Publications of M. Lazar

A list of publications authored or co-authored by M. Lazar, derived from the SAO/NASA Astrophysics Data System (ADS). The number in brackets after each title indicates the number of citations that the paper has received.

Orcid ID: 0000-0002-8508-5466

List of publications ordered by citations
Number of papers: 158 (refereed: 149)
No. of citations: 3751
First author papers: 64 (refereed: 57)

2026

  1. Electrostatic Waves in Astrophysical Druyvesteyn Plasmas. I. Langmuir Waves [0]
    Tischmann, Simon, Gaelzer, Rudi, Schröder, Dustin Lee, Lazar, Marian & Fichtner, Horst, ApJ, 997, 212
  2. Regulation of temperature anisotropy for solar wind protons and alpha particles by collisions and instabilities [0]
    Yoon, Peter H., Salem, Chadi S., Lazar, Marian, Martinović, Mihailo M., Klein, Kristopher G., López, Rodrigo A., Shaaban, Shaaban M., Seough, Jungjoon, Huang, Jia, Sarfraz, Muhammad & Poedts, Stefaan, A&A, 705, A14

2025

  1. Characterizing solar wind electrons with the core-strahlo model: WIND-SWE-VEIS observations [1]
    Eyelade, Adetayo V., Zenteno-Quinteros, Bea, Moya, Pablo S., Silva, Javier I., Urra, Benjamin A., Lazar, Marian & Viñas, Adolfo F., A&A, 702, A198
  2. Boltzmann–Poisson Theory of Nonthermal Self-gravitating Gases, Cold Dark Matter, and Solar Atmosphere [2]
    Hau, L.-N., Chang, C.-K., Lazar, M. & Poedts, S., ApJ, 981, 18
  3. Dynamic spectra of solar radio emissions from weak-turbulence simulation [2]
    Lazar, M., Ziebell, L. F., Yoon, P. H., López, R. A. & Poedts, S., A&A, 696, A187
  4. Extended Scenarios for Solar Radio Emissions With Downshifted Electron Beam Plasma Excitations [2]
    Lazar, M., López, R. A., Shaaban, S. M., Poedts, S. & Fichtner, H., Journal of Geophysical Research (Space Physics), 130, e2024JA033597
  5. Temperature anisotropy instabilities of solar wind electrons with regularized kappa-halos resolved with ALPS [5]
    Schröder, D. L., Fichtner, H., Lazar, M., Verscharen, D. & Klein, K. G., Physics of Plasmas, 32, 032109
  6. Heat-flux Instabilities of Regularized Kappa Distributed Strahl Electrons Resolved with ALPS [1]
    Schröder, Dustin L., Lazar, Marian, López, Rodrigo A. & Fichtner, Horst, ApJ, 987, 110
  7. Core-Halo Correlations of Solar Wind Electrons and Temperature Anisotropy Instabilities [1]
    Shaaban, S. M., Kennis, S., Lazar, M., Pierrard, V. & Poedts, S., Journal of Geophysical Research (Space Physics), 130, e2025JA033838
  8. Cumulative Proton Right-handed Instabilities in the Young Solar Wind Observed by PSP [1]
    Shaaban, Shaaban M., Lazar, M., Fichtner, H., López, R. A. & Poedts, S., ApJ, 993, 1

2024

  1. Quantifying the Expanding and Cooling Effects into the Double Adiabatic Evolution of the Solar Wind Through the Expanding Box Model [4]
    Echeverría-Veas, Sebastián, Moya, Pablo S., Lazar, Marian, Poedts, Stefaan & Asenjo, Felipe A., ApJ, 975, 112
  2. Solar wind effect on the multi-fluid plasma expansion in the Venusian upper ionosphere [1]
    Salem, S., Moslem, W. M., Fichtner, H. & Lazar, M., A&A, 685, A152
  3. Numerical simulations of temperature anisotropy instabilities stimulated by suprathermal protons [2]
    Shaaban, S. M., López, R. A., Lazar, M. & Poedts, S., A&A, 691, A86
  4. Decoding the formation of hammerhead ion populations observed by Parker Solar Probe [4]
    Shaaban, Shaaban M., Lazar, M., López, R. A., Yoon, P. H. & Poedts, S., A&A, 692, L6
  5. Boundary of the Distribution of Solar Wind Proton Beta versus Temperature Anisotropy [9]
    Yoon, P. H., Lazar, M., Salem, C., Seough, J., Martinović, M. M., Klein, K. G. & López, R. A., ApJ, 969, 77
  6. Quasi-linear Analysis of Proton-cyclotron Instability [0]
    Yoon, Peter H., López, Rodrigo A., Seough, Jungjoon, Rashid, Muhammad, Salem, Chadi S., Sarfraz, Muhammad, Lazar, Marian & Shaaban, Shaaban M., ApJ, 976, 173
  7. Regulation of Solar Wind Electron Temperature Anisotropy by Collisions and Instabilities [5]
    Yoon, Peter H., Salem, Chadi S., Klein, Kristopher G., Martinović, Mihailo M., López, Rodrigo A., Seough, Jungjoon, Sarfraz, Muhammad, Lazar, Marian & Shaaban, Shaaban M., ApJ, 975, 105

2023

  1. First Principles Description of Plasma Expansion Using the Expanding Box Model [4]
    Echeverría-Veas, Sebastián, Moya, Pablo S., Lazar, Marian & Poedts, Stefaan, Universe, 9, 448
  2. Linear and nonlinear kinetic Alfvén waves at Venus [3]
    Fayad, A. A., Moslem, W. M., Fichtner, H. & Lazar, M., A&A, 675, A192
  3. Generalized Harris Sheet Equilibrium in Regularized Kappa Distributed Plasmas [6]
    Hau, L.-N., Chang, C.-K. & Lazar, M., ApJ, 956, 144
  4. The aperiodic firehose instability of counter-beaming electrons in space plasmas [5]
    Lazar, M., López, R. A., Moya, P. S., Poedts, S. & Shaaban, S. M., A&A, 670, A85
  5. Kappa-Distributed Electrons in Solar Outflows: Beam-Plasma Instabilities and Radio Emissions [6]
    Lazar, M., López, R. A., Poedts, S. & Shaaban, S. M., Solar Physics, 298, 72
  6. Instability of Langmuir-beam waves: Kappa-distributed electrons [13]
    Lazar, M., López, R. A., Poedts, S. & Shaaban, S. M., Physics of Plasmas, 30, 082106
  7. Hybrid Simulation and Quasi-linear Theory of Bi-Kappa Proton Instabilities [13]
    López, R. A., Yoon, P. H., Viñas, A. F. & Lazar, M., ApJ, 954, 191
  8. Interplay between Anisotropy- and Skewness-driven Whistler Instabilities in the Solar Wind under the Core-Strahlo Model [5]
    Zenteno-Quinteros, Bea, Moya, Pablo S., Lazar, Marian, Viñas, Adolfo F. & Poedts, Stefaan, ApJ, 954, 184

2022

  1. Toward a Realistic Evaluation of Transport Coefficients in Non-equilibrium Space Plasmas [7]
    Husidic, Edin, Scherer, Klaus, Lazar, Marian, Fichtner, Horst & Poedts, Stefaan, ApJ, 927, 159
  2. About the effects of solar wind suprathermal electrons on electrostatic waves [9]
    Lazar, M., Shaaban, S. M., López, R. A. & Poedts, S., Astrophysics and Space Science, 367, 104
  3. Temperature anisotropy instabilities stimulated by the solar wind suprathermal populations [23]
    Lazar, Marian, López, R. A., Shaaban, Shaaban Mohammed, Poedts, Stefaan, Yoon, Peter Haesung & Fichtner, Horst, Frontiers in Astronomy and Space Sciences, 8, 249
  4. Mixing the Solar Wind Proton and Electron Scales. Theory and 2D-PIC Simulations of Firehose Instability [11]
    López, R. A., Micera, A., Lazar, M., Poedts, S., Lapenta, G., Zhukov, A. N., Boella, E. & Shaaban, S. M., ApJ, 930, 158
  5. Comparing the Counter-beaming and Temperature Anisotropy Driven Aperiodic Electron Firehose Instabilities in Collisionless Plasma Environments [2]
    Moya, Pablo S., López, Rodrigo A., Lazar, Marian, Poedts, Stefaan & Shaaban, Shaaban M., ApJ, 937, 49
  6. Implications of Kappa Suprathermal Halo of the Solar Wind Electrons [12]
    Pierrard, Viviane, Lazar, Marian & Stverak, Stepan, Frontiers in Astronomy and Space Sciences, 9, 892236
  7. Effect of the solar wind on the nature of arbitrary amplitude ion-acoustic solitary waves in Venus' upper ionosphere [7]
    Salem, S., Fayad, A. A., El-Shafeay, N. A., Sayed, F. S. H., Shihab, M., Fichtner, H., Lazar, M. & Moslem, W. M., MNRAS, 517, 2876
  8. Revisiting Ulysses electron data with a triple fit of velocity distributions [10]
    Scherer, K., Husidic, E., Lazar, M. & Fichtner, H., A&A, 663, A67

2021

  1. On the propagation of electrostatic wave modes in the inhomogeneous ionospheric plasma of Venus [7]
    Fayad, A. A., Elkamash, I. S., Fichtner, H., Lazar, M., El-Labany, S. K. & Moslem, W. M., Physics of Plasmas, 28, 082902
  2. Transport coefficients enhanced by suprathermal particles in nonequilibrium heliospheric plasmas [10]
    Husidic, E., Lazar, M., Fichtner, H., Scherer, K. & Poedts, S., A&A, 654, A99
  3. Toward a general quasi-linear approach for the instabilities of bi-Kappa plasmas. Whistler instability [21]
    Moya, P. S., Lazar, M. & Poedts, S., Plasma Physics and Controlled Fusion, 63, 025011
  4. Generalized anisotropic κ-cookbook: 2D fitting of Ulysses electron data [11]
    Scherer, K., Husidic, E., Lazar, M. & Fichtner, H., MNRAS, 501, 606
  5. On the interplay of solar wind proton and electron instabilities: linear and quasi-linear approaches [7]
    Shaaban, S. M., Lazar, M., López, R. A. & Wimmer-Schweingruber, R. F., MNRAS, 503, 3134
  6. Electromagnetic ion cyclotron instability stimulated by the suprathermal ions in space plasmas: A quasi-linear approach [16]
    Shaaban, S. M., Lazar, M. & Schlickeiser, R., Physics of Plasmas, 28, 022103
  7. A New Low-beta Regime for Unstable Proton Firehose Modes in Bi-kappa-distributed Plasmas [15]
    Shaaban, S. M., Lazar, M., Wimmer-Schweingruber, R. F. & Fichtner, H., ApJ, 918, 37
  8. Proton-Alpha Drift Instability of Electromagnetic Ion-Cyclotron Modes: Quasilinear Development [2]
    Shaaban, Shaaban M., Lazar, Marian, Yoon, Peter H., Poedts, Stefaan & López, Rodrigo A., Physics, 3, 1175

2020

  1. Linear dispersion theory of parallel electromagnetic modes for regularized Kappa-distributions [20]
    Husidic, Edin, Lazar, Marian, Fichtner, Horst, Scherer, Klaus & Astfalk, Patrick, Physics of Plasmas, 27, 042110
  2. Toward a realistic macroscopic parametrization of space plasmas with regularized κ-distributions [29]
    Lazar, M., Scherer, K., Fichtner, H. & Pierrard, V., A&A, 634, A20
  3. Characteristics of solar wind suprathermal halo electrons [25]
    Lazar, M., Pierrard, V., Poedts, S. & Fichtner, H., A&A, 642, A130
  4. Alternative High-plasma Beta Regimes of Electron Heat-flux Instabilities in the Solar Wind [46]
    López, R. A., Lazar, M., Shaaban, S. M., Poedts, S. & Moya, P. S., ApJ, 900, L25
  5. A firehose-like aperiodic instability of counter-beaming electron plasmas [1]
    López, R. A., Lazar, M., Shaaban, S. M., Poedts, S. & Moya, P. S., Plasma Physics and Controlled Fusion, 62, 075006
  6. Particle-in-cell Simulations of the Parallel Proton Firehose Instability Influenced by the Electron Temperature Anisotropy in Solar Wind Conditions [16]
    Micera, A., Boella, E., Zhukov, A. N., Shaaban, S. M., López, R. A., Lazar, M. & Lapenta, G., ApJ, 893, 130
  7. Particle-in-cell Simulation of Whistler Heat-flux Instabilities in the Solar Wind: Heat-flux Regulation and Electron Halo Formation [48]
    Micera, A., Zhukov, A. N., López, R. A., Innocenti, M. E., Lazar, M., Boella, E. & Lapenta, G., ApJ, 903, L23
  8. Solar Wind Plasma Particles Organized by the Flow Speed [11]
    Pierrard, Viviane, Lazar, Marian & Štverák, Stepan, Solar Physics, 295, 151
  9. Electromagnetic instabilities of low-beta alpha/proton beams in space plasmas [2]
    Rehman, M. A., Shaaban, S. M., Yoon, P. H., Lazar, M. & Poedts, S., Astrophysics and Space Science, 365, 107
  10. Ionospheric losses of Venus in the solar wind [18]
    Salem, S., Moslem, W. M., Lazar, M., Sabry, R., Tolba, R. E. & Schlickeiser, R., Advances in Space Research, 65, 129
  11. The κ-cookbook: a novel generalizing approach to unify κ-like distributions for plasma particle modelling [21]
    Scherer, K., Husidic, E., Lazar, M. & Fichtner, H., MNRAS, 497, 1738
  12. Electromagnetic Ion-Ion Instabilities in Space Plasmas: Effects of Suprathermal Populations [17]
    Shaaban, S. M., Lazar, M., López, R. A. & Poedts, S., ApJ, 899, 20
  13. Whistler instabilities from the interplay of electron anisotropies in space plasmas: a quasi-linear approach [16]
    Shaaban, S. M. & Lazar, M., MNRAS, 492, 3529

2019

  1. Whistler instability stimulated by the suprathermal electrons present in space plasmas [28]
    Lazar, M., López, R. A., Shaaban, S. M., Poedts, S. & Fichtner, H., Astrophysics and Space Science, 364, 171
  2. Particle-in-cell Simulations of the Whistler Heat-flux Instability in Solar Wind Conditions [26]
    López, R. A., Shaaban, S. M., Lazar, M., Poedts, S., Yoon, P. H., Micera, A. & Lapenta, G., ApJ, 882, L8
  3. Particle-in-cell Simulations of Firehose Instability Driven by Bi-Kappa Electrons [40]
    López, R. A., Lazar, M., Shaaban, S. M., Poedts, S., Yoon, P. H., Viñas, A. F. & Moya, P. S., ApJ, 873, L20
  4. Ion escape from the upper ionosphere of Titan triggered by the solar wind [3]
    Moslem, W. M., Salem, S., Sabry, R., Lazar, M., Tolba, R. E. & El-Labany, S. K., Astrophysics and Space Science, 364, 142
  5. On the Applicability of κ-distributions [30]
    Scherer, K., Fichtner, H., Fahr, H. J. & Lazar, M., ApJ, 881, 93
  6. Moments of the Anisotropic Regularized κ-distributions [32]
    Scherer, Klaus, Lazar, Marian, Husidic, Edin & Fichtner, Horst, ApJ, 880, 118
  7. Quasilinear approach of the cumulative whistler instability in fast solar wind: Constraints of electron temperature anisotropy [20]
    Shaaban, S. M., Lazar, M., Yoon, P. H. & Poedts, S., A&A, 627, A76
  8. Firehose instabilities triggered by the solar wind suprathermal electrons [40]
    Shaaban, S. M., Lazar, M., López, R. A., Fichtner, H. & Poedts, S., MNRAS, 483, 5642
  9. The Interplay of the Solar Wind Core and Suprathermal Electrons: A Quasilinear Approach for Firehose Instability [23]
    Shaaban, S. M., Lazar, M., Yoon, P. H. & Poedts, S., ApJ, 871, 237
  10. Quasi-linear approach of the whistler heat-flux instability in the solar wind [30]
    Shaaban, S. M., Lazar, M., Yoon, P. H., Poedts, S. & López, R. A., MNRAS, 486, 4498

2018

  1. Quasi-electrostatic twisted waves in Lorentzian dusty plasmas [6]
    Arshad, Kashif, Lazar, M. & Poedts, S., Planetary and Space Science, 156, 139
  2. Entropy of plasmas described with regularized κ distributions [23]
    Fichtner, H., Scherer, K., Lazar, M., Fahr, H. J. & Vörös, Z., Physical Review E, 98, 053205
  3. Low frequency electromagnetic fluctuations in Kappa magnetized plasmas [11]
    Kim, Sunjung, Lazar, M., Schlickeiser, R., López, R. A. & Yoon, P. H., Plasma Physics and Controlled Fusion, 60, 075010
  4. Temperature anisotropy instabilities stimulated by the interplay of the core and halo electrons in space plasmas [27]
    Lazar, M., Shaaban, S. M., Fichtner, H. & Poedts, S., Physics of Plasmas, 25, 022902
  5. Suprathermal Spontaneous Emissions in κ-distributed Plasmas [14]
    Lazar, M., Kim, S., López, R. A., Yoon, P. H., Schlickeiser, R. & Poedts, S., ApJ, 868, L25
  6. On the effects of suprathermal populations in dusty plasmas: The case of dust-ion-acoustic waves [22]
    Lazar, M., Kourakis, I., Poedts, S. & Fichtner, H., Planetary and Space Science, 156, 130
  7. Electromagnetic Electron Cyclotron Instability in the Solar Wind [35]
    Lazar, M., Yoon, P. H., López, R. A. & Moya, P. S., Journal of Geophysical Research (Space Physics), 123, 6
  8. Uncertainties in the heliosheath ion temperatures [7]
    Scherer, Klaus, Jörg Fahr, Hans, Fichtner, Horst, Sylla, Adama, Richardson, John D. & Lazar, Marian, Annales Geophysicae, 36, 37
  9. Clarifying the solar wind heat flux instabilities [54]
    Shaaban, S. M., Lazar, M. & Poedts, S., MNRAS, 480, 310
  10. Beaming electromagnetic (or heat-flux) instabilities from the interplay with the electron temperature anisotropies [37]
    Shaaban, S. M., Lazar, M., Yoon, P. H. & Poedts, S., Physics of Plasmas, 25, 082105
  11. Stimulated Mirror Instability From the Interplay of Anisotropic Protons and Electrons, and their Suprathermal Populations [19]
    Shaaban, S. M., Lazar, M., Astfalk, P. & Poedts, S., Journal of Geophysical Research (Space Physics), 123, 1754
  12. Solar wind temperature anisotropy constraints from streaming instabilities [7]
    Vafin, S., Lazar, M., Fichtner, H., Schlickeiser, R. & Drillisch, M., A&A, 613, A23
  13. Modified κ-distribution of Solar Wind Electrons and Steady-state Langmuir Turbulence [23]
    Yoon, P. H., Lazar, M., Scherer, K., Fichtner, H. & Schlickeiser, R., ApJ, 868, 131

2017

  1. Kinetic study of electrostatic twisted waves instability in nonthermal dusty plasmas [23]
    Arshad, Kashif, Lazar, M., Mahmood, Shahzad & Aman-ur-Rehman, Poedts, S., Physics of Plasmas, 24, 033701
  2. Cyclotron Electromagnetic Instabilities in a Laboratory Dipole Magnetospheric Plasma with bi-Kappa Distributions [1]
    Grishanov, Nikolay, Azarenkov, Nikolay & Lazar, Marian, Plasma and Fusion Research, 12, 1403047-1403047
  3. Spontaneous emission of electromagnetic fluctuations in Kappa magnetized plasmas [15]
    Kim, Sunjung, Schlickeiser, R., Yoon, P. H., López, R. A. & Lazar, M., Plasma Physics and Controlled Fusion, 59, 125003
  4. Electromagnetic cyclotron instabilities in bi-Kappa distributed plasmas: A quasilinear approach [17]
    Lazar, M., Yoon, P. H. & Eliasson, B., Physics of Plasmas, 24, 042110
  5. Towards realistic characterization of the solar wind suprathermal populations and their effects [6]
    Lazar, M., Physics of Plasmas, 24, 034501
  6. Firehose constraints of the bi-Kappa-distributed electrons: a zero-order approach for the suprathermal electrons in the solar wind [42]
    Lazar, M., Shaaban, S. M., Poedts, S. & Štverák, Š., MNRAS, 464, 564
  7. Dual Maxwellian-Kappa modeling of the solar wind electrons: new clues on the temperature of Kappa populations [71]
    Lazar, M., Pierrard, V., Shaaban, S. M., Fichtner, H. & Poedts, S., A&A, 602, A44
  8. Electron heat flux instability [33]
    Saeed, Sundas, Sarfraz, M., Yoon, P. H., Lazar, M. & Qureshi, M. N. S., MNRAS, 465, 1672
  9. Regularized κ-distributions with non-diverging moments [80]
    Scherer, K., Fichtner, H. & Lazar, M., EPL (Europhysics Letters), 120, 50002
  10. Shaping the solar wind temperature anisotropy by the interplay of electron and proton instabilities [30]
    Shaaban, S. M., Lazar, M., Poedts, S. & Elhanbaly, A., Astrophysics and Space Science, 362, 13

2016

  1. On the interpretation and applicability of κ-distributions [107]
    Lazar, M., Fichtner, H. & Yoon, P. H., A&A, 589, A39
  2. Mixing the Solar Wind Proton and Electron Scales: Effects of Electron Temperature Anisotropy on the Oblique Proton Firehose Instability [19]
    Maneva, Y., Lazar, M., Viñas, A. & Poedts, S., ApJ, 832, 64
  3. The Electron Temperature and Anisotropy in the Solar Wind. Comparison of the Core and Halo Populations [100]
    Pierrard, V., Lazar, M., Poedts, S., Štverák, Š., Maksimovic, M. & Trávníček, P. M., Solar Physics, 291, 2165
  4. Kinetic models for space plasmas: Recent progress for the solar wind and the Earth's magnetosphere [1]
    Pierrard, V., Moschou, S. P., Lazar, M., Borremans, K. & Rosson, G. Lopez, 30th International Symposium on Rarefied Gas Dynamics: Rgd 30, American Institute of Physics Conference Series, 1786, p. 160001
  5. The interplay of the solar wind proton core and halo populations: EMIC instability [29]
    Shaaban, S. M., Lazar, M., Poedts, S. & Elhanbaly, A., Journal of Geophysical Research (Space Physics), 121, 6031
  6. Effects of suprathermal electrons on the proton temperature anisotropy in space plasmas: Electromagnetic ion-cyclotron instability [17]
    Shaaban, S. M., Lazar, M., Poedts, S. & Elhanbaly, A., Astrophysics and Space Science, 361, 193

2015

  1. Nonlinear evolution of the electromagnetic electron-cyclotron instability in bi-Kappa distributed plasma [13]
    Eliasson, B. & Lazar, M., Physics of Plasmas, 22, 062109
  2. Constraints for the aperiodic O-mode streaming instability [4]
    Lazar, M., Schlickeiser, R., Poedts, S., Stockem, A. & Vafin, S., Physics of Plasmas, 22, 012102
  3. Towards realistic parametrization of the kinetic anisotropy and the resulting instabilities in space plasmas. Electromagnetic electron-cyclotron instability in the solar wind [39]
    Lazar, M., Poedts, S., Schlickeiser, R. & Dumitrache, C., MNRAS, 446, 3022
  4. Destabilizing effects of the suprathermal populations in the solar wind [98]
    Lazar, M., Poedts, S. & Fichtner, H., A&A, 582, A124
  5. Effects of Electrons on the Electromagnetic Ion Cyclotron Instability: Solar Wind Implications [27]
    Shaaban, S. M., Lazar, M., Poedts, S. & Elhanbaly, A., ApJ, 814, 34
  6. Quasilinear saturation of the aperiodic ordinary mode streaming instability [13]
    Stockem Novo, A., Yoon, P. H., Lazar, M., Schlickeiser, R., Poedts, S. & Seough, J., Physics of Plasmas, 22, 092301
  7. The instability condition of the aperiodic ordinary mode for new scalings of the counterstreaming parameters [6]
    Vafin, S., Lazar, M. & Schlickeiser, R., Physics of Plasmas, 22, 022129

2014

  1. Solar Wind Electron Strahls Associated with a High-Latitude CME: Ulysses Observations [11]
    Lazar, M., Pomoell, J., Poedts, S., Dumitrache, C. & Popescu, N. A., Solar Physics, 289, 4239
  2. The Electron Firehose and Ordinary-Mode Instabilities in Space Plasmas [30]
    Lazar, M., Poedts, S., Schlickeiser, R. & Ibscher, D., Solar Physics, 289, 369
  3. Instability of the parallel electromagnetic modes in Kappa distributed plasmas - II. Electromagnetic ion-cyclotron modes [35]
    Lazar, M. & Poedts, S., MNRAS, 437, 641
  4. The interplay of Kappa and core populations in the solar wind: Electromagnetic electron cyclotron instability [25]
    Lazar, M., Poedts, S. & Schlickeiser, R., Journal of Geophysical Research (Space Physics), 119, 9395
  5. Effects of Electrons on the Solar Wind Proton Temperature Anisotropy [30]
    Michno, M. J., Lazar, M., Yoon, P. H. & Schlickeiser, R., ApJ, 781, 49

2013

  1. Spontaneous electromagnetic fluctuations in unmagnetized plasmas. II. Relativistic form factors of aperiodic thermal modes [33]
    Felten, T., Schlickeiser, R., Yoon, P. H. & Lazar, M., Physics of Plasmas, 20, 052113
  2. Towards a complete parametrization of the ordinary-mode electromagnetic instability in counterstreaming plasmas. I. Minimizing ion dynamics [20]
    Ibscher, D., Lazar, M., Michno, M. J. & Schlickeiser, R., Physics of Plasmas, 20, 012103
  3. Electromagnetic electron whistler-cyclotron instability in bi-Kappa distributed plasmas [37]
    Lazar, M., Poedts, S. & Michno, M. J., A&A, 554, A64

2012

  1. On the existence of Weibel instability in a magnetized plasma. II. Perpendicular wave propagation: The ordinary mode [26]
    Ibscher, D., Lazar, M. & Schlickeiser, R., Physics of Plasmas, 19, 072116
  2. Suprathermal Particle Populations in the Solar Wind and Corona [10]
    Lazar, M., Schlickeiser, R. & Poedts, S., Exploring the Solar Wind (Editors: Lazar, Marian), p.241
  3. Spontaneous electromagnetic fluctuations in unmagnetized plasmas. III. Generalized Kappa distributions [21]
    Lazar, M., Yoon, P. H. & Schlickeiser, R., Physics of Plasmas, 19, 122108
  4. Modeling Space Plasma Dynamics with Anisotropic Kappa Distributions [31]
    Lazar, M., Pierrard, V., Poedts, S. & Schlickeiser, R., Multi-scale Dynamical Processes in Space and Astrophysical Plasmas (Editors: Leubner, Manfred P. & Vörös, Zoltán), Astrophysics and Space Science Proceedings, 33, p. 97
  5. The electromagnetic ion-cyclotron instability in bi-Kappa distributed plasmas [37]
    Lazar, M., A&A, 547, A94
  6. Exploring the Solar Wind [20]
    Lazar, Marian,

2011

  1. Electron streams formation and secondary two stream instability onset in the post-saturation regime of the classical Weibel instability [12]
    Innocenti, M. E., Lazar, M., Markidis, S., Lapenta, G. & Poedts, S., Physics of Plasmas, 18, 052104
  2. Instability of the parallel electromagnetic modes in Kappa distributed plasmas - I. Electron whistler-cyclotron modes [55]
    Lazar, M., Poedts, S. & Schlickeiser, R., MNRAS, 410, 663
  3. Cosmological magnetic field seeds produced by the Weibel instabilities [0]
    Lazar, M., Schlickeiser, R. & Skoda, T., Astrophysical Dynamics: From Stars to Galaxies (Editors: Brummell, Nicholas H., Brun, A. Sacha, Miesch, Mark S. & Ponty, Yannick), IAU Symposium, 271, p. 387
  4. Proton firehose instability in bi-Kappa distributed plasmas [47]
    Lazar, M., Poedts, S. & Schlickeiser, R., A&A, 534, A116
  5. Evolution of the Electron Distribution Function in the Whistler Wave Turbulence of the Solar Wind [58]
    Pierrard, V., Lazar, M. & Schlickeiser, R., Solar Physics, 269, 421
  6. Modified Temperature-Anisotropy Instability Thresholds in the Solar Wind [24]
    Schlickeiser, R., Michno, M. J., Ibscher, D., Lazar, M. & Skoda, T., Physical Review Letters, 107, 201102
  7. Spontaneously growing, weakly propagating, transverse fluctuations in anisotropic magnetized thermal plasmas [19]
    Schlickeiser, R., Lazar, M. & Skoda, T., Physics of Plasmas, 18, 012103

2010

  1. Is the Weibel instability enhanced by the suprathermal populations or not? [20]
    Lazar, M., Schlickeiser, R. & Poedts, S., Physics of Plasmas, 17, 062112
  2. Counterstreaming magnetized plasmas with kappa distributions - II. Perpendicular wave propagation [22]
    Lazar, M., Tautz, R. C., Schlickeiser, R. & Poedts, S., MNRAS, 401, 362
  3. Resonant Weibel instability in counterstreaming plasmas with temperature anisotropies [10]
    Lazar, M., Dieckmann, M. E. & Poedts, S., Journal of Plasma Physics, 76, 49
  4. Nonresonant electromagnetic instabilities in space plasmas: interplay of Weibel and firehose instabilities [5]
    Lazar, M., Poedts, S. & Schlickeiser, R., Twelfth International Solar Wind Conference (Editors: Maksimovic, M., Issautier, K., Meyer-Vernet, N., Moncuquet, M. & Pantellini, F.), American Institute of Physics Conference Series, 1216, p. 280
  5. Kappa Distributions: Theory and Applications in Space Plasmas [623]
    Pierrard, V. & Lazar, M., Solar Physics, 267, 153
  6. The Influence of Dissipation Range Power Spectra and Plasma-wave Polarization on Cosmic-ray Scattering Mean Free Path [14]
    Schlickeiser, R., Lazar, M. & Vukcevic, M., ApJ, 719, 1497

2009

  1. A comparative study of the filamentation and Weibel instabilities and their cumulative effect. I. Non-relativistic theory [15]
    Lazar, M., Smolyakov, A., Schlickeiser, R. & Shukla, P. K., Journal of Plasma Physics, 75, 19
  2. Limits for the Firehose Instability in Space Plasmas [30]
    Lazar, M. & Poedts, S., Solar Physics, 258, 119
  3. Self-excited surface plasmon-polaritons at the interface of counterstreaming plasmas [8]
    Lazar, M., Moslem, W. M., Smolyakov, A. & Shukla, P. K., Physics of Plasmas, 16, 052102
  4. On the existence of Weibel instability in a magnetized plasma. I. Parallel wave propagation [30]
    Lazar, M., Schlickeiser, R. & Poedts, S., Physics of Plasmas, 16, 012106
  5. Cosmological Effects of Weibel-Type Instabilities [90]
    Lazar, M., Schlickeiser, R., Wielebinski, R. & Poedts, S., ApJ, 693, 1133
  6. Firehose instability in space plasmas with bi-kappa distributions [57]
    Lazaré, M. & Poedtsé, S., A&A, 494, 311
  7. Self-excited plasmon polaritons in counterstreaming quantum plasmas [5]
    Moslem, W. M., Lazar, M., Sabry, R. & Shukla, P. K., Physics of Plasmas, 16, 122106
  8. A comparative study of the filamentation and Weibel instabilities and their cumulative effect. II. Weakly relativistic beams [7]
    Stockem, A., Lazar, M., Shukla, P. K. & Smolyakov, A., Journal of Plasma Physics, 75, 529

2008

  1. Macroscopic description for the quantum Weibel instability [21]
    Haas, F. & Lazar, M., Physical Review E, 77, 046404
  2. Cumulative effect of the Weibel-type instabilities in symmetric counterstreaming plasmas with kappa anisotropies [55]
    Lazar, M., Schlickeiser, R. & Shukla, P. K., Physics of Plasmas, 15, 042103
  3. Fast magnetization in counterstreaming plasmas with temperature anisotropies [11]
    Lazar, M., Physics Letters A, 372, 2446
  4. Counterstreaming magnetized plasmas with kappa distributions - I. Parallel wave propagation [74]
    Lazar, M., Schlickeiser, R., Poedts, S. & Tautz, R. C., MNRAS, 390, 168
  5. On the origin of turbulent fields in interplanetary plasmas [0]
    Lazar, M., Exploring the Solar System and the Universe (Editors: Mioc, Vasile, Dumitrche, Cristiana & Popescu, Nedelia A.), American Institute of Physics Conference Series, 1043, p. 318
  6. Finite amplitude envelope surface solitons [5]
    Moslem, W. M., Lazar, M. & Shukla, P. K., Physics of Plasmas, 15, 042301
  7. Revision of ``Cumulative effect of the filamentation and Weibel instabilities in counterstreaming thermal plasmas'' [Phys. Plasmas 13, 102107 (2006)] [10]
    Stockem, A. & Lazar, M., Physics of Plasmas, 15, 014501

2007

  1. Surface waves on a quantum plasma half-space [72]
    Lazar, M., Shukla, P. K. & Smolyakov, A., Physics of Plasmas, 14, 124501
  2. Relativistic corrections to the nonlinear plasma permittivity: II. Coupling of longitudinal and transverse waves [1]
    Lazar, M., Schlickeiser, R., Shukla, P. K. & Smolyakov, A., Plasma Physics and Controlled Fusion, 49, 1661

2006

  1. Nonlinear response of a relativistic plasma to intense fields: Generation of strong quasistatic magnetic fields [6]
    Lazar, M., Schlickeiser, R. & Shukla, P. K., Physics of Plasmas, 13, 102302
  2. Cumulative effect of the filamentation and Weibel instabilities in counterstreaming thermal plasmas [36]
    Lazar, M., Schlickeiser, R. & Shukla, P. K., Physics of Plasmas, 13, 102107
  3. Covariant kinetic dispersion theory of linear transverse waves parallel propagating in magnetized plasmas with thermal anisotropy [11]
    Lazar, M. & Schlickeiser, R., Physics of Plasmas, 13, 012110
  4. Relativistic corrections to the nonlinear plasma permittivity: I. A covariant kinetic theory for longitudinal plasma wave interactions [2]
    Lazar, M., Shukla, P. K. & Schlickeiser, R., Plasma Physics and Controlled Fusion, 48, 911
  5. Relativistic kinetic dispersion theory of linear parallel waves in magnetized plasmas with isotropic thermal distributions [11]
    Lazar, M. & Schlickeiser, R., New Journal of Physics, 8, 66
  6. Relativistic (covariant) kinetic theory of linear plasma waves and instabilities [0]
    Lazar, M. & Schlickeiser, R., A Century of Relativity Physics: ERE 2005 (Editors: Mornas, Lysiane & Diaz Alonso, Juoaquin), American Institute of Physics Conference Series, 841, p. 479
  7. Covariant kinetic theory for nonlinear plasma waves interaction [1]
    Lazar, Marian & Schlickeiser, Reinhard, Journal of Plasma Physics, 72, 711

2004

  1. On the Relativistic Damping of Transverse Waves Propagating in Magnetized Vlasov Plasmas [4]
    Lazar, M. & Schlickeiser, R., Physica Scripta Volume T, 2004, 130

2003

  1. Relativistic Kinetic Theory of Waves in Equilibrium Magnetized Pair Plasma. General Dispersion Relations [4]
    Lazar, M. & Schlickeiser, R., Physica Scripta, 68, 146
  2. Kinetic theory of nonlinear waves interaction in relativistic plasmas [8]
    Lazar, M. & Merches, I., Physics Letters A, 313, 418
  3. Relativistic kinetic theory of electromagnetic waves in equilibrium magnetized plasma. General dispersion equations [10]
    Lazar, M. & Schlickeiser, R., Canadian Journal of Physics, 81, 1377
  4. Linear damping and energy dissipation of shear Alfvén waves in the interstellar medium [9]
    Lazar, M., Spanier, F. & Schlickeiser, R., A&A, 410, 415

2000

  1. Macroscopic model of PZT ceramics: linear piezoelectric equations [0]
    Lazar, Marian V., SIOEL 1999: Sixth Symposium on Optoelectronics (Editors: Necsoiu, Teodor, Robu, Maria & Dumitras, Dan C.), Society of Photo-Optical Instrumentation Engineers (SPIE) Conference Series, 4068, p. 136

1998

  1. Piezoceramics for acousto-optics applications [0]
    Dobrescu, Gabriel, Robu, Maria, Lazar, Marian V. & Hutanu, Vladimir M., Acousto-Optics and Applications III (Editors: Sliwinski, Antoni, Linde, Bogumil B. & Kwiek, Piotr), Society of Photo-Optical Instrumentation Engineers (SPIE) Conference Series, 3581, p. 271

Created on Wed Apr 8 04:33:58 2026.