T.E. Cowan, Y. Sentoku, M. Bakeman, B. Chrisman*, E. d’Humieres, S. Gaillard, J. Rassuchine*

1. Fusion Science Center of Excellence for Fast Ignition and Extreme States of MatterNTF Status, Cone Target PhysicsChicago O’Hare Hilton 28 February 2007 T.E. Cowan, Y. Sentoku, M. Bakeman, B. Chrisman*, E. d’Humieres, S. Gaillard, J. Rassuchine* Department of Physics University of Nevada, Reno *partial graduate support from FSC

2. Leopard laser commissioning in progress • Schedule shift due to budget continuing resolution (CR) • Commissioning and laser characterization planned through FY07 • Insufficient support for outside “users” while under CR • Minimal “start up” test experiments might be possible within limited UNR program (i.e., collaboration, not as user) • Point of Contact: T.C., or Jeff Thompson, Acting Director

3. On the brighter side…. Good progress with nanofabricated cone-shaped laser targets…. Free Standing Au (10 mm wall) x-ray proton Free Standing Cu (10mm wall) x-ray HED Smoother (!) than prior cones

4. 16.7 um 37.3 um 3.33 um 500 nm 1.0 um Inside sub-micron tip apex: conical, with vestige of Si etch planes. Closer to sharp-tip, Sentoku simulation

6. Experiment summary of x-ray production and proton beam generation March 2006 LANL-Trident, enhanced proton beam, Au “pizza” tops ~2.5% conversion efficiency to protons, 1.5x max energy (M. Hegelich, K. Flippo) June 2006 LLNL-Titan, proton acceleration (P. Patel, J. Rassuchine, S. Gaillard) July 2006 LULI-100 TW, Au “pizza” tops, reduced mass, pre-pulse! (S. Gaillard, J. Rassuchine, M. Bakeman, J. Fuchs, M. Borghesi, O. Willi) August 2006 LANL-Trident, systematics of Au “pizza” tops, alignment! (K. Flippo, S. Gaillard, J. Rassuchine, M. Bakeman, M. Hegelich) December 2006 LULI-100 TW, 1w, 2w comparison with Cu cones & funnels x-ray emission from hot Cu – similar to 50 mm reduced mass (S. Baton, M. Koenig, J. Rassuchine, R. Kodama) summer/fall 2007 LBNL-L’OASIS (3 J, 30 fs); LULI; LANL; Leopard

7. Range of neck and top parameters explored 25 / 5 / 80 mm 50 / 30 / 90 mm Typical Reduced-Mass “Pizza” Target Parameters: Neck OD / Neck ID / Top Diameter Enhanced laser-coupling efficiency, and some increase in proton energy observed at Trident (LANL, UNR, GSI)

8. Alignment is crucial… a postieri determination of laser coupling to cone (central or offset) from proton pattern Central: acceleration from pizza top; 1.5x higher peak proton energy, better collimation, conversion eff. compared to flat foil PIC simulation of longitudinal E-field (E. d’Humieres) Offset: acceleration from cone sides, lower peak proton energy

9. Enhanced acceleration efficiency, despite no surface treatment….more to come? Titan: 200 J/500 fs (10 mm Au, flat) H+ unheated pizza-top dN/dE = 1.5e11 [p/MeV] * exp(-E / 4.5 MeV) N ~ 6.1011 protons, 0.49 J, Elaser = 19 J, h ~ 2.5% several-fold increase in laser-proton acceleration efficiency !

10. Concerns about plasma pre-fill on reproducibility  2w vs. 1w comparison at LULI-100 TW Nov-Dec 2006 S. Baton, M. Koenig, D. Batani, R. Kodama, J. Fuchs J. Rassuchine, Y. Sentoku, T.E. Cowan, E. d’Humieres (UNR) Cu cones – sharp, blunt, “funnel”, with Cu Ka imaging & spectroscopy

11. Defocused 50um with New PHA Defocused 50um High contrast improves laser penetration to cone neck… Transverse Cu Ka imaging: 1w (#119)2w (#96) • - Smaller transverse size of emission zone at 2w (further into neck) • Laser absorption occurs approx. further 50 mm upstream, for 1w • (ASE/prepulse contrast ~ 10-7:1)

12. 1w: Shot #121: Cone #31 1w: Shot #119: Cone #49 1w: Shot #120: Cone #50 New PHA Defocused 50um with New PHA Defocused 50um with New PHA Dcrystal= 8mm ∆lambda = [1.5407:1.54] = 0.0007 A Dcrystal= 8mm ∆lambda = [1.5407:1.54] = 0.0007 A 2w,PH: Shot #97: Cone #48 2w,PH: Shot #98: Cone #43 2w,PH: Shot #96: Cone #47 Defocused 50um Dcrystal= 8mm ∆lambda = [1.5408:1.5402] = 0.0006 A

13. 1w,Shot #119: Cone #49 2w,Shot #96: Cone #47 Defocused 50um Defocused 50um with New PHA Rear surface imaging consistent with transverse… Rear-side (end-on) Cu Ka imaging: • - Smaller transverse size of emission zone at 2w (further into neck)

14. 1w 2w 1w Defocused 50um Defocused 30um up 1w Blunt Cone is 22-37% smaller than Sharp Cone 1w Funnel Cone is 32% and 8% smaller than Sharp and Blunt cone respectively 2w Funnel Cone is 11% and 19% smaller than Sharp and Blunt cone respectively Funnel Cone is 87% smaller than 300um Disk at 1w and 90% at 2w

15. X-ray spectroscopy: increased emission from “hot” ionized-Cu for high contrast (5th order) Spectrometer Data Definition Kα1 and Kα2 Lower energy continuum Total hot spectrum Hot Spectrum Continuum background

16. Hot Cu (Ka pk-to-valley) observed for cones vs. flat at 1w

17. 2w: ionization above F-like. Comparable yield/heating to 50 mm dia. reduced mass, despite huge mass

18. 1w 2w 1w “Cold” Ka yield (Ne-like to neutral) 1w: Total Cold Cu Ka for cones ~ 1.5x higher yield than Multilayer 2w: Total Cold Cu Ka for cone~ 2-4x higher yield than Multilayer and Reduced Mass

19. 1w 2w 1w “Hot” Cu x-ray yield (Li-like to F-like)

20. 2006 progress in sharp-tip cone target physics: • Nanofabrication techniques are promising.…. • Preplasma filling (laser contrast) appears to be very important…. • Enhanced proton acceleration observed (confined hot electron sheath) • X-ray emisison from hot matter observed (similar to reduced mass foils) • Interesting alternative/complement to reduced mass targets: • hot electron concentration • maintains sheath quality for acceleration • more mass for x-ray production • mass produced on wafer • relaxed handling (at cost of more stringent contrast & pointing) • complex geometries possible