Results 21 to 30 of about 319,492 (291)

Traveling mirror compressor delay line with nonconstant capacitance [PDF]

, 1981
The scaling relations for a traveling mirror magnetic compressor [P.M. Bellan, Phys. Rev. Lett. 43, 858 (1979)] having nonconstant capacitance are derived.
Bellan, P. M.
core   +1 more source

Apparent stress-strain relationships in experimental equipment where magnetorheological fluids operate under compression mode [PDF]

, 2008
: This paper presents an experimental investigation of two different magnetorheological ( MR) fluids, namely, water-based and hydrocarbon-based MR fluids in compression mode under various applied currents.
A G Olabi, Carmignani C, Forte P, Genc S, Hagenbuchle M, Kraus J D, Mazlan S A, Monkman G J, N B Ekreem, S A Mazlan   +9 more
core   +1 more source

The Compression of the Heliospheric Magnetic Structure by Interplanetary Shocks: Is the Structure at 1AU a Manifestation of Solar-Wind Turbulence or Is It Fossil Structure From the Sun?

Frontiers in Astronomy and Space Sciences, 2020
As a test of the action of MHD turbulence in the solar wind, the compression of the heliospheric magnetic structure at 1AU by 109 interplanetary shocks is examined.
Joseph E. Borovsky
doaj   +1 more source

All-optical three-dimensional electron pulse compression [PDF]

, 2014
We propose an all-optical, three-dimensional electron pulse compression scheme in which Hermite-Gaussian optical modes are used to fashion a three-dimensional optical trap in the electron pulse's rest frame.
Boot, Hilbert, Sciaini, Weninger, Zewail, Zhu   +5 more
core   +2 more sources

Plasma-Based Accelerator with Magnetic Compression

Physical Review Letters, 2012
Electron dephasing is a major gain-inhibiting effect in plasma-based accelerators. A novel method is proposed to overcome dephasing, in which the modulation of a modest [~O(10 kG)], axial, uniform magnetic field in the acceleration channel leads to densification of the plasma through magnetic compression, enabling direct, time-resolved control of the ...
P F, Schmit, N J, Fisch
openaire   +3 more sources

Magnetic levitation and compression of compact tori [PDF]

Physics of Plasmas, 2020
The magnetic compression experiment at General Fusion was a repetitive non-destructive test to study plasma physics to magnetic target fusion compression. A compact torus (CT) is formed with a co-axial gun into a containment region with an hour-glass shaped inner flux conserver and an insulating outer wall.
Dunlea, Carl, Howard, Stephen, Zawalski, Wade, Epp, Kelly, Mossman, Alex, Team, General Fusion, Xiao, Chijin, Hirose, Akira   +7 more
openaire   +2 more sources

Ion dynamics during compression of Mercury's magnetosphere [PDF]

Annales Geophysicae, 2010
Because of the small planetary magnetic field as well as proximity to the Sun that leads to enhanced solar wind pressure as compared to Earth, the magnetosphere of Mercury is very dynamical and at times subjected to prominent compression.
D. C. Delcourt, T. E. Moore, M.-C. H. Fok   +2 more
doaj   +1 more source

Magnetic Field Amplification in Galaxy Clusters and its Simulation [PDF]

, 2018
We review the present theoretical and numerical understanding of magnetic field amplification in cosmic large-scale structure, on length scales of galaxy clusters and beyond.
A. Bauer, A. Beresnyak, A. Beresnyak, A. Bonafede, A. Bonafede, A. Bonafede, A. Bonafede, A. Brandenburg, A. Brandenburg, A. Dedner, A. Finoguenov, A. Kolmogorov, A. Lazarian, A. Lazarian, A. Maier, A. Marcowith, A. Neronov, A. Ruzmaikin, A. Schekochihin, A. Schekochihin, A. Stroe, A. Stroe, A. Vikhlinin, A. Vladimirov, A.A. Schekochihin, A.A. Schekochihin, A.A. Schekochihin, A.A. Schekochihin, A.A. Schekochihin, A.A. Schekochihin, A.A. Vikhlinin, A.D. Chernin, A.E. Broderick, A.E. Evrard, A.G. Kritsuk, A.M. Beck, A.M. Beck, A.M. Beck, A.M. Beck, A.M. Bykov, A.M. Bykov, A.M. Bykov, A.N. Kolmogorov, A.P. Kazantsev, A.R. Bell, B. Dennison, B. Reville, B. Reville, B.E. Robertson, B.M. Gaensler, C. Caprini, C. Federrath, C. Federrath, C. Federrath, C. Federrath, C. Ferrari, C. Gheller, C. Pfrommer, C. Pfrommer, C. Pfrommer, C. Vogt, C.L. Dobbs, C.L. Sarazin, C.L. Sarazin, C.L. Sarazin, D. Caprioli, D. Caprioli, D. Caprioli, D. Lee, D. Nagai, D. Ryu, D. Ryu, D. Ryu, D. Wittor, D. Wittor, D.H. Porter, D.J. Price, D.J. Price, D.N. Hoang, D.R.G. Schleicher, D.R.G. Schleicher, D.S. Balsara, D.S. Young De, E. Churazov, E. Parizot, E. Roediger, E. Roediger, E. Zinger, E.R. Harrison, E.T. Lau, F. Aharonian, F. Fraschetti, F. Govoni, F. Govoni, F. Guo, F. Guo, F. Marinacci, F. Marinacci, F. Marinacci, F. Miniati, F. Miniati, F. Miniati, F. Miniati, F. Miniati, F. Mogavero, F. Rincon, F. Vazza, F. Vazza, F. Vazza, F. Vazza, F. Vazza, F. Vazza, F. Vazza, F. Vazza, F. Zandanel, F.A. Stasyszyn, F.J. Sánchez-Salcedo, F.N. Owen, G. Brunetti, G. Brunetti, G. Brunetti, G. Brunetti, G. Brunetti, G. Brunetti, G.K. Batchelor, G.M. Voit, G.R. Burbidge, H. Alfvén, H. Böhringer, H. Chen, H. Kang, H. Xu, H. Xu, H.J. Völk, I. Butsky, I. Zhuravleva, I.B. Zeldovich, J. Binney, J. Cho, J. Donnert, J. Donnert, J. Donnert, J. Donnert, J. Giacalone, J. Meinecke, J. Roland, J. Schober, J. Wiener, J. Wiener, J. ZuHone, J.A. Zuhone, J.A. ZuHone, J.A. ZuHone, J.A. ZuHone, J.A. ZuHone, J.D. Barrow, J.M. Burgers, J.M.F. Donnert, J.M.F. Donnert, J.O. Burns, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Dolag, K. Nakazawa, K. Nelson, K. Rajpurohit, K. Roettiger, K. Roettiger, K. Roettiger, K. Subramanian, K. Subramanian, K. Waagan, L. Biermann, L. Campanelli, L. Iapichino, L. Iapichino, L. Iapichino, L. Spitzer, L.D. Landau, L.D. Shaw, L.J. Dursi, L.J. Dursi, L.M. Widrow, L.O. Drury, M. Ackermann, M. Brüggen, M. Brüggen, M. Brüggen, M. Brüggen, M. Brüggen, M. Gaspari, M. Gendron-Marsolais, M. Langer, M. Lyutikov, M. Markevitch, M. Rieder, M. Ruszkowski, M. Ruszkowski, M. Takizawa, M.A. Latif, M.A. Malkov, M.A. Riquelme, M.A. Riquelme, M.A.G. Willson, M.S. Turner, M.W. Kunz, M.W. Kunz, N. Asai, N. Asai, N. Asai, N. Battaglia, N. Werner, N.E.L. Haugen, N.E.L. Haugen, N.L. Mitchell, O. Goldshmidt, P. Goldreich, P. Kuchar, P. Mazzotta, P. Schuecker, P. Slane, P. Trivedi, P.A. Thomas, P.A.R. Ade, P.F. Hopkins, P.F. Hopkins, P.M. Ricker, P.P. Kronberg, R. Beck, R. Durrer, R. Khatri, R. Pakmor, R. Pakmor, R. Santos-Lima, R. Santos-Lima, R. Schlickeiser, R. Taylor, R. Valdarnini, R.A. Laing, R.H. Kraichnan, R.M. Kulsrud, R.M. Kulsrud, R.M. Kulsrud, R.P. Kraft, S. Bertone, S. Borgani, S. Giacintucci, S. Giacintucci, S. Giacintucci, S. Jacob, S. Jacob, S. Ji, S. Li, S. Martin-Alvarez, S. Melville, S. Paul, S. Planelles, S. Planelles, S. Schindler, S. Sur, S.A. Walker, S.G. Lucek, S.I. Vaĭnshteĭn, S.P. Reynolds, S.R. Furlanetto, S.W. Skillman, T. Enßlin, T. Inoue, T. Kahniashvili, T. Kahniashvili, T. Kahniashvili, T. Naab, T. Sano, T.A. Enßlin, T.A. Gardiner, T.C. Arlen, T.S. Tricco, T.W. Jones, T.W. Shimwell, U. Keshet, U. Klein, V. Springel, V. Vacca, V. Vacca, V. Yakhot, V.B. Semikoz, V.N. Zirakashvili, W. Chen, W. Dobler, W. Jaffe, W. Schmidt, X. Shi, X. Shi, X. Shi, X.N. Bai, Y. Birnboim, Y. Dubois, Y. Dubois, Y. Ichinohe, Y. Su, Y.B. Zel’dovich   +309 more
core   +3 more sources

Magnetic Field Strength in the Upper Solar Corona Using White-light Shock Structures Surrounding Coronal Mass Ejections

, 2011
To measure the magnetic field strength in the solar corona, we examined 10 fast (> 1000 km/s) limb CMEs which show clear shock structures in SOHO/LASCO images.
Bemporad, Cho, Eselevich, Gopalswamy, Gopalswamy, Gopalswamy, Gopalswamy, Gopalswamy, Hayes, Ingleby, K.-S. Cho, Kozarev, Landau, Lee, Lin, Ma, Maloney, Manchester, Mann, N. Gopalswamy, Ontiveros, R.-S. Kim, Ramesh, S. Yashiro, Seiff, Sheeley, Van de Hulst, Vourlidas, Y.-J. Moon   +28 more
core   +1 more source

Magnetic compression gastrostomy in the rat

Pediatric Surgery International, 2012
Magnetic compression anastomosis is used for gastrointestinal, biliary, and urinary anastomoses. We have developed a simple magnetic compression gastrostomy technique in rats.Animals were randomized into two groups (n = 12 each): magnetic gastrostomy (MG) and surgical gastrostomy (SG) (control).
Uygun, Ibrahim, Okur, Mehmet Hanifi, Cimen, Hasan, Keles, Aysenur, Yalcin, Ozben, Ozturk, Hayrettin, Otcu, Selcuk   +6 more
openaire   +4 more sources