Victor L'vov

Victor S. L'vov (Russian: Виктор Сергеевич Львов) is a Russian-Israeli physicist most known for his contributions to the advanced theories and applications of wave and hydrodynamic turbulence, as well as nonlinear phenomena in various physical systems, including plasma, superfluids, classical environmental flows, and solid states. He has authored about 280 publications in academic journals, including Nature Physics and Physical Review,^[1] and has written three books: Nonlinear Spin Waves (in Russian), Kolmogorov Spectra of Turbulence I: Wave Turbulence^[2] (in collaboration with V. Zakharov and G. Falkovich), and Wave Turbulence under Parametric Excitation: Applications to Magnets.^[3]

Victor S. L'vov
Nationality	Russian
Citizenship	Israeli
Occupation	Physicist
Academic background
Education	M.Sc., Theoretical Physics Ph.D., Physics and Math D.Sc., Physics
Alma mater	University of Leningrad, Russia Institute for Semiconductors, Leningrad, Russia
Academic work
Institutions	Weizmann Institute of Science

Education

L'vov completed his M.Sc. in Theoretical Physics from University of Leningrad in 1966 followed by a Ph.D. in Physics and Math from the Institute for Semiconductors at Leningrad. Later in 1974, he obtained his D.Sc. degree in physics from the Institute of Nuclear Physics at Novosibirsk.^[4]

Career

In 1968, L'vov joined the Institute for Semiconductors in Leningrad as a Junior Research Associate, serving until 1970. From 1970 to 1973, he was a Senior Research Associate at the Institute of Nuclear Physics in Novosibirsk. In 1970, he also became an Assistant Professor in Theoretical Physics at Novosibirsk University, a position he held until 1974. This was followed by an appointment as an Associate Professor in Theoretical Physics. From 1983 to 1990, he served as a Professor of Computer Science at the same institution. Concurrently, from 1973 to 2000, he was the head of the Lab for Nonlinear Physics at the Institution of Automation in Novosibirsk. From 1993 to 2012, he was a professor in the Department of Chemical Physics and has been a professor in the Feinberg Graduate School at the Weizmann Institute of Science since 1997.^[5]

Works

L'vov has authored three books. In 1987, he published the book Nonlinear Spin Waves in Russian, which focused on the dynamics and statistics of interacting spin waves. This book included the nonlinear theory of parametric and kinetic excitation of spin waves and provided a comparison of the theory with experiments. His next book, co-authored with V. Zakharov and G. Falkovich in 1992, was Kolmogorov Spectra of Turbulence I: Wave Turbulence. This work provided a study of turbulence across various systems, focusing on wave turbulence, and explored theoretical developments, including Kolmogorov spectra and energy cascade processes.^[2] Two years later, he authored Wave turbulence under parametric excitation: applications to magnets. The book explored wave turbulence with a focus on parametric wave turbulence, examining how it developed under strong external periodic modulation and comparing it to fully developed turbulence with different energy scales.^[3]

Since 1983, L'vov has co-authored five chapters in various books,^[6] including a chapter titled Turbulent Dynamics in Rotating Helium Superfluids in volume 16 of book series Progress in Low Temperature Physics (2009). The chapter investigated turbulence in helium superfluids ³He-B and ⁴He, using new techniques to explore how turbulence initiated, dissipated, and behaved at low temperatures where the normal fluid component was minimal.^[7]

Research

As part of his research, L'vov has authored academic papers. His 1975 study reviewed the nonlinear dynamics of spin waves in ferromagnetic dielectrics under parametric excitation, focusing on the limiting mechanism of wave pairing, described by the S theory, and its experimental verification and implications for collective oscillations and self-modulation.^[8] While reviewing the magnon properties of yttrium-iron garnet (YIG), his 1993 study introduced a new method for calculating magnon spectra, analyzing temperature-dependent magnetization, and discussing magnon relaxation mechanisms using both experimental data and theoretical models.^[9] In 1998, through an article published in Physical Review, he introduced a new "Sabra" shell model of turbulence with improved nonlinear coupling and correlation properties that addressed issues in the GOY model, while preserving multiscaling and exhibiting scaling exponents independent of the viscous mechanism.^[10]

Since 2007, L'vov's research has examined superfluid turbulence at near absolute zero. He highlighted how the interaction of quantized vortex filaments caused deviations from classical turbulence models and introduced a bottleneck effect in the energy spectrum at the crossover scale.^[11] In 2022, in collaboration with Y. Lvov, S. Nazarenko, and A. Pomyalov, he developed a theory of anisotropic superfluid counterflow turbulence, which explained the discovery of this phenomenon in numerical and laboratory experiments. Back in 2016, he ventured into the field of Bose-Einstein condensation of spin waves (magnons) in room-temperature ferrimagnets, particularly Yttrium-Iron Garnet. Collaborating with an experimental group in Kaiserslautern, he reported the discovery of a supercurrent in a room-temperature Bose–Einstein magnon condensate, Josephson oscillations, propagating Bogolyubov waves, and other quantum mechanical effects. In 2024, he conducted a study investigating how localized heating in magnetic films affected magnetization and the demagnetizing field, leading to changes in magnon dispersion and the formation of magnon supercurrents and Bose-Einstein condensation.^[12]

Returning to the study of wave turbulence in 2020, L'vov explored weak wave turbulence in Schrödinger-Helmholtz equations. He highlighted simultaneous inverse and forward cascades and interpreted the inverse cascade as non equilibrium condensation.^[13] Furthermore, in 2022, he collaborated with the Nazarenko group, and developed a theory of two-dimensional acoustic turbulence.^[14]

Bibliography

Books

• Nonlinear Spin Waves (1987)
• Kolmogorov spectra of turbulence I: Wave turbulence (1992) ISBN 9783642500541
• Wave Turbulence Under Parametric Excitation; Applications to Magnets (1994) 9783642752971

Selected articles

• Zakharov, V. E., L'vov, V. S., & Starobinets, S. S. (1975). Spin-wave turbulence beyond the parametric excitation threshold. Soviet Physics Uspekhi, 17(6), 896.
• Cherepanov, V., Kolokolov, I., & L'vov, V. (1993). The saga of YIG: Spectra, thermodynamics, interaction and relaxation of magnons in a complex magnet. Physics reports, 229(3), 81–144.
• L’vov, V. S., Podivilov, E., Pomyalov, A., Procaccia, I., & Vandembroucq, D. (1998). Improved shell model of turbulence. Physical Review E, 58(2), 1811.
• L’vov, V. S., Nazarenko, S. V., & Rudenko, O. (2007). Bottleneck crossover between classical and quantum superfluid turbulence. Physical Review B—Condensed Matter and Materials Physics, 76(2), 024520.
• Bozhko, D. A., Serga, A. A., Clausen, P., Vasyuchka, V. I., Heussner, F., Melkov, G. A., ... & Hillebrands, B. (2016). Supercurrent in a room-temperature Bose–Einstein magnon condensate. Nature Physics, 12(11), 1057–1062.
• L'vov, V. S., Lvov, Y. V., Nazarenko, S., & Pomyalov, A. (2022). Theory of anisotropic superfluid He-4 counterflow turbulence. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 380(2219). https://doi.org/10.1098/rsta.2021.0162

References

1. "Victor S. L'vov - Google Scholar".
2. "Kolmogorov spectra of turbulence I: Wave turbulence".
3. "Wave turbulence under parametric excitation: applications to magnets".
4. "Victor S. L'vov - Researchgate".
5. "Prof. Victor L'vov - Department of Chemical Physics".
6. "Reviews - Department of Chemical Physics".
7. "Turbulent Dynamics in Rotating Helium Superfluids".
8. "Spin-wave turbulence beyond the parametric excitation threshold".
9. "The saga of YIG: Spectra, thermodynamics, interaction and relaxation of magnons in a complex magnet".
10. "Improved shell model of turbulence".
11. "Bottleneck crossover between classical and quantum superfluid turbulence".
12. "Local temperature control of magnon frequency and direction of supercurrents in a magnon Bose-Einstein condensate".
13. "Wave turbulence in self-gravitating Bose gases and nonlocal nonlinear optics".
14. "Energy Spectrum of Two-Dimensional Acoustic Turbulence".