isotopes separation and their applications,
spectroscopy,
quantum control,
quantum computer,
global optimization,
laser,
MHD-generator.
Subject:
Quantum technologies, physical chemistry, aerodynamics, photochemistry, theoretical and applied nuclear physics, theoretical and applied plasma physics, device physics.
Biography
Since 2018, Ive been working in the department of Mathematical Methods of Quantum Technologies at Steklov Mathematical Institute. My major field of research there is the laser assisted isotope separation.
In December of 2010 I have joined the Plasma Applications laboratory in the Nuclear and Energy Engineering department of Jeju National University as a Researcher, then, in the mid-2012, I have been promoted to Research Professor. I was involved there in the development of laser assisted methods for isotopes separation and fabrication of new materials.
Since 2010, I have joined the company "Science for Technology" at the Institute of Biochemical Physics of Russian Academy of Science as a researcher. My research field there was on the fuel cells, polymer physics, optimal control, and multidimensional stochastic analysis.
Since 2008, I have been oil reservoir engineer and researcher in the company "Petroleum Technologies"and since 2009 as a researcher in oil fields development in the company "Konkord"
Ive earned PhD degree in theoretical nuclear and high energy physics in the Physical Department of J.W. Goethe University, Frankfurt am Main, in the February 2008. As a PhD student in Frankfurt International Graduate School for Science, I have been involved in the research on "Baryon stopping and Quark Gluon Plasma production at Relativistic Heavy Ion Collider(RHIC) and Large Hadron Collider(LHC) experiments".
Ive earned MSc degree in theoretical physics in the Physical Faculty of Lomonosov Moscow State University, in 2001.
Main publications:
Lyakhov, K.A. and Lee, H.J. and Pechen, A.N., “Some issues of industrial scale boron isotopes separation by the laser assisted retarded condensation (SILARC) method”, Separation and Purification Technology, 176:4 (2017), 402-411
Lyakhov, K.A. and Lee, H.J. and Pechen, A.N., “Some Features of Boron Isotopes Separation by the Laser-Assisted Retardation of Condensation Method in Multipass Irradiation Cell Implemented as a Resonator”, IEEE Journal of Quantum Electronics, 52:12 (2016), 1400208-1-8
Ahmed, M.W. and Choi, S. and Lyakhov, K.A. and Shaislamov, U. and Mongre, R.K. and Jeong, D.K. and Suresh, R. and Lee, H.J., “High-frequency underwater plasma discharge application in antibacterial activity”, Plasma Phys. Rep., 2017, 1-12
Mishustin, I.N., Lyakhov,K.A., “Baryon deceleration and partonic plasma creation by strong chromofields in ultra-relativistic heavy ion collisions”, Physics of Atomic Nuclei, 75 (2012), 371-392
Lyakhov, K.A. and Lee, H.-J., “Baryon kinetic energy loss in the color flux tube model”, Physical Review C, 84 (2011), 055206
K. A. Lyakhov, H. J. Lee, A. N. Pechen, “Some issues of industrial scale boron isotopes separation by the laser assisted retarded condensation (SILARC) method”, Sep. Purif. Technol., 176:4 (2017), 402–411
K. A. Lyakhov, A. N. Pechen, “CO$_2$ laser system design for efficient boron isotope separation by the method of selective laser-assisted retardation of condensation”, Appl. Phys. B, 126 (2020), 141 , 11 pp. ;
I. N. Mishustin, K. A. Lyakhov, “Baryon deceleration by strong chromofields in ultra-relativistic heavy ion collisions”, Physical Review C, 76 (2007), 011603
K. A. Lyakhov, Heon Ju Lee, A. N. Pechen, “Some features of Boron isotopes separation by the laser-assisted retardation of condensation method in multipass irradiation cell implemented as a resonator”, IEEE Journal of Quantum Electronics, 52:12 (2016), 1400208–8
K. A. Lyakhov, A. N. Pechen, H.-J. Lee, “The efficiency of one-line versus multi-line excitation of boron isotopes within the method of selective laser assisted retardation of condensation”, AIP Advances, 8 (2018), 95325 , 10 pp.
K. A. Lyakhov, K. H. Lee, “Some features of experimental setup design for isotopes separation by the laser assisted retardation of condensation method”, J. Laser Appl., 27:2 (2015), 022008
K. A. Lyakhov, H. J. Lee, “Basic features of boron isotope separation by SILARC method in the two-step iterative static model”, Appl. Phys. B, 111:2 (2013), 261–272
K. A. Lyakhov, H. J. Lee, “New Experimental Setup for Boron Isotopes Separation by the Laser Assisted Retardation of Condensation Method”, J. Nanoscience Nanotechnology, 15:11 (2015), 8502–8507
K. A. Lyakhov, A. N. Pechen, “Evolution of the Enrichment Factor for an Iterative Scheme of Zirconium Isotopes Separation”, Lobachevskii J. Math., 41:12 (2020), 2345–2351;
K. A. Lyakhov, H.-J. Lee, I. N. Mishustin, “Baryon stopping and partonic plasma production by strong chromofields”, Physical Review C, 84 (2011), 055202
K. A. Lyakhov, A. N. Pechen, “Constrained Optimization Criterion for Zirconium Isotope Separation by the Method of Laser-Assisted Retardation of Condensation”, Proc. Steklov Inst. Math., 313 (2021), 131–141
13.
K. A. Lyakhov, A. N. Pechen, “Enrichment factor for molybdenum isotopes separation by the method of laser-assisted retardation of condensation”, Lobachevskii J. Math., 42:10 (2021), 2392–2400;
Lyakhov, K. A., “Optimization Criterion for Two-Stage Cascade for Iterative Molybdenum Isotopes Recovery by the method of laser-assisted retardation of condensation(SILARC)”, Journal of Physics: Conference Series, 2147 (2022), 012009
K. A. Lyakhov, A. N. Pechen, “Mathematical model of hydrogen dissociation on $\mathrm{MO}_2\mathrm{C}$ surface in the presence of a laser field”, Lobachevskii J. Math., 44:6 (2023), 2125–2134
K. A. Lyakhov, A. N. Pechen, “Laser and diffusion driven optimal discrimination of similar quantum systems in resonator”, Lobachevskii J. Math., 43:7 (2022), 1693–1703;
K. A. Lyakhov, “Two-stage industrial scale scheme for molybdenum isotopes separation by the laser assisted retardation of condensation method”, Nuclear Engineering and Design, 424 (2024), 113250 , 11 pp. ;
19.
Lyakhov, K. A., Some Features of Boron Isotopes Separation by Laser-Assisted Retardation of Condensation Method, Boron, Boron Compounds and Boron-Based Materials and Structures, eds. Prof. Metin Aydin, Intech Open, Rijeka, 2023 , 29 pp. https://www.intechopen.com/online-first/87383
20.
K. A. Lyakhov, V. A. Grigoriev, E. G. Tsiplakova, “Automatic recognition of internal structures in translucent objects based on hologram-moire interferometry”, Sci.Tech. J. Inf. Technol. Mech. Opt., 22:5 (2022), 854–858
21.
K. A. Lyakhov, A. N. Pechen, “Selective multi-line excitation of isotopologues with similar quantum spectra as a function of gas flow pressure, temperature, and laser pulse spectrum”, AIP Conf. Proc., 2362, 2021, 040008 , 6 pp. ;
22.
Lyakhov, K. A., Pechen, A.N.,, “Objective Function in the Problem of Optimal Laser-Assisted Separation of Isotopes by the Method of Selective Retardation of Condensation”, Journal of Mathematical Sciences, 252 (2021), 60–64; K. A. Lyakhov, A. N. Pechen, “Tselevaya funktsiya v zadache optimalnogo lazernogo razdeleniya izotopov metodom selektivnogo tormozheniya”, Kvantovaya veroyatnost, Itogi nauki i tekhn. Ser. Sovrem. mat. i ee pril. Temat. obz., 151 (2018), 62-66
23.
K.A.Lyakhov, A.N.Pechen, “Basic Vacuum Pump System Prerequisites for Boron Isotopes Separation by the Laser Assisted Retardation of Condensation (SILARC) method”, Physical and Chemical Processes in Atomic Systems, XVII International Scientific Conference and School of Young Scholars (Moscow, Russia, 2019, Oct’28-30), NRNU MEPhI, 2019, 67https://pnasc.mephi.ru/wp-content/uploads/2019/10/tp_final.pdf
24.
K. A. Lyakhov, A. N. Pechen, H. J. Lee, “Optimal CO2 laser system design for 11BCl3 excitation by the method of selective laser assisted retardation of condensation”, J. Electr. Eng. Electron. Technol., 8 (2019), 86;
25.
K. A. Lyakhov, A. N. Pechen, “Objective Function in the Problem of Optimal Laser-Assisted Separation of Isotopes by the Method of Selective Retardation of Condensation”, J. Math. Sci. (N. Y.), 252:1 (2021), 60–64
26.
K. A. Lyakhov, H.-J. Lee, “Baryon kinetic energy loss in the color flux tube model”, Physical Review C, 84 (2011), 055206
27.
K. A. Lyakhov, “Particles production in expanding color flux tube”, Physics of Particles and Nuclei, 39 (2008), 1110–1112