Coulomb explosion of nanodroplets drives the conversion of laser energy to nuclear energy

Isidore Last; Shlomo Ron; Andreas Heidenreich; Joshua Jortner

doi:10.1017/hpl.2013.10

Journals >High Power Laser Science and Engineering >Volume 1 >Issue 2 >Page 02000069 > Article

High Power Laser Science and Engineering
Vol. 1, Issue 2, 02000069 (2013)

Coulomb explosion of nanodroplets drives the conversion of laser energy to nuclear energy

Isidore Last¹, Shlomo Ron¹, Andreas Heidenreich^2、3, and Joshua Jortner^1、†,*

Author Affiliations

¹School of Chemistry, Tel Aviv University, Ramat Aviv, 69978 Tel Aviv, Israel

²Kimika Fakultatea, Euskal Herriko Unibertsitatea (UPV/EHU) and Donastia International Physics Center (DICP), P.K. 1072, 20080 Euskadi, Spain

³IKERBASQUE, Basque Foundation for Science, 48011 Bilbao, Spain

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DOI: 10.1017/hpl.2013.10 Cite this Article Set citation alerts

Isidore Last, Shlomo Ron, Andreas Heidenreich, Joshua Jortner. Coulomb explosion of nanodroplets drives the conversion of laser energy to nuclear energy[J]. High Power Laser Science and Engineering, 2013, 1(2): 02000069 Copy Citation Text

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Nanodroplet size dependence of the table-top fusion yields , Equation (1), within the source–target design for the fusion of deuterons with a solid hollow cylinder of , , solid deuterium, and deuterated polyethylene , as marked on the curves. The laser parameters are , , and . The inset shows the energy dependence of the fusion reaction probability .

Fig. 1. Nanodroplet size dependence of the table-top fusion yields

, Equation (1), within the source–target design for the fusion of deuterons with a solid hollow cylinder of

, solid deuterium, and deuterated polyethylene

, as marked on the curves. The laser parameters are

, and

. The inset shows the energy dependence of the fusion reaction probability

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A record of the currently available data for the dependence of the efficiency of conversion of laser energy to nuclear energy on the laser pulse energy for table-top fusion driven by CE of nanodroplets and in a source–target design. A comparison is presented between experimental data for DD fusion driven by CE of ( and clusters inside and outside a macroscopic plasma filament[5–8], theoretical–computational data for fusion of deuterium with light atoms , , T, and D within the source–target design (present work and reference 26), and of experimental data for DT and DD inertial fusion in ‘big science’ inertial fusion setups [28–30].

Fig. 2. A record of the currently available data for the dependence of the efficiency

of conversion of laser energy to nuclear energy on the laser pulse energy

for table-top fusion driven by CE of nanodroplets and in a source–target design. A comparison is presented between experimental data for DD fusion driven by CE of (

and

clusters inside and outside a macroscopic plasma filament^[5–8], theoretical–computational data for fusion of deuterium with light atoms

, T, and D within the source–target design (present work and reference 26), and of experimental data for DT and DD inertial fusion in ‘big science’ inertial fusion setups ^[28–30].

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