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The importance of cell cycle parameters for the development of space plant growing. Space Science and Technology. 2017 ;23(5):66-71.
. Mathematical modelling of thermal and hydrodynamic processes in the electron beam floating-zone melting of silicon monocrystal under microgravity conditions. Kosm. nauka tehnol. 2002 ;8(5-6):112-116.
. Activation of lipid peroxidation as a mechanism of plant cell rearrangements under microgravity. Kosm. nauka tehnol. 2007 ;13(2):075-079.
. Microgravity and ultrahigh vacuum as specific components of technological environment and new feasibilities of semiconductor technology. Kosm. nauka tehnol. 2002 ;8(4):096-099.
. MICROCOSM as a perspective model for biological experiment at nanosatellite. Space Science and Technology. 2018 ;24(2):55-59.
. Features of the control of solidification structure using directional crystallization with superimposed vibration exposure under weightlessness conditions. Kosm. nauka tehnol. 2015 ;21(2):73–80.
. Microgravity as the experimental basis for understanding of the peculiarities of plant morphogenesis in the gravitational field. Kosm. nauka tehnol. 2006 ;12(5-6):030-035.
. High-gradient magnetic fields as a tool of simulating gravity effects on plants. Kosm. nauka tehnol. 2001 ;7(5-6):100-111.
. Statoliths displacement in root statocytes in real and simulated microgravity. Space Science and Technology. 2021 ;27(2):78-84.
. Influence of the real and simulated microgravity on gene expression of heat-shock proteins. Kosm. nauka tehnol. 2007 ;13(2):057-061.