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Your search keyword '"Farrell, Audrey"' showing total 11 results
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11 results on '"Farrell, Audrey"'

1. Thermal Weibel instability induced magnetic fields co-exist with linear wakes in laser-ionized plasmas

Author

Wu, Yipeng, Farrell, Audrey, Sinclair, Mitchell, Zhang, Chaojie, Petrushina, Irina, Vafaei-Najafabadi, Navid, Babzien, Marcus, Li, William, Pogorelsky, Igor, Polyanskiy, Mikhail, Fedurin, Mikhail, Kusche, Karl, Palmer, Mark, Marsh, Ken, and Joshi, Chan

Subjects
Physics - Plasma Physics
Abstract

When a moderately intense, few-picoseconds long laser pulse ionizes gas to produce an underdense plasma column, a linear relativistic plasma wave or wake can be excited by the self-modulation instability that may prove useful for multi-bunch acceleration of externally injected electrons or positrons to high energies in a short distance. At the same time, due to the anisotropic temperature distributions of the ionized plasma electrons, the Weibel instability can self-generate magnetic fields throughout such a plasma on a few picosecond timescale. In the present paper we first show using simulations that both these effects do indeed co-exist in space and time in the plasma. Using our simulations, we make preliminary estimates of the transverse emittance growth of an externally injected beam due to the Weibel magnetic fields. We then present results of an experiment that has allowed us to measure the spatiotemporal evolution of the magnetic fields using an ultrashort relativistic electron probe beam. Both the topology and the lifetime of the Weibel instability induced magnetic fields are in reasonable agreement with the simulations.

Published
2024

2. Efficient generation and amplification of intense vortex and vector laser pulses via strongly coupled stimulated Brillouin scattering in plasmas

Author

Wu, Yipeng, Zhang, Chaojie, Nie, Zan, Sinclair, Mitchell, Farrell, Audrey, Marsh, Kenneth A, Alves, E. Paulo, Tsung, Frank, Mori, Warren B., and Joshi, Chan

Subjects
Physics - Plasma Physics, Physics - Optics
Abstract

The past decade has seen tremendous progress in the production and utilization of vortex and vector laser pulses. Although both are considered as structured light beams, the vortex lasers have helical phase fronts and phase singularities, while the vector lasers have spatially variable polarization states and polarization singularities. In contrast to the vortex pulses that carry orbital angular momentum (OAM), the vector laser pulses have a complex spin angular momentum (SAM) and OAM coupling. Despite many potential applications enabled by such pulses, the generation of high-power/-intensity vortex and vector beams remains challenging. Here, we demonstrate using theory and three-dimensional simulations that the strongly-coupled stimulated Brillouin scattering (SC-SBS) process in plasmas can be used as a promising amplification technique with up to 65% energy transfer efficiency from the pump beam to the seed beam for both vortex and vector pulses. We also show that SC-SBS is strongly polarization-dependent in plasmas, enabling an all-optical polarization control of the amplified seed beam. Additionally, the interaction of such structured lasers with plasmas leads to various angular momentum couplings and decouplings that produce intense new light structures with controllable OAM and SAM. This scheme paves the way for novel optical devices such as plasma-based amplifiers and light field manipulators.

Published
2023

4. Mapping the self-generated magnetic fields due to thermal Weibel instability

Author

Zhang, Chaojie, Wu, Yipeng, Sinclair, Mitchell, Farrell, Audrey, Marsh, Kenneth A, Petrushina, Irina, Vafaei-Najafabadi, Navid, Gaikwad, Apurva, Kupfer, Rotem, Kusche, Karl, Fedurin, Mikhail, Pogorelsky, Igor, Polyanskiy, Mikhail, Huang, Chen-Kang, Hua, Jianfei, Lu, Wei, Mori, Warren B, and Joshi, Chan

Subjects
Weibel instability, optical-field ionization, temperature anisotropy, self-magnetization, kinetic theory
Abstract

The origin of the seed magnetic field that is amplified by the galactic dynamo is an open question in plasma astrophysics. Aside from primordial sources and the Biermann battery mechanism, plasma instabilities have also been proposed as a possible source of seed magnetic fields. Among them, thermal Weibel instability driven by temperature anisotropy has attracted broad interests due to its ubiquity in both laboratory and astrophysical plasmas. However, this instability has been challenging to measure in a stationary terrestrial plasma because of the difficulty in preparing such a velocity distribution. Here, we use picosecond laser ionization of hydrogen gas to initialize such an electron distribution function. We record the 2D evolution of the magnetic field associated with the Weibel instability by imaging the deflections of a relativistic electron beam with a picosecond temporal duration and show that the measured [Formula: see text]-resolved growth rates of the instability validate kinetic theory. Concurrently, self-organization of microscopic plasma currents is observed to amplify the current modulation magnitude that converts up to ~1% of the plasma thermal energy into magnetic energy, thus supporting the notion that the magnetic field induced by the Weibel instability may be able to provide a seed for the galactic dynamo.

Published
2022

5. Efficient Generation of Tunable Magnetic and Optical Vortices Using Plasmas

Author

Wu, Yipeng, Xu, Xinlu, Zhang, Chaojie, Nie, Zan, Sinclair, Mitchell, Farrell, Audrey, Marsh, Ken A, Hua, Jianfei, Lu, Wei, Mori, Warren B., and Joshi, Chan

Subjects
Physics - Plasma Physics, Physics - Optics
Abstract

Plasma is an attractive medium for generating strong microscopic magnetic structures and tunable electromagnetic radiation with predictable topologies due to its extraordinary ability to sustain and manipulate high currents and strong fields. Here, using theory and simulations, we show efficient generation of multi-megagauss magnetic and tunable optical vortices when a sharp relativistic ionization front (IF) passes through a relatively long-wavelength Laguerre-Gaussian (LG) laser pulse with orbital angular momentum (OAM). The optical vortex is frequency upshifted within a wide spectral range simply by changing the plasma density and compressed in duration. The topological charges of both vortices can be manipulated by controlling the OAM mode of the incident LG laser and/or by controlling the topology and density of the IF. For relatively high (low) plasma densities, most energy of the incident LG laser pulse is converted to the magnetic (optical) vortex.

Published
2022

6. Electron Weibel instability induced magnetic fields in optical-field ionized plasmas

Author

Zhang, Chaojie, Wu, Yipeng, Sinclair, Mitchell, Farrell, Audrey, Marsh, Kenneth A., Hua, Jianfei, Petrushina, Irina, Vafaei-Najafabadi, Navid, Kupfer, Rotem, Kusche, Karl, Fedurin, Mikhail, Pogorelsky, Igor, Polyanskiy, Mikhail, Huang, Chen-Kang, Lu, Wei, Mori, Warren B., and Joshi, Chan

Subjects
Physics - Plasma Physics
Abstract

Generation and amplification of magnetic fields in plasmas is a long-standing topic that is of great interest to both plasma and space physics. The electron Weibel instability is a well-known mechanism responsible for self-generating magnetic fields in plasmas with temperature anisotropy and has been extensively investigated in both theory and simulations, yet experimental verification of this instability has been challenging. Recently, we demonstrated a new experimental platform that enables the controlled initialization of highly nonthermal and/or anisotropic plasma electron velocity distributions via optical-field ionization. Using an external electron probe bunch from a linear accelerator, the onset, saturation and decay of the self-generated magnetic fields due to electron Weibel instability were measured for the first time to our knowledge. In this paper, we will first present experimental results on time-resolved measurements of the Weibel magnetic fields in non-relativistic plasmas produced by Ti:Sapphire laser pulses (0.8 $\mu m$) and then discuss the feasibility of extending the study to quasi-relativistic regime by using intense $\rm CO_2$ (e.g., 9.2 $\mu m$) lasers to produce much hotter plasmas., Comment: 22 pages, 10 figures

Published
2022
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10. Electron Weibel instability induced magnetic fields in optical-field ionized plasmas

Author

Zhang, Chaojie, primary, Wu, Yipeng, additional, Sinclair, Mitchell, additional, Farrell, Audrey, additional, Marsh, Kenneth A., additional, Hua, Jianfei, additional, Petrushina, Irina, additional, Vafaei-Najafabadi, Navid, additional, Kupfer, Rotem, additional, Kusche, Karl, additional, Fedurin, Mikhail, additional, Pogorelsky, Igor, additional, Polyanskiy, Mikhail, additional, Huang, Chen-Kang, additional, Lu, Wei, additional, Mori, Warren B., additional, and Joshi, Chan, additional

Published
2022
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