Mietek Lisak mainly focuses on Nonlinear system, Optics, Optical fiber, Plasma and Nonlinear optics. His Nonlinear system study incorporates themes from Wave equation, Pulse, Classical mechanics and Schrödinger equation. His research in Optics intersects with topics in Soliton, Computational physics and Kerr effect.
In his research, Bandwidth, Communications system and Quantum electrodynamics is intimately related to Optical communication, which falls under the overarching field of Optical fiber. Mietek Lisak has included themes like Radiation, Electron, Laser and Atomic physics in his Plasma study. His work deals with themes such as Tokamak and Electric field, which intersect with Atomic physics.
The scientist’s investigation covers issues in Optics, Nonlinear system, Atomic physics, Plasma and Computational physics. His studies in Optical fiber, Pulse, Nonlinear optics, Self-phase modulation and Dispersion are all subfields of Optics research. The various areas that Mietek Lisak examines in his Nonlinear system study include Quantum electrodynamics, Classical mechanics and Schrödinger equation.
His study looks at the relationship between Atomic physics and fields such as Electron, as well as how they intersect with chemical problems. The concepts of his Plasma study are interwoven with issues in Magnetic field and Laser. His Computational physics research incorporates elements of Distribution function and Microwave.
His main research concerns Microwave, Optics, Computational physics, Nonlinear system and Classical mechanics. The Optics study combines topics in areas such as Transmission line, Coaxial waveguides, Radio frequency, Electric power transmission and Computer simulation. His Computational physics study combines topics from a wide range of disciplines, such as Phase space, Plasma, Statistical physics and Electron, Secondary emission.
His Plasma research includes themes of Field and Particle. His work on Soliton as part of his general Nonlinear system study is frequently connected to Bursting, thereby bridging the divide between different branches of science. His studies deal with areas such as Instability, Nonlinear Schrödinger equation, Nonlinear evolution and Multi-mode optical fiber as well as Classical mechanics.
Optics, Electric field, Electron, Computational physics and Mechanics are his primary areas of study. Mietek Lisak interconnects Soliton and Radio frequency in the investigation of issues within Optics. His research integrates issues of Field, Microwave and Electronics in his study of Electric field.
His Electron research integrates issues from Numerical analysis and Avalanche breakdown. His Computational physics study combines topics in areas such as Particle, Plasma, Fusion plasma, Magnetic field and Nuclear magnetic resonance. His Nonlinear system study is concerned with Quantum mechanics in general.
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Nonlinear asymmetric self-phase modulation and self-steepening of pulses in long optical waveguides
D. Anderson;M. Lisak.
Physical Review A (1983)
Wave-breaking-free pulses in nonlinear-optical fibers
Dan Anderson;M. Desaix;Magnus Karlsson;M. Lisak.
Journal of The Optical Society of America B-optical Physics (1993)
Wave breaking in nonlinear-optical fibers
Dan Anderson;M. Desaix;M. Lisak;Manuel L. Quiroga-Teixeiro.
Journal of The Optical Society of America B-optical Physics (1992)
Variational approach to collapse of optical pulses
M. Desaix;D. Anderson;M. Lisak.
Journal of The Optical Society of America B-optical Physics (1991)
Spatiotemporal solitons in multidimensional optical media with a quadratic nonlinearity
Boris A. Malomed;P. Drummond;H. He;A. Berntson.
Physical Review E (1997)
Statistical effects in the multistream model for quantum plasmas.
Dan Anderson;Björn Hall;Mietek Lisak;Mattias Marklund.
Physical Review E (2002)
Soliton Perturbations: A Variational Principle for the Soliton Parameters
A Bondeson;M Lisak;D Anderson.
Physica Scripta (1979)
Statistical theory for incoherent light propagation in nonlinear media.
B. Hall;M. Lisak;D. Anderson;R. Fedele.
Physical Review E (2002)
Threshold of induced transparency in the relativistic interaction of an electromagnetic wave with overdense plasmas
F. Cattani;A. Kim;D. Anderson;M. Lisak.
Physical Review E (2000)
Modulational instability of coherent optical-fiber transmission signals
D. Anderson;M. Lisak.
Optics Letters (1984)
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