Your search keyword '"Bott AFA"' showing total 12 results

1. Role of collisionality and radiative cooling in supersonic plasma jet collisions of different materials

Author

Bott, AFA and Gregori, G

Abstract

Currently there is considerable interest in creating scalable laboratory plasmas to study the mechanisms behind the formation and evolution of astrophysical phenomena such as Herbig-Haro (HH) objects and supernova remnants (SNRs). Laboratory-scaled experiments can provide a well diagnosed and repeatable supplement to direct observations of these extra-terrestrial objects if they meet similarity criteria demonstrating that the same physics govern both systems. Here we present a study on the role of collision and cooling rates on shock formation using colliding jets from opposed conical wire arrays on a compact pulsed-power driver. These diverse conditions were achieved by changing the wire material feeding the jets, since the ion-ion mean free path (λmfp-ii) and radiative cooling rates (PRad) increase with atomic number. Low Z carbon flows produced smooth, temporally stable shocks. Weakly-collisional, moderately-cooled aluminum flows produced strong shocks that developed signs of thermal condensation instabilities and turbulence. Weakly-collisional, strongly-cooled copper flows collided to form thin shocks that developed inconsistently and fragmented. Effectively collisionless, strongly cooled tungsten flows interpenetrated, producing long axial density perturbations.

2. Saturation of the compression of two interacting magnetized plasma toroids evidenced in the laboratory.

Author

Sladkov A, Fegan C, Yao W, Bott AFA, Chen SN, Ahmed H, Filippov ED, Lelièvre R, Martin P, McIlvenny A, Waltenspiel T, Antici P, Borghesi M, Pikuz S, Ciardi A, d'Humières E, Soloviev A, Starodubtsev M, and Fuchs J

Abstract

Interactions between magnetic fields advected by matter play a fundamental role in the Universe at a diverse range of scales. A crucial role these interactions play is in making turbulent fields highly anisotropic, leading to observed ordered fields. These in turn, are important evolutionary factors for all the systems within and around. Despite scant evidence, due to the difficulty in measuring even near-Earth events, the magnetic field compression factor in these interactions, measured at very varied scales, is limited to a few. However, compressing matter in which a magnetic field is embedded, results in compression up to several thousands. Here we show, using laboratory experiments and matching three-dimensional hybrid simulations, that there is indeed a very effective saturation of the compression when two independent parallel-oriented magnetic fields regions encounter one another due to plasma advection. We found that the observed saturation is linked to a build-up of the magnetic pressure, which decelerates and redirects the inflows at their encounter point, thereby stopping further compression. Moreover, the growth of an electric field, induced by the incoming flows and the magnetic field, acts in redirecting the inflows transversely, further hampering field compression., Competing Interests: Competing interests: The authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

3. Laboratory realization of relativistic pair-plasma beams.

Author

Arrowsmith CD, Simon P, Bilbao PJ, Bott AFA, Burger S, Chen H, Cruz FD, Davenne T, Efthymiopoulos I, Froula DH, Goillot A, Gudmundsson JT, Haberberger D, Halliday JWD, Hodge T, Huffman BT, Iaquinta S, Miniati F, Reville B, Sarkar S, Schekochihin AA, Silva LO, Simpson R, Stergiou V, Trines RMGM, Vieu T, Charitonidis N, Bingham R, and Gregori G

Abstract

Relativistic electron-positron plasmas are ubiquitous in extreme astrophysical environments such as black-hole and neutron-star magnetospheres, where accretion-powered jets and pulsar winds are expected to be enriched with electron-positron pairs. Their role in the dynamics of such environments is in many cases believed to be fundamental, but their behavior differs significantly from typical electron-ion plasmas due to the matter-antimatter symmetry of the charged components. So far, our experimental inability to produce large yields of positrons in quasi-neutral beams has restricted the understanding of electron-positron pair plasmas to simple numerical and analytical studies, which are rather limited. We present the first experimental results confirming the generation of high-density, quasi-neutral, relativistic electron-positron pair beams using the 440 GeV/c beam at CERN's Super Proton Synchrotron (SPS) accelerator. Monte Carlo simulations agree well with the experimental data and show that the characteristic scales necessary for collective plasma behavior, such as the Debye length and the collisionless skin depth, are exceeded by the measured size of the produced pair beams. Our work opens up the possibility of directly probing the microphysics of pair plasmas beyond quasi-linear evolution into regimes that are challenging to simulate or measure via astronomical observations., (© 2024. The Author(s).)

Published

2024

4. Strong suppression of heat conduction in a laboratory replica of galaxy-cluster turbulent plasmas.

Author

Meinecke J, Tzeferacos P, Ross JS, Bott AFA, Feister S, Park HS, Bell AR, Blandford R, Berger RL, Bingham R, Casner A, Chen LE, Foster J, Froula DH, Goyon C, Kalantar D, Koenig M, Lahmann B, Li C, Lu Y, Palmer CAJ, Petrasso RD, Poole H, Remington B, Reville B, Reyes A, Rigby A, Ryu D, Swadling G, Zylstra A, Miniati F, Sarkar S, Schekochihin AA, Lamb DQ, and Gregori G

Abstract

In conventional gases and plasmas, it is known that heat fluxes are proportional to temperature gradients, with collisions between particles mediating energy flow from hotter to colder regions and the coefficient of thermal conduction given by Spitzer's theory. However, this theory breaks down in magnetized, turbulent, weakly collisional plasmas, although modifications are difficult to predict from first principles due to the complex, multiscale nature of the problem. Understanding heat transport is important in astrophysical plasmas such as those in galaxy clusters, where observed temperature profiles are explicable only in the presence of a strong suppression of heat conduction compared to Spitzer's theory. To address this problem, we have created a replica of such a system in a laser laboratory experiment. Our data show a reduction of heat transport by two orders of magnitude or more, leading to large temperature variations on small spatial scales (as is seen in cluster plasmas).

Published

2022

5. Inefficient Magnetic-Field Amplification in Supersonic Laser-Plasma Turbulence.

Author

Bott AFA, Chen L, Boutoux G, Caillaud T, Duval A, Koenig M, Khiar B, Lantuéjoul I, Le-Deroff L, Reville B, Rosch R, Ryu D, Spindloe C, Vauzour B, Villette B, Schekochihin AA, Lamb DQ, Tzeferacos P, Gregori G, and Casner A

Abstract

We report a laser-plasma experiment that was carried out at the LMJ-PETAL facility and realized the first magnetized, turbulent, supersonic (Ma_{turb}≈2.5) plasma with a large magnetic Reynolds number (Rm≈45) in the laboratory. Initial seed magnetic fields were amplified, but only moderately so, and did not become dynamically significant. A notable absence of magnetic energy at scales smaller than the outer scale of the turbulent cascade was also observed. Our results support the notion that moderately supersonic, low-magnetic-Prandtl-number plasma turbulence is inefficient at amplifying magnetic fields compared to its subsonic, incompressible counterpart.

Published

2021

6. Time-resolved turbulent dynamo in a laser plasma.

Author

Bott AFA, Tzeferacos P, Chen L, Palmer CAJ, Rigby A, Bell AR, Bingham R, Birkel A, Graziani C, Froula DH, Katz J, Koenig M, Kunz MW, Li C, Meinecke J, Miniati F, Petrasso R, Park HS, Remington BA, Reville B, Ross JS, Ryu D, Ryutov D, Séguin FH, White TG, Schekochihin AA, Lamb DQ, and Gregori G

Abstract

Understanding magnetic-field generation and amplification in turbulent plasma is essential to account for observations of magnetic fields in the universe. A theoretical framework attributing the origin and sustainment of these fields to the so-called fluctuation dynamo was recently validated by experiments on laser facilities in low-magnetic-Prandtl-number plasmas ([Formula: see text]). However, the same framework proposes that the fluctuation dynamo should operate differently when [Formula: see text], the regime relevant to many astrophysical environments such as the intracluster medium of galaxy clusters. This paper reports an experiment that creates a laboratory [Formula: see text] plasma dynamo. We provide a time-resolved characterization of the plasma's evolution, measuring temperatures, densities, flow velocities, and magnetic fields, which allows us to explore various stages of the fluctuation dynamo's operation on seed magnetic fields generated by the action of the Biermann-battery mechanism during the initial drive-laser target interaction. The magnetic energy in structures with characteristic scales close to the driving scale of the stochastic motions is found to increase by almost three orders of magnitude and saturate dynamically. It is shown that the initial growth of these fields occurs at a much greater rate than the turnover rate of the driving-scale stochastic motions. Our results point to the possibility that plasma turbulence produced by strong shear can generate fields more efficiently at the driving scale than anticipated by idealized magnetohydrodynamics (MHD) simulations of the nonhelical fluctuation dynamo; this finding could help explain the large-scale fields inferred from observations of astrophysical systems., Competing Interests: Competing interest statement: The authors declare a competing interest (as defined by PNAS policy). A.F.A.B., M.W.K., and N.A.B. are affiliated with Princeton University. They have not collaborated. The authors declare that they have no other conflicts of interest.

Published

2021

7. Observations of pressure anisotropy effects within semi-collisional magnetized plasma bubbles.

Author

Tubman ER, Joglekar AS, Bott AFA, Borghesi M, Coleman B, Cooper G, Danson CN, Durey P, Foster JM, Graham P, Gregori G, Gumbrell ET, Hill MP, Hodge T, Kar S, Kingham RJ, Read M, Ridgers CP, Skidmore J, Spindloe C, Thomas AGR, Treadwell P, Wilson S, Willingale L, and Woolsey NC

Abstract

Magnetized plasma interactions are ubiquitous in astrophysical and laboratory plasmas. Various physical effects have been shown to be important within colliding plasma flows influenced by opposing magnetic fields, however, experimental verification of the mechanisms within the interaction region has remained elusive. Here we discuss a laser-plasma experiment whereby experimental results verify that Biermann battery generated magnetic fields are advected by Nernst flows and anisotropic pressure effects dominate these flows in a reconnection region. These fields are mapped using time-resolved proton probing in multiple directions. Various experimental, modelling and analytical techniques demonstrate the importance of anisotropic pressure in semi-collisional, high-β plasmas, causing a reduction in the magnitude of the reconnecting fields when compared to resistive processes. Anisotropic pressure dynamics are crucial in collisionless plasmas, but are often neglected in collisional plasmas. We show pressure anisotropy to be essential in maintaining the interaction layer, redistributing magnetic fields even for semi-collisional, high energy density physics (HEDP) regimes.

Published

2021

8. Role of collisionality and radiative cooling in supersonic plasma jet collisions of different materials.

Author

Collins GW, Valenzuela JC, Speliotopoulos CA, Aybar N, Conti F, Beg FN, Tzeferacos P, Khiar B, Bott AFA, and Gregori G

Abstract

Currently there is considerable interest in creating scalable laboratory plasmas to study the mechanisms behind the formation and evolution of astrophysical phenomena such as Herbig-Haro objects and supernova remnants. Laboratory-scaled experiments can provide a well diagnosed and repeatable supplement to direct observations of these extraterrestrial objects if they meet similarity criteria demonstrating that the same physics govern both systems. Here, we present a study on the role of collision and cooling rates on shock formation using colliding jets from opposed conical wire arrays on a compact pulsed-power driver. These diverse conditions were achieved by changing the wire material feeding the jets, since the ion-ion mean free path (λ_{mfp-ii}) and radiative cooling rates (P_{rad}) increase with atomic number. Low Z carbon flows produced smooth, temporally stable shocks. Weakly collisional, moderately cooled aluminum flows produced strong shocks that developed signs of thermal condensation instabilities and turbulence. Weakly collisional, strongly cooled copper flows collided to form thin shocks that developed inconsistently and fragmented. Effectively collisionless, strongly cooled tungsten flows interpenetrated, producing long axial density perturbations.

Published

2020

9. Retrieving fields from proton radiography without source profiles.

Author

Kasim MF, Bott AFA, Tzeferacos P, Lamb DQ, Gregori G, and Vinko SM

Abstract

Proton radiography is a technique in high-energy density science to diagnose magnetic and/or electric fields in a plasma by firing a proton beam and detecting its modulated intensity profile on a screen. Current approaches to retrieve the integrated field from the modulated intensity profile require the unmodulated beam intensity profile before the interaction, which is rarely available experimentally due to shot-to-shot variability. In this paper, we present a statistical method to retrieve the integrated field without needing to know the exact source profile. We apply our method to experimental data, showing the robustness of our approach. Our proposed technique allows for the retrieval not only of the path-integrated fields, but also of the statistical properties of the fields.

Published

2019

10. Thomson scattering cross section in a magnetized, high-density plasma.

Author

Bott AFA and Gregori G

Abstract

We calculate the Thomson scattering cross section in a nonrelativistic, magnetized, high-density plasma-in a regime where collective excitations can be described by magnetohydrodynamics. We show that, in addition to cyclotron resonances and an elastic peak, the cross section exhibits two pairs of peaks associated with slow and fast magnetosonic waves; by contrast, the cross section arising in pure hydrodynamics possesses just a single pair of Brillouin peaks. Both the position and the width of these magnetosonic-wave peaks depend on the ambient magnetic field and temperature, as well as transport and thermodynamic coefficients, and so can therefore serve as a diagnostic tool for plasma properties that are otherwise challenging to measure.

Published

2019

11. Supersonic plasma turbulence in the laboratory.

Author

White TG, Oliver MT, Mabey P, Kühn-Kauffeldt M, Bott AFA, Döhl LNK, Bell AR, Bingham R, Clarke R, Foster J, Giacinti G, Graham P, Heathcote R, Koenig M, Kuramitsu Y, Lamb DQ, Meinecke J, Michel T, Miniati F, Notley M, Reville B, Ryu D, Sarkar S, Sakawa Y, Selwood MP, Squire J, Scott RHH, Tzeferacos P, Woolsey N, Schekochihin AA, and Gregori G

Abstract

The properties of supersonic, compressible plasma turbulence determine the behavior of many terrestrial and astrophysical systems. In the interstellar medium and molecular clouds, compressible turbulence plays a vital role in star formation and the evolution of our galaxy. Observations of the density and velocity power spectra in the Orion B and Perseus molecular clouds show large deviations from those predicted for incompressible turbulence. Hydrodynamic simulations attribute this to the high Mach number in the interstellar medium (ISM), although the exact details of this dependence are not well understood. Here we investigate experimentally the statistical behavior of boundary-free supersonic turbulence created by the collision of two laser-driven high-velocity turbulent plasma jets. The Mach number dependence of the slopes of the density and velocity power spectra agree with astrophysical observations, and supports the notion that the turbulence transitions from being Kolmogorov-like at low Mach number to being more Burgers-like at higher Mach numbers.

Published

2019

12. Laboratory evidence of dynamo amplification of magnetic fields in a turbulent plasma.

Author

Tzeferacos P, Rigby A, Bott AFA, Bell AR, Bingham R, Casner A, Cattaneo F, Churazov EM, Emig J, Fiuza F, Forest CB, Foster J, Graziani C, Katz J, Koenig M, Li CK, Meinecke J, Petrasso R, Park HS, Remington BA, Ross JS, Ryu D, Ryutov D, White TG, Reville B, Miniati F, Schekochihin AA, Lamb DQ, Froula DH, and Gregori G

Abstract

Magnetic fields are ubiquitous in the Universe. The energy density of these fields is typically comparable to the energy density of the fluid motions of the plasma in which they are embedded, making magnetic fields essential players in the dynamics of the luminous matter. The standard theoretical model for the origin of these strong magnetic fields is through the amplification of tiny seed fields via turbulent dynamo to the level consistent with current observations. However, experimental demonstration of the turbulent dynamo mechanism has remained elusive, since it requires plasma conditions that are extremely hard to re-create in terrestrial laboratories. Here we demonstrate, using laser-produced colliding plasma flows, that turbulence is indeed capable of rapidly amplifying seed fields to near equipartition with the turbulent fluid motions. These results support the notion that turbulent dynamo is a viable mechanism responsible for the observed present-day magnetization.

Published

2018