John M.; Nakhleh, Charles N.; Owen, Albert C.; Peterson, Kyle J.; Herrmann, Mark H.; Smith, Ian C.; Vesey, Roger A.; Slutz, Stephen A.; Cuneo, M.E.; McBride, Ryan D.; Rovang, Dean C.; Sefkow, Adam B.; Jennings, Christopher A.
Ao, Tommy A.; Bailey, James E.; Hansen, Stephanie B.; Desjarlais, Michael P.; Geissel, Matthias G.; Smith, Ian C.; Sinars, Daniel S.; Lemke, Raymond W.
Lemke, Raymond W.
Bailey, James E.; Ao, Tommy A.; Harding, Eric H.; Hansen, Stephanie B.; Desjarlais, Michael P.; Lemke, Raymond W.; Rochau, G.A.; Reneker, Joseph R.; Romero, Dustin H.
Sinars, Daniel S.; Jobe, Marc R.; Lamppa, Derek C.; Martin, Matthew; Nakhleh, Charles N.; Owen, Albert C.; Mckenney, John M.; McBride, Ryan D.; Rovang, Dean C.; Sefkow, Adam B.; Slutz, Stephen A.; Lemke, Raymond W.; Cuneo, M.E.; Herrmann, Mark H.; Jennings, Christopher A.
Lemke, Raymond W.
Ao, Tommy A.; Harding, Eric H.; Bailey, James E.; Sinars, Daniel S.; Hansen, Stephanie B.; Desjarlais, Michael P.; Lemke, Raymond W.; Geissel, Matthias G.; Smith, Ian C.
Physics of Plasmas
Martin, M.R.; Lemke, Raymond W.; McBride, Ryan D.; Davis, Jean-Paul D.; Dolan, Daniel H.; Knudson, Marcus D.; Cochrane, K.R.; Sinars, Daniel S.; Smith, Ian C.; Savage, Mark E.; Stygar, William A.; Killebrew, K.; Flicker, Dawn G.; Herrmann, Mark H.
Current pulse shaping techniques, originally developed for planar dynamic material experiments on the Z-machine [M. K. Matzen, Phys. Plasmas 12, 055503 (2005)], are adapted to the design of controlled cylindrical liner implosions. By driving these targets with a current pulse shape that prevents shock formation inside the liner, shock heating is avoided along with the corresponding decrease in electrical conductivity ahead of the magnetic diffusion wave penetrating the liner. This results in an imploding liner with a significant amount of its mass in the solid phase and at multi-megabar pressures. Pressures in the solid region of a shaped pulse driven beryllium liner fielded on the Z-machine are inferred to 5.5 Mbar, while simulations suggest implosion velocities greater than 50 kms-1. These solid liner experiments are diagnosed with multi-frame monochromatic x-ray backlighting which is used to infer the material density and pressure. This work has led to a new platform on the Z-machine that can be used to perform off-Hugoniot measurements at higher pressures than are accessible through magnetically driven planar geometries. © 2012 American Institute of Physics.
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