First-authored, refereed papers of Valery V. Pipin

A list of first-authored, refereed publications of Valery V. Pipin, 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: 0000-0001-9884-1147

List of publications ordered by citations
Number of papers: 48
No. of citations: 774

2026

1. Effects of Harmonic Magnetic Field Boundary Conditions in Mean-Field Solar Dynamo [1]
   Pipin, Valery, Solar Physics, 301, 24

2025

1. Helicity Fluxes and Hemispheric Helicity Rule of Active Regions Emerging from the Convection Zone Dynamo [2]
   Pipin, Valery V., Yang, Shangbin & Kosovichev, Alexander G., ApJ, 991, 88

2024

1. Solar Poloidal Magnetic Field Generation Rate from Observations and Mean-Field Dynamos [1]
   Pipin, Valery, Solar Physics, 299, 111
2. Toroidal Magnetic Flux Budget in Mean-field Dynamo Model of Solar Cycles 23 and 24 [5]
   Pipin, Valery V. & Kosovichev, Alexander G., ApJ, 962, 25

2023

1. Spatio-temporal non-localities in a solar-like mean-field dynamo [6]
   Pipin, V. V., MNRAS, 522, 2919
2. Effects of Emerging Bipolar Magnetic Regions in Mean-field Dynamo Model of Solar Cycles 23 and 24 [10]
   Pipin, V. V., Kosovichev, A. G. & Tomin, V. E., ApJ, 949, 7

2022

1. On the effect of surface bipolar magnetic regions on the convection zone dynamo [11]
   Pipin, V. V., MNRAS, 514, 1522

2021

1. Solar dynamo cycle variations with a rotational period [14]
   Pipin, V. V., MNRAS, 502, 2565
2. The magnetic helicity density patterns from non-axisymmetric solar dynamo [4]
   Pipin, Valery V., Journal of Plasma Physics, 87, 775870101

2020

1. Torsional Oscillations in Dynamo Models with Fluctuations and Potential for Helioseismic Predictions of the Solar Cycles [18]
   Pipin, Valery V. & Kosovichev, Alexander G., ApJ, 900, 26

2019

1. On the Origin of Solar Torsional Oscillations and Extended Solar Cycle [38]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 887, 215
2. Evolution of Magnetic Helicity in Solar Cycle 24 [25]
   Pipin, Valery V., Pevtsov, Alexei A., Liu, Yang & Kosovichev, Alexander G., ApJ, 877, L36

2018

1. Nonkinematic solar dynamo models with double-cell meridional circulation [12]
   Pipin, V. V., Journal of Atmospheric and Solar-Terrestrial Physics, 179, 185
2. Large-scale magnetic fields and anomalies of chemical composition of stellar coronae [1]
   Pipin, V. V. & Tomozov, V. M., Journal of Atmospheric and Solar-Terrestrial Physics, 173, 28
3. Does Nonaxisymmetric Dynamo Operate in the Sun? [13]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 867, 145
4. Generation of a Large-scale Magnetic Field in a Convective Full-sphere Cross-helicity Dynamo [13]
   Pipin, V. V. & Yokoi, N., ApJ, 859, 18
5. On the Origin of the Double-cell Meridional Circulation in the Solar Convection Zone [16]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 854, 67
6. The Nature of Variations in Anomalies of the Chemical Composition of the Solar Corona with the 11-Year Cycle [3]
   Pipin, V. V. & Tomozov, V. M., Astronomy Reports, 62, 281

2017

1. Non-linear regimes in mean-field full-sphere dynamo [21]
   Pipin, V. V., MNRAS, 466, 3007

2016

1. Dependence of Stellar Magnetic Activity Cycles on Rotational Period in a Nonlinear Solar-type Dynamo [12]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 823, 133
2. Angular momentum fluxes caused by Λ -effect and meridional circulation structure of the Sun [5]
   Pipin, Valery V. & Kosovichev, Alexander G., Advances in Space Research, 58, 1490

2015

1. Dependence of magnetic cycle parameters on period of rotation in non-linear solar-type dynamos [13]
   Pipin, V. V., MNRAS, 451, 1528
2. Effects of Large-scale Non-axisymmetric Perturbations in the Mean-field Solar Dynamo. [17]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 813, 134

2014

1. Magnetic Helicity of the Global Field in Solar Cycles 23 and 24 [19]
   Pipin, V. V. & Pevtsov, A. A., ApJ, 789, 21
2. Effects of Anisotropies in Turbulent Magnetic Diffusion in Mean-field Solar Dynamo Models [15]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 785, 49
3. Reversals of the solar magnetic dipole in the light of observational data and simple dynamo models [10]
   Pipin, V. V., Moss, D., Sokoloff, D. & Hoeksema, J. T., A&A, 567, A90

2013

1. The origin of the helicity hemispheric sign rule reversals in the mean-field solar-type dynamo [21]
   Pipin, V. V., Zhang, H., Sokoloff, D. D., Kuzanyan, K. M. & Gao, Y., MNRAS, 435, 2581
2. Helicity─vorticity turbulent pumping of magnetic fields in the solar convection zone [3]
   Pipin, V. V., Geophysical and Astrophysical Fluid Dynamics, 107, 185
3. The Mean-field Solar Dynamo with a Double Cell Meridional Circulation Pattern [36]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 776, 36
4. Helicity Conservation in Nonlinear Mean-field Solar Dynamo [23]
   Pipin, V. V., Sokoloff, D. D., Zhang, H. & Kuzanyan, K. M., ApJ, 768, 46

2012

1. Variations of the solar cycle profile in a solar dynamo with fluctuating dynamo governing parameters [47]
   Pipin, V. V., Sokoloff, D. D. & Usoskin, I. G., A&A, 542, A26

2011

1. The fluctuating α-effect and Waldmeier relations in the nonlinear dynamo models [13]
   Pipin, V. V. & Sokoloff, D. D., Physica Scripta, 84, 065903
2. Turbulent Cross-helicity in the Mean-field Solar Dynamo Problem [12]
   Pipin, V. V., Kuzanyan, K. M., Zhang, H. & Kosovichev, A. G., ApJ, 743, 160
3. The Asymmetry of Sunspot Cycles and Waldmeier Relations as a Result of Nonlinear Surface-shear Shaped Dynamo [46]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 741, 1
4. Mean-field Solar Dynamo Models with a Strong Meridional Flow at the Bottom of the Convection Zone [25]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 738, 104
5. The Subsurface-shear-shaped Solar αΩ Dynamo [64]
   Pipin, V. V. & Kosovichev, A. G., ApJ, 727, L45

2009

1. Stellar dynamos with Ω × J effect [22]
   Pipin, V. V. & Seehafer, N., A&A, 493, 819

2008

1. Closure tests for mean field magnetohydrodynamics using a self-consistent reduced model [1]
   Pipin, V. V. & Proctor, M. R. E., MNRAS, 388, 367
2. The mean electro-motive force and current helicity under the influence of rotation, magnetic field and shear [52]
   Pipin, V. V., Geophysical and Astrophysical Fluid Dynamics, 102, 21

2007

1. Generation of solar magnetic fields by the αδΘ dynamo [5]
   Pipin, V. V., Astronomy Reports, 51, 411

2004

1. Variations in the Solar Luminosity, Radius, and Quadrupole Moment as Effects of a Large-Scale Dynamo in the Solar Convection Zone [11]
   Pipin, V. V., Astronomy Reports, 48, 418

2003

1. The s-Effect and Current Helicity for Fast Sheared Rotators [4]
   Pipin, V. V., Geophysical and Astrophysical Fluid Dynamics, 97, 25

2001

1. Diffusion of a Passive Scalar in a Rotating Medium with Anisotropic Turbulence [1]
   Pipin, V. V., Astronomy Letters, 27, 171

2000

1. The Solar Dynamo and Integrated Irradiance Variations in the Course of the 11-Year Cycle [12]
   Pipin, V. V. & Kichatinov, L. L., Astronomy Reports, 44, 771

1999

1. The Gleissberg cycle by a nonlinear alpha L\ dynamo [58]
   Pipin, V. V., A&A, 346, 295

1996

1. The rotational quenching of the rotation-induced kinetic alpha-effect [12]
   Pipin, V. V., Rüdiger, G. & Kitchatinov, L. L., Geophysical and Astrophysical Fluid Dynamics, 83, 119

1995

1. On the transport of large-scale magnetic fields in the turbulent convective envelope of the sun [1]
   Pipin, V. V., Astronomy Letters, 21, 199

1994

1. Turbulence in a rotating magnetized fluid [0]
   Pipin, V. V., Astronomische Nachrichten, 315, 151