Jafari, M. J. Jafari Milani, M. R. and Niknam, A. R. 2016. Evolution of a Gaussian laser beam in warm collisional magnetoplasma. Physics of Plasmas, Vol. 23, Issue. 7, p. 073119.
Managadze, George G. Engel, Michael H. Getty, Stephanie Wurz, Peter Brinckerhoff, William B. Shokolov, Anatoly G. Sholin, Gennady V. Terent'ev, Sergey A. Chumikov, Alexander E. Skalkin, Alexander S. Blank, Vladimir D. Prokhorov, Vyacheslav M. Managadze, Nina G. and Luchnikov, Konstantin A. 2016. Excess of l-alanine in amino acids synthesized in a plasma torch generated by a hypervelocity meteorite impact reproduced in the laboratory. Planetary and Space Science, Vol. 131, p. 70.
Shi, Yuan Fisch, Nathaniel J. and Qin, Hong 2016. Effective-action approach to wave propagation in scalar QED plasmas. Physical Review A, Vol. 94, Issue. 1,
Xiong, Gang Li, Shuiqing Zhang, Yiyang Buckley, Steven G. and Tse, Stephen D. 2016. Phase-selective laser-induced breakdown spectroscopy of metal-oxide nanoparticle aerosols with secondary resonant excitation during flame synthesis. J. Anal. At. Spectrom., Vol. 31, Issue. 2, p. 482.
Albertazzi, B. d’Humières, E. Lancia, L. Dervieux, V. Antici, P. Böcker, J. Bonlie, J. Breil, J. Cauble, B. Chen, S. N. Feugeas, J. L. Nakatsutsumi, M. Nicolaï, P. Romagnani, L. Shepherd, R. Sentoku, Y. Swantusch, M. Tikhonchuk, V. T. Borghesi, M. Willi, O. Pépin, H. and Fuchs, J. 2015. A compact broadband ion beam focusing device based on laser-driven megagauss thermoelectric magnetic fields. Review of Scientific Instruments, Vol. 86, Issue. 4, p. 043502.
Craxton, R. S. Anderson, K. S. Boehly, T. R. Goncharov, V. N. Harding, D. R. Knauer, J. P. McCrory, R. L. McKenty, P. W. Meyerhofer, D. D. Myatt, J. F. Schmitt, A. J. Sethian, J. D. Short, R. W. Skupsky, S. Theobald, W. Kruer, W. L. Tanaka, K. Betti, R. Collins, T. J. B. Delettrez, J. A. Hu, S. X. Marozas, J. A. Maximov, A. V. Michel, D. T. Radha, P. B. Regan, S. P. Sangster, T. C. Seka, W. Solodov, A. A. Soures, J. M. Stoeckl, C. and Zuegel, J. D. 2015. Direct-drive inertial confinement fusion: A review. Physics of Plasmas, Vol. 22, Issue. 11, p. 110501.
Gao, L. Nilson, P. M. Igumenshchev, I. V. Haines, M. G. Froula, D. H. Betti, R. and Meyerhofer, D. D. 2015. Precision Mapping of Laser-Driven Magnetic Fields and Their Evolution in High-Energy-Density Plasmas. Physical Review Letters, Vol. 114, Issue. 21,
Sharma, R. P. Tiwary, Prem Pyari Modi, K. V. Singh, Ram Kishor Sharma, Swati and Satsangi, V. R. 2015. Spatio-temporal evolution of magnetosonic wave in the laser plasma interaction. Physics of Plasmas, Vol. 22, Issue. 5, p. 052307.
Albertazzi, B. Ciardi, A. Nakatsutsumi, M. Vinci, T. Beard, J. Bonito, R. Billette, J. Borghesi, M. Burkley, Z. Chen, S. N. Cowan, T. E. Herrmannsdorfer, T. Higginson, D. P. Kroll, F. Pikuz, S. A. Naughton, K. Romagnani, L. Riconda, C. Revet, G. Riquier, R. Schlenvoigt, H.- P. Skobelev, I. Y. Faenov, A. Y. Soloviev, A. Huarte-Espinosa, M. Frank, A. Portugall, O. Pepin, H. and Fuchs, J. 2014. Laboratory formation of a scaled protostellar jet by coaligned poloidal magnetic field. Science, Vol. 346, Issue. 6207, p. 325.
Bawa’aneh, M.S. Assayed, Ghada Said, M.R. and Al-Awfi, S. 2014. Convective laser filamentation instability in magnetized plasma. Canadian Journal of Physics, Vol. 92, Issue. 6, p. 504.
Chatterjee, Gourab Singh, Prashant Kumar Adak, Amitava Lad, Amit D. and Kumar, G. Ravindra 2014. High-resolution measurements of the spatial and temporal evolution of megagauss magnetic fields created in intense short-pulse laser-plasma interactions. Review of Scientific Instruments, Vol. 85, Issue. 1, p. 013505.
Davies, A. Haberberger, D. Boni, R. Ivancic, S. Brown, R. and Froula, D. H. 2014. Polarimetry diagnostic on OMEGA EP using a 10-ps, 263-nm probe beam. Review of Scientific Instruments, Vol. 85, Issue. 11, p. 11E611.
Modestov, M. Bychkov, V. Brodin, G. Marklund, M. and Brandenburg, A. 2014. Evolution of the magnetic field generated by the Kelvin-Helmholtz instability. Physics of Plasmas, Vol. 21, Issue. 7, p. 072126.
Modi, K. V. Tiwary, Prem Pyari Singh, Ram Kishor Satsangi, V. R. and Sharma, R. P. 2014. Filamentation of magnetosonic wave and generation of magnetic turbulence in laser plasma interaction. Physics of Plasmas, Vol. 21, Issue. 10, p. 102305.
Bissell, J J Ridgers, C P and Kingham, R J 2013. Super-Gaussian transport theory and the field-generating thermal instability in laser–plasmas. New Journal of Physics, Vol. 15, Issue. 2, p. 025017.
KRASHENINNIKOV, S. I. 2013. On the turbulence-induced seeding of large scale-length magnetic field during the interactions of plasma clouds. Journal of Plasma Physics, Vol. 79, Issue. 06, p. 1011.
Kugland, N. L. Ross, J. S. Chang, P.-Y. Drake, R. P. Fiksel, G. Froula, D. H. Glenzer, S. H. Gregori, G. Grosskopf, M. Huntington, C. Koenig, M. Kuramitsu, Y. Kuranz, C. Levy, M. C. Liang, E. Martinez, D. Meinecke, J. Miniati, F. Morita, T. Pelka, A. Plechaty, C. Presura, R. Ravasio, A. Remington, B. A. Reville, B. Ryutov, D. D. Sakawa, Y. Spitkovsky, A. Takabe, H. and Park, H.-S. 2013. Visualizing electromagnetic fields in laser-produced counter-streaming plasma experiments for collisionless shock laboratory astrophysics. Physics of Plasmas, Vol. 20, Issue. 5, p. 056313.
Maity, Chandan Sarkar, Anwesa Shukla, Padma Kant and Chakrabarti, Nikhil 2013. Wave-Breaking Phenomena in a Relativistic Magnetized Plasma. Physical Review Letters, Vol. 110, Issue. 21,
Mauricio Paulin Fuentes, J Sánchez-Aké, C Bredice, Fausto O and Villagrán-Muniz, Mayo 2013. Dipolar distribution generated by laser-induced plasma (LIP) in air in earliest instants. Journal of Physics D: Applied Physics, Vol. 46, Issue. 49, p. 495202.
Niknam, A. R. Taghadosi, M. R. Majedi, S. and Khorashadizadeh, S. M. 2013. Formation of current filaments and magnetic field generation in a quantum current-carrying plasma. Physics of Plasmas, Vol. 20, Issue. 9, p. 092310.
Large (megagauss) “spontaneous” magnetic fields are produced by laser–plasma interactions when a short, powerful laser pulse is focused to a small diameter onto a solid target. The relevance of these magnetic fields to inertial confinement fusion applications depends on the numerous ways in which they can affect laser–plasma interactions and the resulting plasma. Theoretical studies have dealt with a variety (thermal, radiative, and dynamo) of generation mechanisms and with the associated transport and instability phenomena. The fields, originally observed with small induction probes placed near the target, have been studied in the focal region by optical methods. These optical diagnostics have used Faraday rotation of a probing laser beam and Zeeman profiles of emitted spectral lines.
This list contains references from the content that can be linked to their source. For a full set of references and notes please see the PDF or HTML where available.
Email your librarian or administrator to recommend adding this journal to your organisation's collection.
Full text views reflects the number of PDF downloads, PDFs sent to Google Drive, Dropbox and Kindle and HTML full text views.
Abstract views reflect the number of visits to the article landing page.
* Views captured on Cambridge Core between September 2016 - 23rd May 2017. This data will be updated every 24 hours.