Tribute
Nikita Alexeevich Sveshnikov
(27.02 1953  29.07 1997)
In memory of Nikita Alexeevich Sveshnikov (19531997)
Nikita Alexeevich Sveshnikov, Associate Professor at the Department of Physics of Moscow State University, a brilliant scientist and educator, untimely died on July 29 1997, aged 44.
As a graduate of the Chair of Quantum Statistics in the Department of Physics of MSU, headed by Professor N.N. Bogoliubov, Nikita Sveshnikov started his scientific endeavors early in his undergraduate years. In his Diploma work and then PhD thesis under the supervision of Professor D.V. Shirkov he studied the problem of infrared divergences in Quantum Field Theory. Such divergences known since 1930s have acquired a special interest in connection with the problem of confinement of quarks in Quantum Chromodynamics. N.A. Sveshnikov was the first to realise that a consistent application of the method of asymptotic dynamics, which exactly describes interaction processes of particles at asymptotically large times, to massless models of nonAbelian symmetry may give rise to nontrivial restrictions on the spectrum of the theory. In a series of works in late 1970s  early 1980s he has shown that in a model charge symmetric theory there are no states with nonzero nonAbelian charge, and in the framework of perturbative Quantum ChromoDynamics there are no asymptotic states corresponding to free quarks, what may be interpreted as an indication for confinement. Later on during his scientific career, Nikita Alexeevich turned again to these related problems of infrared divergences, asymptotic dynamics and confinement, and continued to work on them productively to the last day of his life.
An important contribution by N.A. Sveshnikov to the Quantum Gauge Field Theory was in recognition of the special role of surface terms and delocalised observables (variables at infinity) in Quantum Gluodynamics formulated in the physical FockSchwinger gauge. He also developed elegant functional integration techniques for adequately taking such variables into account and studying the dependence of the partition function on the boundary conditions. This has allowed him to explain the mechanism of the confinementdeconfinement phase transition in SU(N)gluodynamics. He has shown that below the critical temperature only the zero value of the colour charge flux in any angular cone at spatial infinity is statistically realisable. The latter is equivalent to the `noescape' condition of colour in any angular direction and mathematically expresses the singletness of physical observables with respect to the subgroup of gauge transformations at infinity, which in turn ensures fulfillment of the Wilson confinement criterion. The numerical value for the string tension coefficient predicted by this theory is close to that from Monte Carlo lattice simulations.
These works had a natural development in later results for the theory of jet reactions at high energies obtained in mid1990s. In particular, the connection of the main class of observables to the energymomentum tensor was established.
It should be noted that the supreme theoretical abilities of Nikita Alexeevich enabled him to construct consistent theories in fields which until then were only amenable to halfphenomenological treatments. The mathematical gift was perhaps one of his strongest points  one is tempted to think of a genetic predisposition. Sometimes it might even seem that mathematics obscures the physical side for him. However, such an impression is certainly wrong  the physics of any phenomenon was always on the forefront of his thinking.
As time went on, the scope of Nikita Alexeevich's scientific interests expanded. His extensive erudition and superlative skill allowed him to work successfully on a few pivotal theoretical problems from different branches of physics, and not physics alone, simultaneously. For example, he studied propagation of information in distributed systems. In particular, he demonstrated that a population of neurons not directly interacting with each other, but only via secreting a special chemical into their common environment and responding to local variations in its concentration, are capable of carrying out rather complex functions in transferring information. Also, more complicated systems with large organic molecules as active units and messengermolecules carrying information about the addressee code were studied.
Sadly, untimely death interrupted the diverse scientific studies of Nikita Alexeevich. He left many unpublished or partially published results at different stages of completion, which will continue to be submitted to press by his colleagues and students. Among his late works it is interesting to mention the original study of special nonPauli states in threebody systems, the development of the theory of quantum bound states embedded in continuum, the study of classical analogues of such states: bound states without classical turning points, and the development of methods for construction of isospectral Hamiltonians.
For Nikita Alexeevich scientific research was always inseparable from teaching. The latter was one of the most important sides of his activity. It would be no exaggeration to say that he put his heart into teaching students from the Chair of Quantum Theory and High Energy Physics in the Department of Physics of MSU, headed by Professor A.A. Logunov, and the Division of Nuclear Physics as a whole, where he was Deputy Head for many years. He liked and knew how to teach well, and his pedagogical talent matured with every year. For the current generation of students of the Department of Physics Nikita Alexeevich was one of the best loved lecturers. Anyone, who had the privilege of knowing him, will remember how rapidly Nikita Alexeevich perfected as a University teacher and researcher. This was clear to his undergraduate and postgraduate students, the number of which constantly increased. During the past few years he was giving a fullyear special course on Quantum Field Theory. His contribution to the organisation of various other topical courses, such as e.g. the course `Quantum Field Theory for Experimentalists' given by Professor D.V. Shirkov, was also invaluable. Nikita Alexeevich had a striking ability to carry the weight of organisational and public duties with elegance and ease, and every job was invariably done in the most efficient and comprehensive manner.
One such duty, closely related to research and teaching, was the job into which Nikita Alexeevich put his heart during the last 12 years. In 1985 he helped organising the first Summer School for Young Scientists on Quantum Field Theory and High Energy Physics convened by the Nuclear Physics Institute of MSU. Gradually, this Summer School grew into an annual international event, widely known in Russia and worldwide as the QFTHEP Workshop. Since the first School and every year Nikita Alexeevich was the key figure in the Organising Committee. His admirable presentations and numerous discussions he organised will be long remembered by many participants of QFTHEP. As usual, he played a most active role in the preparation of the 12th QFTHEP Workshop, which took place already after his demise in September 1997 in Samara and was dedicated to his memory.
N.A. Sveshnikov was, despite his young age, a person to whom people came for advice and opinion. His sharp wit, deep knowledge, and importantly, outgoing personality helped to many in their problems. Nikita Alexeevich was also a rather modest and selfdisciplined person. He was a man of many talents, among which the art of human relations was intrinsic to him. It was no accident that he always played an important role in the social life of the Department of Physics in Moscow State University.
Nikita Alexeevich, our dear colleague and good friend, was generously blessed with many talents. The words `TALENT' and `CHARM' would perhaps characterise him best of all. It would be wrong to say that he left this life, for his accomplishments, scientific results, ideas and dreams will stay with us for ever.
Friends, colleagues and disciples will cherish the grateful memory of this remarkable man.
Professors V.G. Kadyshevskii, A.A. Logunov, V.A. Matveev,
V.A. Rubakov, V.I. Savrin, A.A. Slavnov,
V.I. Trukhin, O.A. Khrustalev, D.V. Shirkov
1998 (C) UFN, No 2, 198, Russian Academy of Sciences. All rights reserved.
Highlights of the biography
Graduated from Physics Faculty, Moscow State University (1976).
Ph.D. from Moscow State University (1981) under supervision of Professor D.V. Shirkov.
Associate Professor, Department of Quantum Theory and High Energy Physics, Physics Faculty, Moscow State University.
Research speciality: Elementary Particle Physics and Field Theory, Thermodynamics and Statistical Physics.
Selected publications

Kamenschik, A.Yu., Sveshnikov N.A., Absence of free quarks in perturbative QCD. Physics Letters B, 1983, 123, No 3/4, 255258.

Kamenschik, A.Yu., Sveshnikov, N.A., "Quarks 84", Proc. Intern. Sem., 1985, p. 258.

Imashev, M.S., Sveshnikov, N.A., Dynamical time formulation of quantum mechanics and the BohrSommerfeld quantization rule. Preprint NPI MSU, 1987, No 8719/96, 15 p.

Krivchenkov, I.V., Sveshnikov, N.A., "Quarks 86", Proc. Intern. Sem., 1987, p. 339.

Krivchenkov, I.V., Sveshnikov N.A., Asymptotics of the massive particle propagator in a model related to the Heisenberg algebra (In Russian). Teoreticheskaya i matematicheskaya fizika, 1989, 78, No 2, 215226.

Mikhailov, A.S., Sveshnikov, N.A., Dual description and dynamics of the Hopfield model. Preprint NPI MSU, 1989, No 50/127, 30 p.

Sveshnikov N.A., Krivchenkov I.V., Asymptotics of massive particle propagator in a model related with Heisenberg algebra (in Russian). Theor. Math. Fiz. (1989) 78 , No 2, 154162.

Krivchenkov, I.V., Sveshnikov, N.A., "Problems of High Energy Physics and Field Theory", Proc. XI Workshop, 1989, p. 231.

Mikhailov, A.S., Mitkov I.V., Sveshnikov, N.A., Molecular associative memory. BioSystems, 1990, 23, No 4, 291295.

Izhikevich, E.M., Mikhailov A.S., Sveshnikov, N.A., Memory, learning, and neuromediators. BioSystems, 1991, 25, No 4, 219229.

Mikhailov, A.S., Mitkov I.V., Sveshnikov, N.A., Associative memory with mediators. J. of Nonlinear Biology, 1991, No 2, 263272.

Mikhailov, A.S., Igikevich E.A.., Sveshnikov, N.A., Pattern recognition by realistic neural nets. J. of Nonlinear Biology, 1991, 4 No 1, 243457.

Sveshnikov N.A., Timoshenko E.G., Confinement phase transition mechanism of SU(2)gluodynamics. Preprint IHEP, 1991, No 91140, 30 p.

Sveshnikov N.A., Timoshenko E.G., Confinement phase transition in gluodynamics. Preprint IHEP, 1992, No 9231, 13 p.

Sveshnikov, N.A., Timoshenko E.G., Confinement phase transition in gluodynamics. Physics Letters B, 1992, 289, No 3/4, 423428.

Sveshnikov N.A., NonPauli states in 3body systems. In: "Proc. of Int. Workshop on Quantum Systems. Minsk, 2329. V.1994, Eds. A.O.Barut et al., World Scientific, Singapore, p. 7178 (1994).

Sveshnikov N.A., Timoshenko E.G., Confinement phase transition in gluodynamics via variables at infinity. Problems on High Energy Physics and Quantum Field Theory  Proceedings of the XV Workshop, IHEP, Protvino, pp. 162168 (1995).

Sveshnikov N.A., NonPauli states in quantum systems. In.:"Problems on High Energy Physics and Field Theory" Proc.of XVI Workshop. IHEP, Protvino, p.198206 (1995).19. Sveshnikov N.A., Tkachov F.V., Jets and quantum field theory. Phys. Lett B 382: (4) 403408 AUG 15 1996.

Sveshnikov N.A., Tkachov F.V., Jets and quantum field theory. Phys. Lett B 382: (4) 403408 AUG 15 1996.

Sveshnikov N.A., Timoshenko E.G., The partition function versus boundary conditions and confinement in the YangMills theory. Phys. Rev. D. Vol. 58, No 8, Art. No 085024, 9 p. (1998).

N.A. Sveshnikov, E.G. Timoshenko. Boundary effects and confinement in the gauge field theory. Talk at the XII International HEPQFT Workshop. Samara, Russia, 4  10 September 1997.
Special issue Vol. 117, No 2, November 1998 of Theoretical and Mathematical Physics dedicated to the memory of N.A. Sveshnikov and F.A. Lunev
English Translation by Plenum Publ. Corp., New York.
IDS Number: 174DT. ISSN: 00405779.
Tribute
It is with a feeling of deep sadness and irrecoverable loss that we have heard of the untimely death of Nikita Aleexeecich. In the name of N.A. Sveshnikov Theoretical Physics has lost an extremely talented scientist, a great educator and a very nice person. No matter how big influence Nikita Alexeevich's ideas had on his students and on colleagues who knew him well, it would be only fair to say that it is for future generations to judge their true merit. It was one of N.A. Sveshnikov's gifts to be able to see farther ahead in search for the hidden mathematical beauty of the physical world, the beauty that expresses the essence of all things.
E.G. Timoshenko, on behalf of his students
Gennadi Alexandrovich Sardanashvily
(13.03.1950  01.09.2016)
Gennadi Sardanashvily graduated from Moscow State University (MSU) in 1973, he was a Ph.D. student of the Department of Theoretical Physics (MSU) in 1973–76, where he held a position in 1976.
He attained his Ph.D. degree in physics and mathematics from MSU, in 1980, with Dmitri Ivanenko as his supervisor, and his D.Sc. degree in physics and mathematics from MSU, in 1998.
Gennadi Sardanashvily was the founder and Managing Editor (2003  2013) of the International Journal of Geometric Methods in Modern Physics (IJGMMP).
He was a member of Lepage Research Institute (Czech Republic).
Alexander Valerievich Gorelov
(15.08.1962  30.03.2018)
Sasha was a wonderful man, a brilliant scientist in polymers, laser light scattering, ultrasound, who understood theory and could do experiments. He has married Tatiana in 1997, had a son Alexei born in 2002. Sasha has died on the Good Friday 30.03.2018 at age of 55 of a heart failure. My friend for 25 years. RIP, Sasha (Alexander).
1. D.A. Tikhonov, R.V. Polozov, E.G. Timoshenko, Yu.A. Kuznetsov, A.V. Gorelov, K.A. Dawson. "Hydration of a BDNA fragment in the method of atomatom correlation functions in the RISM approximation." J. Chem. Phys. Vol. 109, No 4, pp. 15281539 (1998).
2. K.A. Dawson, A.V. Gorelov, E.G. Timoshenko, Yu.A. Kuznetsov, A. Du Chesne. "Formation of mesoglobules from phase separation in dilute polymer solutions; A study in experiment, theory, and applications." Physica, Vol. A 244, pp. 6880 (1997).
3. D.A. Tikhonov, R.V. Polozov, A.V. Gorelov, E.G. Timoshenko, Yu.A. Kuznetsov, L.A. Panchenko, K.A. Dawson. "Hydration of the BDNA fragment, d(GGGGG). Integral equation theory of liquids." (In Russian). Biophysics (Russia), Vol. 42, No 5, pp. 10661078 (1997).
4. D.A. Tikhonov, R.V. Polozov, A.V. Gorelov, E.G. Timoshenko, Yu.A. Kuznetsov, L.A. Panchenko, K.A. Dawson. "Integral equations theory of liquids for studying of hydration of macromolecules." (In Russian). Biophysics (Russia), Vol. 42, No 5, pp. 10541065 (1997).
5. A.V. Gorelov, L.N. Vasil'eva, A. du Chesne, E.G. Timoshenko, Yu.A. Kuznetsov, K.A. Dawson. "Analysis of dynamic light scattering of poly(Nisopropylacrylamide) across the collapse transition." Il Nuovo Cimento, Vol. D 16, No 7, pp. 711720 (1994).