Publications of V. N. Krivodubskij

A list of publications authored or co-authored by V. N. Krivodubskij, 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: 0000-0001-7655-8121

List of publications ordered by citations
Number of papers: 33 (refereed: 28)
No. of citations: 165
First author papers: 22 (refereed: 18)

2025

  1. North-South Asymmetry of Sunspot Activity during the Maunder Minimum [0]
    Krivodubskij, V. N., Odessa Astronomical Publications, 38, 162

2024

  1. Macroscopic Turbulent Diamagnetism of Solar Plasma [0]
    Krivodubskij, V. N., Odessa Astronomical Publications, 37, 118

2023

  1. Anomalous Magnetic Regions on the Sun [1]
    Kondrashova, N. N. & Krivodubskij, V. N., Odessa Astronomical Publications, 36, 167
  2. Theoretical and Observed Signs of Excitation of Small-Scale Magnetic Fluctuations in the Depth of the Sun [0]
    Krivodubskij, V. N. & Kondrashova, N. M., Kinematics and Physics of Celestial Bodies, 39, 342

2021

  1. Role of rotational radial magnetic advection in possible explaining a cycle with two peaks [3]
    Krivodubskij, V. N., Advances in Space Research, 68, 3943
  2. Generation of the Solar Variable Magnetic Field by the Global Migratory Flow [0]
    Loginov, A. A., Krivodubskij, V. N. & Cheremnykh, O. K., Kinematics and Physics of Celestial Bodies, 37, 16
  3. Generation by global migratory flow of variable magnetic field of the Sun [0]
    Loginov, A. A., Krivodubskij, V. N. & Cheremnykh, O. K., Kinematika i Fizika Nebesnykh Tel, 37, 30
  4. ULF Activity in the Earth Environment: Penetration of Electric Field from the Near-Ground Source to the Ionosphere under Different Configurations of the Geomagnetic Field [6]
    Yutsis, Vsevolod, Rapoport, Yuriy, Grimalsky, Volodymyr, Grytsai, Asen, Ivchenko, Vasyl, Petrishchevskii, Sergei, Fedorenko, Alla & Krivodubskij, Valery, Atmosphere, 12, 801

2020

  1. The Role of Macroscopic Turbulent Diamagnetism in Ensuring Long-Term Stability of Sunspots [0]
    Krivodubskij, V. N., Odessa Astronomical Publications, 33, 85
  2. Generation of the Sun's Radial Magnetic Field by Global Hydrodynamic Flows [2]
    Loginov, A. A., Krivodubskij, V. N. & Cheremnykh, O. K., Kinematics and Physics of Celestial Bodies, 36, 56

2019

  1. On the Role of MHD Turbulence in the Decrease of Electrical Conductivity of Plasma in the Sun's Active Magnetic Region [1]
    Krivodubskij, V. N., Kinematics and Physics of Celestial Bodies, 35, 124
  2. On the role of MHD turbulence in the decrease of electric conductivity of plasma in the active magnetic area of the Sun [0]
    Krivodubskij, V. N., Kinematika i Fizika Nebesnykh Tel, 35, 34
  3. Generation of the toroidal magnetic field in the radiant zone of the Sun and alternation of the amplitude of the neighboring magnetic cycles [0]
    Krivodubskij, V. N., Astronomical School's Report, 15, 25

2018

  1. Convective overshoot and tachochlin are the most favorable the deep layers of the Sun to excite a toroidal magnetic field [0]
    Krivodubskij, V. N., Astronomical School's Report, 14, 62

2017

  1. Double maxima of 11-year solar cycles [6]
    Krivodubskij, V. N., Kinematics and Physics of Celestial Bodies, 33, 24
  2. Double maxima 11-year solar cycles [0]
    Krivodubskij, V. N., Kinematika i Fizika Nebesnykh Tel, 33, 55
  3. Sources of solar energy and interplanetary magnetic field [0]
    Krivodubskij, V. N., Astronomical School's Report, 13, 68
  4. Simulating the generation of the solar toroidal magnetic field by differential rotation [5]
    Loginov, A. A., Krivodubskij, V. N., Salnikov, N. N. & Prutsko, Yu. V., Kinematics and Physics of Celestial Bodies, 33, 265
  5. Simulation of the generation of the toroidal magnetic field of the Sun by differential rotation [0]
    Loginov, A. A., Krivodubskij, V. N., Salnikov, N. N. & Prutsko, Y. V., Kinematika i Fizika Nebesnykh Tel, 33, 17

2015

  1. Small scale alpha-squared effect in the solar convection zone [9]
    Krivodubskij, V. N., Kinematics and Physics of Celestial Bodies, 31, 55

2013

  1. The role of the negative helical turbulent viscosity in the fragmentations of the magnetic fields on the Sun [0]
    Krivodubskij, V. N., Astronomical School's Report, 9, 28
  2. Dependence of solar cycles duration on the magnitude of the annual module of the sunspots magnetic field [4]
    Krivodubskij, Valery N. & Lozitska, Natalia I., Solar and Astrophysical Dynamos and Magnetic Activity (Editors: Kosovichev, Alexander G., de Gouveia Dal Pino, Elisabete & Yan, Yihua), IAU Symposium, 294, p. 71
  3. On the extended 23rd solar cycle [5]
    Krivodubskij, Valery N., Solar and Astrophysical Dynamos and Magnetic Activity (Editors: Kosovichev, Alexander G., de Gouveia Dal Pino, Elisabete & Yan, Yihua), IAU Symposium, 294, p. 69

2012

  1. The mass distribution in the galaxy cluster Abell 2744 [37]
    Babyk, Iu., Elyiv, A., Melnyk, O. & Krivodubskij, V. N., Kinematics and Physics of Celestial Bodies, 28, 69
  2. Turbulent effects of sunspot magnetic field reconstruction [15]
    Krivodubskii, V. N., Kinematics and Physics of Celestial Bodies, 28, 232
  3. Hydrodynamic model of spatial and temporal variations of poloidal and Toroidal components of three-dimensional solar flows [6]
    Loginov, A. A., Cheremnykh, O. K., Krivodubskij, V. N. & Salnikov, N. N., Bulletin Crimean Astrophysical Observatory, 108, 58

2007

  1. "Negative magnetic buoyancy" effects and reconstruction of toroidal field in the solar convection zone [0]
    Krivodubskij, Valery N., Convection in Astrophysics (Editors: Kupka, Friedrich, Roxburgh, Ian & Chan, Kwing Lam), IAU Symposium, 239, p. 502

2005

  1. Turbulent dynamo near tachocline and reconstruction of azimuthal magnetic field in the solar convection zone [47]
    Krivodubskij, V. N., Astronomische Nachrichten, 326, 61

2004

  1. Illintsi's astroblem is the ancientest one on the Ukrainian crystal shield [0]
    Krivodubskij, V. N., Solonenko, V. I. & Churiumov, K. I., Astronomical School's Report, 5, 23
  2. A role of magnetic advection mechanisms in the formation of a sunspot belt [1]
    Krivodubskij, Valery N., Multi-Wavelength Investigations of Solar Activity (Editors: Stepanov, Alexander V., Benevolenskaya, Elena E. & Kosovichev, Alexander G.), IAU Symposium, 223, p. 277

2001

  1. The structure of the global solar magnetic field excited by the turbulent dynamo mechanism [14]
    Krivodubskii, V. N., Astronomy Reports, 45, 738

1991

  1. The transfer of large-scale magnetic field by radial inhomogeneity of the material density in the rotating convection zone [2]
    Krivodubskij, V. N. & Kichatinov, L. L., IAU Colloquium 130: The Sun and Cool Stars. Activity, Magnetism, Dynamos (Editors: Tuominen, I., Moss, D. & Rüdiger, G.), p.190
  2. The Toroidal Magnetic Field Inside the Sun [1]
    Krivodubskij, V. N., Dudorov, A. E., Ruzmaikin, A. A. & Ruzmaikina, T. V., IAU Colloquium 130: The Sun and Cool Stars. Activity, Magnetism, Dynamos (Editors: Tuominen, I., Moss, D. & Rüdiger, G.), p.187

Created on Wed Apr 8 04:34:08 2026.