Relevant bibliographies by topics / Laser-plasma interactions

Academic literature on the topic 'Laser-plasma interactions'

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Published: 4 June 2021
Last updated: 29 July 2024

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Journal articles on the topic "Laser-plasma interactions"

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Umstadter, Donald. "Relativistic laser plasma interactions." Journal of Physics D: Applied Physics 36, no. 8 (April 3, 2003): R151—R165. http://dx.doi.org/10.1088/0022-3727/36/8/202.

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Gibbon, P., and E. Förster. "Short-pulse laser - plasma interactions." Plasma Physics and Controlled Fusion 38, no. 6 (June 1, 1996): 769–93. http://dx.doi.org/10.1088/0741-3335/38/6/001.

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Wang, Qingsong, Lan Jiang, Jingya Sun, Changji Pan, Weina Han, Guoyan Wang, Feifei Wang, Kaihu Zhang, Ming Li, and Yongfeng Lu. "Structure-Mediated Excitation of Air Plasma and Silicon Plasma Expansion in Femtosecond Laser Pulses Ablation." Research 2018 (December 9, 2018): 1–11. http://dx.doi.org/10.1155/2018/5709748.

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Femtosecond laser-induced surface structures upon multiple pulses irradiation are strongly correlated with the pulse number, which in turn significantly affects successive laser-material interactions. By recording the dynamics of femtosecond laser ablation of silicon using time-resolved shadowgraphy, here we present direct visualization of the excitation of air plasma induced by the reflected laser during the second pulse irradiation. The interaction of the air plasma and silicon plasma is found to enhance the shockwave expansion induced by silicon ablation in the longitudinal direction, showing anisotropic expansion dynamics in different directions. We further demonstrate the vanishing of air plasma as the pulse number increases because of the generation of a rough surface without light focusing ability. In the scenario, the interaction of air plasma and silicon plasma disappears; the expansion of the silicon plasma and shockwave restores its original characteristic that is dominated by the laser-material coupling. The results show that the excitation of air plasma and the laser-material coupling involved in laser-induced plasma and shockwave expansion are structure mediated and dependent on the pulse number, which is of fundamental importance for deep insight into the nature of laser-material interactions during multiple pulses ablation.
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Renner, O., R. Liska, and F. B. Rosmej. "Laser-produced plasma-wall interaction." Laser and Particle Beams 27, no. 4 (December 2009): 725–31. http://dx.doi.org/10.1017/s0263034609990504.

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AbstractJets of laser–generated plasma represent a flexible and well-defined model environment for investigation of plasma interactions with solid surfaces (walls). The pilot experiments carried out on the iodine laser system (5–200 J, 0.44 µm, 0.25–0.3 ns, <1×1016 W/cm2) at the PALS Research Centre in Prague are reported. Modification of macroscopic characteristics of the Al plasma jets produced at laser-irradiated double-foil Al/Mg targets is studied by high-resolution, high-dispersion X-ray spectroscopy. The spatially variable, complex satellite structure observed in emission spectra of the Al Lyα group proves a formation of rather cold dense plasma at the laser-exploded Al foil, an occurrence of the hot plasma between both foils and subsequent thermalization, deceleration and trapping of Al ions in the colliding plasma close to the Mg foil surface. The spectra interpretation based on the collisional-radiative code is complemented by 1D and 2D hydrodynamic modeling of the plasma expansion and interaction of counter-propagating Al/Mg plasmas. The obtained results demonstrate a potential of high resolution X-ray diagnostics in investigation of the laser-produced plasma–wall interactions.
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BATANI, DIMITRI, SABRINA BIAVA, SERGIO BITTANTI, and FABIO PREVIDI. "A cellular automaton model of laser–plasma interactions." Laser and Particle Beams 19, no. 4 (October 2001): 631–42. http://dx.doi.org/10.1017/s0263034601194103.

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This paper deals with the realization of a CA model of the physical interactions occurring when high-power laser pulses are focused on plasma targets. The low-level and microscopic physical laws of interactions among the plasma and the photons in the pulse are described. In particular, electron–electron interaction via the Coulomb force and photon–electron interaction due to ponderomotive forces are considered. Moreover, the dependence on time and space of the index of refraction is taken into account, as a consequence of electron motion in the plasma. Ions are considered as a fixed background. Simulations of these interactions are provided in different conditions and the macroscopic dynamics of the system, in agreement with the experimental behavior, are evidenced.
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KIM, Chul Min, and Ki Hong PAE. "Fundamentals of Relativistic Laser-plasma Interactions." Physics and High Technology 22, no. 10 (October 31, 2013): 20. http://dx.doi.org/10.3938/phit.22.045.

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Silva, L. O., W. B. Mori, R. Bingham, J. M. Dawson, T. M. Antonsen, and P. Mora. "Photon kinetics for laser-plasma interactions." IEEE Transactions on Plasma Science 28, no. 4 (August 2000): 1128–34. http://dx.doi.org/10.1109/27.893299.

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Boyd, T. J. M. "The trouble with laser-plasma interactions." Plasma Physics and Controlled Fusion 28, no. 12B (December 1, 1986): 1887–903. http://dx.doi.org/10.1088/0741-3335/28/12b/002.

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Wilks, S. C. "Simulations of ultraintense laser–plasma interactions*." Physics of Fluids B: Plasma Physics 5, no. 7 (July 1993): 2603–8. http://dx.doi.org/10.1063/1.860697.

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Kemp, A. J., F. Fiuza, A. Debayle, T. Johzaki, W. B. Mori, P. K. Patel, Y. Sentoku, and L. O. Silva. "Laser–plasma interactions for fast ignition." Nuclear Fusion 54, no. 5 (April 17, 2014): 054002. http://dx.doi.org/10.1088/0029-5515/54/5/054002.

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Dissertations / Theses on the topic "Laser-plasma interactions"

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Rae, Stuart Campbell. "Short-pulse laser-plasma interactions." Thesis, University of Oxford, 1991. http://ora.ox.ac.uk/objects/uuid:c429d2ee-64d4-415a-b799-f5436d19ccc9.

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This thesis deals with several theoretical aspects of the interaction of an intense femtosecond laser pulse with a plasma. A mechanism for the enhancement of the collisional absorption of light at high intensities is described, involving the direct excitation of collective modes of the plasma, and the importance of this mechanism for a solid-density laser-produced plasma is studied under a range of conditions. An intensity-dependent collision rate is used in a numerical calculation of the reflectivity of a steep-gradient plasma, such as might be produced by an intense femtosecond laser pulse, and the conditions required to maximize absorption at high intensities are determined. The relative contributions of field-induced ionization and collisional ionization in laser-produced plasmas are studied, and it is shown that the behaviour of a gaseous plasma is almost solely governed by the field-induced process. A model is developed to simulate the propagation of an intense femtosecond laser pulse through an initially neutral gas, and this model is used to make predictions about spectral modifications to the laser pulse. Under certain conditions the spectrum is significantly broadened and suffers an overall blue shift. Quantitative fitting of theoretical spectra to experimental results in the literature is attempted, but is complicated by associated defocusing effects in the plasma. Field-induced ionization can produce a gaseous plasma which is significantly colder, for the same degree of ionization, than a plasma produced by collisional ionization. One possible application for a cold highly-ionized plasma is in a recombination x-ray laser, and the propagation model allows the calculation of the plasma temperature, which is a crucial parameter in assessing the feasibility of such schemes.
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Blackburn, Thomas George. "QED effects in laser-plasma interactions." Thesis, University of Oxford, 2015. http://ora.ox.ac.uk/objects/uuid:d026b091-f278-4fbe-b27e-bd6af4a91b7a.

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It is possible to reach the radiation-reaction–dominated regime in today’s high-intensity laser facilities, using the collision of a wakefield-accelerated GeV electron beam with a 30 fs laser pulse of intensity 1022 Wcm-2. This would demonstrate that the yield of high energy gamma rays is increased by the stochastic nature of photon emission: a beam of 109 electrons will emit 6300 photons with energy > 700 MeV, 60 times the number predicted classically. Detecting those photons, or a prominent low energy peak in the electron beam's post-collision energy spectrum, will provide strong evidence of quantum radiation reaction; we place constraints on the accuracy of timing necessary to achieve this. This experiment would provide benchmarking for the simulations that will be used to study the plasmas produced in the next generation of laser facilities. With focused intensities > 1023 Wcm-2, these will be powerful enough to generate high fluxes of gamma rays and electron-positron pairs from laser–laser and laser–solid interactions. It will become possible to test the physics of exotic astrophysical phenomena, such as pair cascades in pulsar magnetospheres, and explore fundamental aspects of quantum electrodynamics (QED). To that end we will discuss: classical theories of radiation reaction; QED processes in intense fields; and a Monte Carlo algorithm by which the latter may be included in particle-in-cell codes. The feedback between QED processes and classical plasma dynamics characterises a new regime we call QED-plasma physics.
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Neil, Alastair John. "Quasilinear theory of laser-plasma interactions." W&M ScholarWorks, 1992. https://scholarworks.wm.edu/etd/1539623827.

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The interaction of a high intensity laser beam with a plasma is generally susceptible to the filamentation instability due to nonuniformities in the laser profile. In ponderomotive filamentation high intensity spots in the beam expell plasma by ponderomotive force, lowering the local density, causing even more light to be focused into the already high intensity region. The result--the beam is broken up into a filamentary structure.;Several optical smoothing techniques have been proposed to eliminate this problem. In the Random Phase Plates (RPS) approach, the beam is split into a very fine scale, time-stationary interference pattern. The irregularities in this pattern are small enough that thermal diffusion is then responsible for smoothing the illumination. In the Induced Spatial Incoherence (ISI) approach the beam is broken up into a larger scale but non-time-stationary interference pattern. In this dissertation we propose that the photons in an ISI beam resonantly interact with the sound waves in the wake of the beam. Such a resonant interaction induces diffusion in the velocity space of the photons. The diffusion will tend to spread the distribution of photons, thus if the diffusion time is much shorter than the e-folding time of the filamentation instability, the instability will be suppressed.;Using a wave-kinetic description of laser-plasma interactions we have applied quasilinear theory to model the resonant interaction of the photons in an ISI beam with the beam's wake field. We have derived an analytic expression for the transverse diffusion coefficient. The quasilinear hypothesis was tested numerically and shown to yield an underestimate of the diffusion rate. By comparing the quasilinear diffusion rate, {dollar}\gamma\sb{lcub}D{rcub}{dollar}, with the maximum growth rate for the ponderomotive filamentation of a uniform beam, {dollar}\gamma\sb{lcub}f\sb{lcub}max{rcub}{rcub}{dollar}, we have derived a worst case criterion for stability against ponderomotive filamentation: {dollar}{dollar}{lcub}\gamma\sb{lcub}f\sb{lcub}max{rcub}{rcub}\over \gamma\sb D{rcub} \sim .5 {lcub}\tilde f\sp5/\tilde D\sp5\over \vert \tilde E\vert\sp2 \tilde\omega\sbsp{lcub}0{rcub}{lcub}2{rcub}\tilde N\sp6{rcub}\ll 1.{dollar}{dollar}The tildaed quantities are scaled to the following fusion relevant reference values; laser intensity: {dollar}\vert E\vert\sp2{dollar} = 10{dollar}\sp{lcub}15{rcub}\vert\tilde E\vert{dollar} Watts cm,{dollar}\sp{lcub}-2{rcub}{dollar} focal length: {dollar}f = 30\tilde f{dollar}m, width of each ISI echelon: {dollar}D = .75\tilde D{dollar} cm, laser carrier frequency: {dollar}\omega\sb{lcub}0{rcub} = 7.5 \times 10\sp{lcub}15{rcub}\tilde\omega\sb0{dollar} s{dollar}\sp{lcub}-1{rcub}{dollar}, and the number of ISI echelons: {dollar}N = 20\tilde N{dollar}.
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Kingham, Robert Joseph. "High intensity short-pulse laser-plasma interactions." Thesis, Imperial College London, 1996. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.267882.

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Streeter, Matthew. "Ultrafast dynamics of relativistic laser plasma interactions." Thesis, Imperial College London, 2013. http://hdl.handle.net/10044/1/24854.

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This thesis documents the experimental and theoretical investigation of laser pulse evolution in relativistic laser-plasma interactions for plasma-wakefield acceleration and ion acceleration experiments. Power amplification of the Astra Gemini laser in a plasma was observed, with the compression of an initially 55 fs, 180 TW pulse down to 14 fs, with a peak power of 320 TW. This was achieved in a laser-driven plasma wakefield operating just below the self-injection threshold density for a propagation distance of 15 mm. Self-guiding of the laser pulse was observed, while pulse depletion was characterised as a function of density and propagation distance, showing that the pulse evolution scales equally with both. These measurements displayed good agreement with a depletion model based on pulse front etching. Particle-in-cell simulations were seen to closely reproduce the experimental results, which were concluded to be predominantly dependent on the longitudinal properties of the laser and wakefield. The simulations also revealed a new wakefield instability that is driven by the far red-shifted component of the laser pulse. In the case of high-contrast solid-density interactions, oscillations of the front surface of the plasma were seen to result in the generation of the second harmonic of the driving laser for a p-polarised interaction. Conversion efficiencies of 22% into the second harmonic were measured, while the total plasma reflectivity into the first and second harmonics remained relatively constant at 65% over the intensity range of 1E17 - 1E21 W/cm2. For normal incidence interactions with sub-micron thickness foils, the cycle-averaged surface motion was measured using a FROG diagnostic. Targets of a few nanometers in thickness underwent an acceleration away from the laser, but the measured surface velocities did not match the expected hole-boring velocities or the measured ion energies, due to the thermal expansion of the plasma. 2D simulations revealed that studying target motion in this way is affected by the scale length of the plasma and photon acceleration that can occur in the tenuous plasma in front of the laser-reflecting surface.
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Quinn, Kevin Edward. "Plasma dynamics following ultraintense laser-solid interactions." Thesis, Queen's University Belfast, 2010. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.527919.

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Tubman, Eleanor. "Magnetic field generation in laser-plasma interactions." Thesis, University of York, 2016. http://etheses.whiterose.ac.uk/16757/.

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The primary focus of this thesis is understanding the production of magnetic fields during laser-plasma experiments. Each chapter investigates a different mechanism of producing magnetic fields. The first is from the by-product of launching asymmetric shocks which drive Biermann battery generated magnetic fields. The second looks at the reconnection of magnetic fields between two laser focal spots and the third is from fields produced around a current carrying loop target. Blast waves are investigated in the laboratory using a fast framing camera to capture multiple images on a single shot. In analysing the images, the blast wave's trajectory is compared to a Sedov-Taylor solution and the coupling of the laser energy into the shock wave is calculated to be 0.5-2%. The evolution of the blast wave's shape is characterised by fitting an ellipse to the outer edge and is observed to progress into a more symmetrical shape. Calculations show that two shocks produced in the interaction cause the change in ellipticity. We experimentally demonstrate that when two laser spots are placed in close proximity reconnection occurs. Diagnostics, including proton radiography, X-ray detectors and an optical probe, record and diagnose the existence of a semi-collisional reconnection event. The experimental data and simulations show that both Nernst and anisotropic pressure effects need to be taken into account for understanding and predicting the correct plasma dynamics observed. Magnetic fields are produced by driving a current through a loop attached to two plates and new measurements recording the voltages induced are presented in this thesis. It is found that the predicted values for the resistance, capacitance and inductance do not match those extracted from the experimental data and reasons for these are presented. Ideas for furthering this research to enhance our understanding in this area are given.
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Johnson, David A. "Some aspects of nonlinear laser plasma interactions." Thesis, University of St Andrews, 1995. http://hdl.handle.net/10023/14318.

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Recent advances in the development of high power short pulse laser systems has opened a new regime of laser plasma interactions for study. The thesis is presented in two parts. In Part I, we consider the implications of these high power laser pulses for the interaction with a uniform underdense plasma, with particular regard to plasma-based accelerators. We present a scheme for the resonant excitation of large electrostatic Wakefields in these plasmas using a train of ultra-intense laser pulses. We also present an analysis of the resonant mechanism of this excitation based on consideration of phase space trajectories. In Part II, we consider the transition from linear Resonance Absorption to nonlinear absorption processes in a linear electron density profile as the intensity of the incident radiation increases and the scale length of the density profile decreases. We find that the electron motion excited by an electrostatic field exhibits some extremely complicated dynamics with bifurcations to period doubling and chaotic motion as the strength of the driving field is increased or the density scale length is decreased. We also present some results obtained from particle simulations of these interactions.
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Watts, Ian Frank. "Intense laser-plasma interactions : harmonics and other phenomena." Thesis, Imperial College London, 2001. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.271186.

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Ramsay, Martin. "Short-pulse laser interactions with high density plasma." Thesis, University of Warwick, 2015. http://wrap.warwick.ac.uk/77583/.

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The constraints on particle-in-cell (PIC) simulations of short-pulse laser interactions with solid density targets severely limit the spatial and temporal scales which can be modelled routinely. Although recent advances in high performance computing (HPC) capabilities have rendered collisionless simulations at a scale and density directly applicable to experiments tractable, detailed modelling of the fast electron transport resulting from the laser interaction is often only possible by sampling the fast electron populations and passing this information to a separate, dedicated transport code. However, this approach potentially neglects phenomena which take place or are seeded near the transition between the two codes. Consequently there is a need to develop techniques capable of efficiently modelling fast electron transport in high density plasma without being subject to the usual grid-scale and time-step constraints. The approach employed must also be compatible with retaining the standard PIC model in the laser interaction regions in order to model laser absorption and charged particle acceleration processes. Such an approach, proposed by Cohen, Kemp and Divol [J. Comput. Phys., 229:4591, 2010], has been identified, adapted and implemented in EPOCH. The final algorithm, as implemented, is presented here. To demonstrate the ability of the adapted code to model high intensity laser-plasma interactions with peak densities at, and above, solid density, the results of simulations investigating filamentation of the fast electron population and heating of the bulk target, at high densities, are presented and compared with the results of recent experiments as well as other, similar codes.
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Books on the topic "Laser-plasma interactions"

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Scottish Universities Summer School in Physics (60th 2005 St Andrews, Scotland). Laser-plasma interactions. Edited by Jaroszynski Dino A, Bingham R, and Cairns R. A. Boca Raton: Taylor & Francis, 2009.

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Scottish Universities Summer School in Physics (60th 2005 St. Andrews, Scotland). Laser-plasma interactions. Edited by Jaroszynski Dino A, Bingham R. A, and Cairns R. A. Boca Raton: Taylor & Francis, 2009.

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A, Jaroszynski Dino, Bingham R. A, and Cairns R. A, eds. Laser-plasma interactions. Boca Raton: Taylor & Francis, 2009.

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McKenna, Paul, David Neely, Robert Bingham, and Dino Jaroszynski, eds. Laser-Plasma Interactions and Applications. Heidelberg: Springer International Publishing, 2013. http://dx.doi.org/10.1007/978-3-319-00038-1.

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Shalom, Eliezer, and Mima Kunioki, eds. Applications of laser plasma interactions. Boca Raton: Taylor & Francis, 2009.

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Michel, Pierre. Introduction to Laser-Plasma Interactions. Cham: Springer International Publishing, 2023. http://dx.doi.org/10.1007/978-3-031-23424-8.

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M, Rubenchik A., and Witkowski S, eds. Physics of laser plasma. Amsterdam: North-Holland, 1991.

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Hora, Heinrich. Laser plasma physics: Forces and the nonlinearity principle. Bellingham, Washington: SPIE, 2014.

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Japan-U, S. Seminar on Physics of High Power Laser Matter Interactions (1992 Kyoto Japan). Japan-U.S. Seminar on Physics of High Power Laser Matter Interactions, Kyoto, Japan, 9-13 March 1992. Singapore: World Scientific, 1992.

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M, Kovrizhnykh L., ed. Generat͡s︡ii͡a︡ nelineĭnykh voln i kvazistat͡s︡ionarnykh tokov v plazme: Sbornik nauchnykh trudov. Moskva: "Nauka", 1988.

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Book chapters on the topic "Laser-plasma interactions"

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Mihailescu, Ion N., and Jörg Hermann. "Laser–Plasma Interactions." In Laser Processing of Materials, 49–88. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-13281-0_4.

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Malka, Victor. "Laser Plasma Accelerators." In Laser-Plasma Interactions and Applications, 281–301. Heidelberg: Springer International Publishing, 2013. http://dx.doi.org/10.1007/978-3-319-00038-1_11.

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Kruer, William L. "Laser Plasma Experiments." In The Physics Of Laser Plasma Interactions, 153–78. Boca Raton: CRC Press, 2019. http://dx.doi.org/10.1201/9781003003243-13.

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Takabe, Hideaki. "Relativistic Laser Plasma Interactions." In Springer Series in Plasma Science and Technology, 203–38. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-49613-5_6.

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Kono, Mitsuo, and Miloš M. Škorić. "Relativistic Laser Plasma Interactions." In Nonlinear Physics of Plasmas, 415–77. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-14694-7_13.

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Neely, David, and Tim Goldsack. "Diagnostics of Laser-Plasma Interactions." In Laser-Plasma Interactions and Applications, 409–30. Heidelberg: Springer International Publishing, 2013. http://dx.doi.org/10.1007/978-3-319-00038-1_16.

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Silva, Luis O., and Robert Bingham. "Theory of Underdense Laser-Plasma Interactions with Photon Kinetic Theory." In Laser-Plasma Interactions and Applications, 3–18. Heidelberg: Springer International Publishing, 2013. http://dx.doi.org/10.1007/978-3-319-00038-1_1.

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Atzeni, Stefano. "Inertial Confinement Fusion with Advanced Ignition Schemes: Fast Ignition and Shock Ignition." In Laser-Plasma Interactions and Applications, 243–77. Heidelberg: Springer International Publishing, 2013. http://dx.doi.org/10.1007/978-3-319-00038-1_10.

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Roth, Markus, and Marius Schollmeier. "Ion Acceleration: TNSA." In Laser-Plasma Interactions and Applications, 303–50. Heidelberg: Springer International Publishing, 2013. http://dx.doi.org/10.1007/978-3-319-00038-1_12.

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Zepf, Matt. "Coherent Light Sources in the Extreme Ultraviolet, Frequency Combs and Attosecond Pulses." In Laser-Plasma Interactions and Applications, 351–73. Heidelberg: Springer International Publishing, 2013. http://dx.doi.org/10.1007/978-3-319-00038-1_13.

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Conference papers on the topic "Laser-plasma interactions"

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Škorić, Miloš M., Bengt Eliasson, and Padma K. Shukla. "Relativistic Laser-Plasma Interactions." In NEW DEVELOPMENTS IN NONLINEAR PLASMA PHYSICS: Proceedings of the 2009 ICTP Summer College on Plasma Physics and International Symposium on Cutting Edge Plasma Physics. AIP, 2009. http://dx.doi.org/10.1063/1.3266794.

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Schaaf, Peter. "Laser Plasma Material Interactions." In THE PHYSICS OF IONIZED GASES: 22nd Summer School and International Symposium on the Physics of Ionized Gases; Invited Lectures, Topical Invited Lectures and Progress Reports. AIP, 2004. http://dx.doi.org/10.1063/1.1843502.

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Kruer, W. L. "Long Pulse Laser-Plasma Interactions." In 1988 Los Angeles Symposium--O-E/LASE '88, edited by Hector A. Baldis and E. M. Campbell. SPIE, 1988. http://dx.doi.org/10.1117/12.965116.

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Bin, Ouyang, Zhizhan Xu, Li-Huang Lin, Shisheng Cheng, Haihe Lu, Pinzhong Fan, Yaolin Li, et al. "Intense laser source for X-ray laser research and laser-plasma study." In Laser-Plasma Interactions: the International Symposium, edited by ZhiJiang Wang and Zhizhan Xu. SPIE, 1993. http://dx.doi.org/10.1117/12.155764.

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Mason, R. J., R. A. Kopp, H. X. Vu, D. C. Wilson, S. R. Goldman, R. G. Watt, and O. Willi. "Foam-buffered laser-matter interactions." In LASER INTERACTION AND RELATED PLASMA PHENOMENA. ASCE, 1997. http://dx.doi.org/10.1063/1.53531.

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"Session: laser-plasma interactions and plasma diagnostics. II." In IEEE 1988 International Conference on Plasma Science. IEEE, 1988. http://dx.doi.org/10.1109/plasma.1988.132286.

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Witkowski, Siegbert. "X rays from laser-produced plasma." In Laser-Plasma Interactions: the International Symposium, edited by ZhiJiang Wang and Zhizhan Xu. SPIE, 1993. http://dx.doi.org/10.1117/12.155771.

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Nikolić, Lj. "Simulations of Relativistic Laser-Plasma Interactions." In THE PHYSICS OF IONIZED GASES: 22nd Summer School and International Symposium on the Physics of Ionized Gases; Invited Lectures, Topical Invited Lectures and Progress Reports. AIP, 2004. http://dx.doi.org/10.1063/1.1843531.

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Newberger, Barry S. "Laser plasma interactions and particle acceleration." In The Physics of Particle Accelerators Vol. I (based on the US Particle Accelerator School (USPAS) Seminars and Courses). AIP, 1992. http://dx.doi.org/10.1063/1.41996.

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Walsh, C. A., P. T. Campbell, B. Russell, L. Willingale, E. Tubman, and M. Sherlock. "Magnetic Fields in Laser-Plasma Interactions." In 2022 IEEE International Conference on Plasma Science (ICOPS). IEEE, 2022. http://dx.doi.org/10.1109/icops45751.2022.9813000.

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Reports on the topic "Laser-plasma interactions"

1

Baldis, H. Laser-Plasma Interactions in High-Energy-Density Plasmas. Office of Scientific and Technical Information (OSTI), October 2006. http://dx.doi.org/10.2172/900158.

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2

Turner, R. E., L. V. Powers, and R. L. Berger. Laser-plasma interactions in large gas-filled hohlraums. Office of Scientific and Technical Information (OSTI), June 1996. http://dx.doi.org/10.2172/376944.

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Wharton, K. B. Laser-plasma interactions relevant to Inertial Confinement Fusion. Office of Scientific and Technical Information (OSTI), November 1998. http://dx.doi.org/10.2172/12528.

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4

MacGowan, B., R. Berger, and J. Fernandez. Laser-plasma interactions in NIF-scale plasmas (HLP5 and HLP6). Office of Scientific and Technical Information (OSTI), June 1996. http://dx.doi.org/10.2172/376965.

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Mackinnon, A., P. Patel, R. Town, S. Hatchett, D. Hicks, T. Phillips, S. Wilks, et al. Proton Radiography of Laser-Plasma Interactions with Picosecond Time Resolution. Office of Scientific and Technical Information (OSTI), February 2005. http://dx.doi.org/10.2172/917505.

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Yin, Lin, Scott Vernon Luedtke, David James Stark, Robert Francis Bird, William David Nystrom, Brian James Albright, and Bjorn Manuel Hegelich. Simulating High Intensity Laser-Plasma Interactions Including Models of Quantum Radiation. Office of Scientific and Technical Information (OSTI), March 2019. http://dx.doi.org/10.2172/1498014.

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Beg, Farhat. HOT ELECTRON SCALING AND ENERGY COUPLING IN NONLINEAR LASER PLASMA INTERACTIONS. Office of Scientific and Technical Information (OSTI), January 2020. http://dx.doi.org/10.2172/1581765.

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B. H. FAILOR, J. C. FERNANDEZ, and ET AL. HOT, DENSE, MILLIMETER-SCALE, HIGH-Z PLASMAS FOR LASER-PLASMA INTERACTIONS STUDIES. Office of Scientific and Technical Information (OSTI), August 2000. http://dx.doi.org/10.2172/764191.

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Weichman, Kathleen, and Alexey Arefiev. Effects of a strong applied magnetic field on relativistic laser-plasma interactions. Office of Scientific and Technical Information (OSTI), June 2023. http://dx.doi.org/10.2172/1976086.

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Kemp, Gregory Elijah. Specular Reflectivity and Hot-Electron Generation in High-Contrast Relativistic Laser-Plasma Interactions. Office of Scientific and Technical Information (OSTI), January 2013. http://dx.doi.org/10.2172/1092502.

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