Impact-driven shock waves and thermonuclear neutron generation

Gus’kov, S. Yu.; Azechi, H.; Demchenko, N. N.; Doskoch, Igor Ya.; Murakami, M.; Rozanov, V. B.; Sakaiya, T.; Watari, T.; Змитренко, Н. В.

doi:10.1088/0741-3335/51/9/095001

Cited by 15 publications

(8 citation statements)

References 9 publications

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“…For example, a recent analysis of such planar collisions by Gus'kov et al 17 indicates that there may be insufficient time for electron and ion temperature equilibration. If this was the case it would imply that a lower V eff corresponds to the measured ion temperature.…”

Section: A Collision Hydrodynamicsmentioning

confidence: 99%

Acceleration to high velocities and heating by impact using Nike KrF laser

et al. 2010

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The Nike krypton fluoride laser ͓S. P. Obenschain, S. E. Bodner, D. Colombant, et al., Phys. Plasmas 3, 2098 ͑1996͔͒ is used to accelerate planar plastic foils to velocities that for the first time reach 1000 km/s. Collision of the highly accelerated deuterated polystyrene foil with a stationary target produces ϳGbar shock pressures and results in heating of the foil to thermonuclear temperatures. The impact conditions are diagnosed using DD fusion neutron yield, with ϳ10 6 neutrons produced during the collision. Time-of-flight neutron detectors are used to measure the ion temperature upon impact, which reaches 2-3 keV.

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Section: A Collision Hydrodynamicsmentioning

confidence: 99%

Acceleration to high velocities and heating by impact using Nike KrF laser

et al. 2010

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“…In our hypothesis, nuclear reaction (and likely even fusion) would happen while migrating in front of the object hot plasma [41] formed from vaporised rock. Neutrons produced in the plasma penetrate and react in the undisturbed host rock.…”

Section: Proposed Verification Of the Hypothesismentioning

confidence: 84%

Are Kimberlite Pipes a Kind of Macroscopic Nuclear Tracks Formed in Collision with CUDO?

Paszkowski¹,

Mietelski²

2013

Acta Phys. Pol. B

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A new, unorthodox mechanism is proposed to explain the formation of kimberlite pipes supposed to have been formed as the result of cosmic ultra-dense objects (CUDO) passing through the Earth. Moreover, it is proposed that due to such a passage, neutrons produced in nuclear reactions in the plasma formed at the front of passing objects, cause natural elements abundances and their isotopic ratios to change. Thus, to assess our model and hopefully obtain an indirect proof to CUDO class objects existence, we suggest researching such geochemical anomalies in crustal country rocks around kimberlite pipes, as well as in xenoliths embedded in kimberlite materials.

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“…As it was mentioned in section 3, one of the factors determining the pressure of the shock generated in the LICPA-driven collider is the projectile density at the moment of its collision with the impacted target. When the density of the impacting projectile is much lower than the target density, the energy transfer from the projectile to the target can be far from the optimal one [24] and the efficiency of the shock generation can be low. A simple way to increase the density of the impacting projectile is using the projectile material of higher initial density.…”

Section: The Effect Of Projectile Density and Laser Energy On Shock G...mentioning

confidence: 99%

The LICPA-driven collider—a novel efficient tool for the production of ultra-high pressures in condensed media

et al. 2016

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A: Generation of strong shock waves for the production of Mbar or Gbar pressures is a topic of high relevance for contemporary research in various domains, including inertial confinement fusion, laboratory astrophysics, planetology and material science. The pressures in the multi-Mbar range can be produced by the shocks generated using chemical explosions, light-gas guns, Z-pinch machines or lasers. Higher pressures, in the sub-Gbar or Gbar range are attainable only with nuclear explosions or laser-based methods. Unfortunately, due to the low efficiency of energy conversion from a laser to the shock (below a few percent), multi-kJ, multi-beam lasers are needed to produce such pressures with these methods. Here, we propose and investigate a novel scheme for generating high-pressure shocks which is much more efficient than the laser-based schemes known so far. In the proposed scheme, the shock is generated in a dense target by the impact of a fast projectile driven by the laser-induced cavity pressure acceleration (LICPA) mechanism. Using two-dimensional hydrodynamic simulations and the measurements performed at the kilojoule PALS laser facility it is shown that in the LICPA-driven collider the laser-to-shock energy conversion efficiency can reach a very high value ∼ 15-20 % and, as a result, the shock pressure ∼ 0.5-1 Gbar can be produced using lasers of energy 0.5 kJ. On the other hand, the pressures in the multi-Mbar range could be produced in this collider with low-energy (∼ 10 J) lasers available on the market. It would open up the possibility of conducting research in high energy-density science also in small, university-class laboratories. K: Plasma generation (laser-produced, RF, x ray-produced); Plasma diagnostics -interferometry, spectroscopy and imaging 1Corresponding author.

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Impact-driven shock waves and thermonuclear neutron generation

Cited by 15 publications

References 9 publications

Acceleration to high velocities and heating by impact using Nike KrF laser

Acceleration to high velocities and heating by impact using Nike KrF laser

Are Kimberlite Pipes a Kind of Macroscopic Nuclear Tracks Formed in Collision with CUDO?

The LICPA-driven collider—a novel efficient tool for the production of ultra-high pressures in condensed media

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