Nikolay Bogolyubov was born on 21 August 1909 in
Nizhny Novgorod,
Russian Empire to
Russian Orthodox Churchpriest and
seminary teacher of
theology,
psychology and
philosophy Nikolay Mikhaylovich Bogolyubov, and Olga Nikolayevna Bogolyubova, a teacher of music. The Bogolyubovs relocated to the village of Velikaya Krucha in the
Poltava Governorate (now in
Poltava Oblast,
Ukraine) in 1919, where the young Nikolay Bogolyubov began to study physics and mathematics. The family soon moved to
Kyiv in 1921, where they continued to live in poverty as the elder Nikolay Bogolyubov only found a position as a priest in 1923.[1]
He attended research seminars in
Kyiv University and soon started to work under the supervision of the well-known contemporary mathematician
Nikolay Krylov. In 1924, at the age of 15, Nikolay Bogolyubov wrote his first published scientific paper On the behavior of solutions of linear differential equations at infinity. In 1925 he entered Ph.D. program at the Academy of Sciences of the
Ukrainian SSR and obtained the degree of
Kandidat Nauk (Candidate of Sciences, equivalent to a Ph.D.) in 1928, at the age of 19, with the doctoral thesis titled On direct methods of variational calculus. In 1930, at the age of 21, he obtained the degree of
Doktor nauk (Doctor of Sciences, equivalent to
Habilitation), the highest degree in the Soviet Union, which requires the recipient to have made a significant independent contribution to his or her scientific field.
This early period of Bogolyubov's work in science was concerned with such mathematical problems as direct methods of the
calculus of variations, the theory of
almost periodic functions, methods of approximate solution of
differential equations, and
dynamical systems. This earlier research had already earned him recognition. One of his essays was awarded the
Bologna Academy of Sciences Prize in 1930, and the author was awarded the erudite degree of doctor of mathematics. This was the period when the scientific career of the young Nikolay Bogolyubov began, later producing new scientific trends in modern mathematics, physics, and mechanics.
Since 1931, Krylov and Bogolyubov worked together on the problems of nonlinear mechanics and nonlinear oscillations. They were the key figures in the "Kyiv school of nonlinear oscillation research", where their cooperation resulted in the paper "On the quasiperiodic solutions of the equations of nonlinear mechanics" (1934) and the book Introduction to Nonlinear Mechanics (1937; translated to English in 1947) leading to a creation of a large field of non-linear mechanics.
And this can explain, as the authors believe, the need to shape the collection of problems of non-linear perturbation theory into a special science, which could be named NON-LINEAR MECHANICS.
— N. M. Krylov and N. N. Bogolyubov, New methods in non-linear mechanics, ONTI GTTI, Moscow-Leningrad, 1934
Distinctive features of the Kyiv School approach included an emphasis on the computation of solutions (not just a proof of its existence), approximations of periodic solutions, use of the invariant manifolds in the phase space, and applications of a single unified approach to many different problems. From a
control engineering point of view, the key achievement of the Kyiv School was the development by Krylov and Bogolyubov of the
describing function method for the analysis of nonlinear control problems.
In the period 1928–1973, Nikolay Bogolyubov worked in the
Institute for Theoretical Physics of the Academy of Sciences of the Ukrainian SSR holding the position of the Director of the institute since 1965. He lectured at Kyiv University in the period 1936–1959.
In evacuation (1941–1943)
After the
German attack against the
Soviet Union on 22 June 1941 (beginning of the
Great Patriotic War), most institutes and universities from the western part of Russia were evacuated into the eastern regions, far from the battle lines. Nikolay Bogolyubov moved to
Ufa, where he became Head of the Departments of Mathematical Analysis at
Ufa State Aviation Technical University and at
Ufa Pedagogical Institute, remaining on these positions during the period of July 1941 – August 1943.
Moscow (1943–?)
In autumn 1943, Bogolyubov came from evacuation to Moscow and on 1 November 1943 he accepted a position in the Department of Theoretical Physics at the
Moscow State University (MSU). At that time the Head of the Department was
Anatoly Vlasov (for a short period in 1944 the Head of the Department was
Vladimir Fock). Theoretical physicists working in the department in that period included
Dmitri Ivanenko,
Arseny Sokolov, and other physicists.
In the period 1943–1946, Bogolyubov's research was essentially concerned with the theory of
stochastic processes and
asymptotic methods. In his work[citation needed] a simple example of an
anharmonic oscillator driven by a
superposition of incoherent
sinusoidal oscillations with
continuous spectrum was used to show that depending on a specific approximation time scale the evolution of the system can be either
deterministic, or a stochastic process satisfying
Fokker–Planck equation, or even a process which is neither deterministic nor stochastic. In other words, he showed that depending on the choice of the time scale for the corresponding approximations the same stochastic process can be regarded as both dynamical and
Markovian, and in the general case as a non-Markov process. This work was the first to introduce the notion of time hierarchy in
non-equilibriumstatistical physics which then became the key concept in all further development of the statistical theory of irreversible processes.
In 1945, Bogolyubov proved a fundamental theorem on the existence and basic properties of a one-parameter integral manifold for a system of non-linear differential equations. He investigated periodic and quasi-periodic solutions lying on a one-dimensional manifold, thus forming the foundation for a new method of non-linear mechanics, the method of integral manifolds.
In 1946, he published in
JETP two works on equilibrium and non-equilibrium statistical mechanics which became the essence of his fundamental monograph Problems of dynamical theory in statistical physics (Moscow, 1946).
On 26 January 1953, Nikolay Bogolyubov became the Head of the Department of Theoretical Physics at MSU, after Anatoly Vlasov decided to leave the position on January 2, 1953.
Steklov Institute (1947–?)
In 1947, Nikolay Bogolyubov organized and became the Head of the Department of Theoretical Physics at the
Steklov Institute of Mathematics. In 1969, the Department of Theoretical Physics was separated into the Departments of Mathematical Physics (Head
Vasily Vladimirov), of Statistical Mechanics, and of Quantum Field Theory (Head
Mikhail Polivanov). While working in the Steklov Institute, Nikolay Bogolyubov and his school contributed to science with many important works including works on renormalization theory,
renormalization group, axiomatic
S-matrix theory, and works on the theory of dispersion relations.
In 1946, Nikolay Bogolyubov was elected as a Corresponding Member of the
Academy of Sciences of the Soviet Union. He was elected a full member (
academician) of the Academy of Sciences of the Ukrainian SSR and in full member of the Academy of Sciences of the USSR in 1953.
Dubna (1956–1992)
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He had two sons - Pavel and Nikolay (jr). Nikolay Boglyubov (jr) is a theoretical physicist working in the fields of mathematical physics and statistical mechanics.
Fundamental works of Nikolay Bogolyubov were devoted to asymptotic methods of nonlinear mechanics, quantum field theory, statistical field theory, variational calculus, approximation methods in mathematical analysis, equations of mathematical physics, theory of stability, theory of dynamical systems, and to many other areas.
He built a new theory of scattering matrices, formulated the concept of
microscopical causality, obtained important results in quantum electrodynamics, and investigated on the basis of the
edge-of-the-wedge theorem the dispersion relations in elementary particle physics. He suggested a new synthesis of the Bohr theory of quasiperiodic functions and developed methods for asymptotic integration of nonlinear differential equations which describe oscillating processes.
Mathematics and non-linear mechanics
In 1932–1943, in the early stage of his career, he worked in collaboration with
Nikolay Krylov on mathematical problems of nonlinear mechanics and developed mathematical methods for asymptotic integration of non-linear differential equations. He also applied these methods to problems of statistical mechanics.
In 1956, at the International Conference on Theoretical Physics in Seattle, USA (September, 1956), he presented the formulation and the first proof of the
edge-of-the-wedge theorem. This theorem in the theory of functions of several complex variables has important implications to the dispersion relations in elementary particle physics.
Statistical mechanics
1939 Jointly with
Nikolay Krylov gave the first consistent microscopic derivation of the
Fokker–Planck equation in the single scheme of classical and quantum mechanics.[4]
1946 Developed a general method for a microscopic derivation of kinetic equations for classical systems.[5][6] The method was based on the hierarchy of equations for multi-particle distribution functions known now as
Bogoliubov–Born–Green–Kirkwood–Yvon hierarchy.
1947 Jointly with
K. P. Gurov extended this method to the derivation of kinetic equations for quantum systems on the basis of the quantum BBGKY hierarchy.[7]
1947—1948 Introduced kinetic equations in the theory of
superfluidity,[8][9] computed the excitation spectrum for a weakly imperfect
Bose gas, showed that this spectrum has the same properties as spectrum of
Helium II, and used this analogy for a theoretical description of superfluidity of Helium II.
1958 Formulated a microscopic theory of
superconductivity[10] and established an analogy between superconductivity and superfluidity phenomena; this contribution was discussed in details in the book A New Method in the Theory of Superconductivity (co-authors V. V. Tolmachev and
D. V. Shirkov, Moscow, Academy of Sciences Press, 1958).
Quantum theory
1955 Developed an axiomatic theory for the
scattering matrix (S-matrix) in quantum field theory and introduced the
causality condition for S-matrix in terms of variational derivatives.
1955 Jointly with
Ostap Parasyuk proved the theorem on the finiteness and uniqueness (for renormalizable theories) of the scattering matrix in any order of perturbation theory (
Bogoliubov-Parasyuk theorem) and developed a procedure (
R-operation) for a practical subtraction of singularities in quantum field theory.[11][12]
N. M. Krylov and N. N. Bogoliubov (1934): On various formal expansions of non-linear mechanics. Kyiv, Izdat. Zagal'noukr. Akad. Nauk. (in Ukrainian)
N. M. Krylov and N. N. Bogoliubov (1947): Introduction to Nonlinear Mechanics. Princeton, Princeton University Press.
N. N. Bogoliubov,
Y. A. Mitropolsky (1961): Asymptotic Methods in the Theory of Non-Linear Oscillations. New York, Gordon and Breach.
Statistical Mechanics:
N. N. Bogoliubov (1945): On Some Statistical Methods in Mathematical Physics. Kyiv (in Russian).
N. N. Bogoliubov, V. V. Tolmachev,
D. V. Shirkov (1959): A New Method in the Theory of Superconductivity. New York, Consultants Bureau.
N. N. Bogoliubov (1960): Problems of Dynamic Theory in Statistical Physics. Oak Ridge, Tenn., Technical Information Service.
N. N. Bogoliubov (1967—1970): Lectures on Quantum Statistics. Problems of Statistical Mechanics of Quantum Systems. New York, Gordon and Breach.
N. N. Bogolubov and N. N. Bogolubov, Jnr. (1992): Introduction to Quantum Statistical Mechanics. Gordon and Breach.
ISBN2-88124-879-9.
Quantum Field Theory:
N. N. Bogoliubov, B. V. Medvedev, M. K. Polivanov (1958): Problems in the Theory of Dispersion Relations. Institute for Advanced Study, Princeton.
N. N. Bogoliubov,
D. V. Shirkov (1959): The Theory of Quantized Fields. New York, Interscience. The first text-book on the
renormalization group theory.
N. N. Bogoliubov, A. A. Logunov and I. T. Todorov (1975): Introduction to Axiomatic Quantum Field Theory.[14] Reading, Mass.: W. A. Benjamin, Advanced Book Program.
ISBN978-0-8053-0982-9.
ISBN0-8053-0982-9.
N. N. Bogoliubov, A. A. Logunov, A. I. Oksak, I. T. Todorov (1990): General Principles of Quantum Field Theory. Dordrecht [Holland]; Boston, Kluwer Academic Publishers.
ISBN0-7923-0540-X.
ISBN978-0-7923-0540-8.
Bogoliubov, N. N. (1948). "Equations of Hydrodynamics in Statistical Mechanics" (in Ukrainian)". Sbornik Trudov Instituta Matematiki AN USSR. 10: 41–59.
"On Question about Superfluidity Condition in the Nuclear Matter Theory" (in Russian), Doklady Akademii Nauk USSR, 119, 52, 1958.
"On One Variational Principle in Many Body Problem" (in Russian), Doklady Akademii Nauk USSR, 119, N2, 244, 1959.
"On Compensation Principle in the Method of Selfconformed Field" (in Russian), Uspekhi Fizicheskhih Nauk, 67, N4, 549, 1959.
"The Quasi-averages in Problems of Statistical Mechanics" (in Russian), Preprint D-781, JINR, Dubna, 1961.
"On the Hydrodynamics of a Superfluiding" (in Russian), Preprint P-1395, JINR, Dubna, 1963.
^Bogolyubov, A. N. (2009). "Nikolay Nikolayevich Bogolyubov".N. N. Bogolyubov: K 100-letiyu so dnya rozhdeniya (Joint Institute for Nuclear Research). Retrieved 8 January 2012. (in Russian)
^N. N. Bogoliubov and N. M. Krylov (1937). "La theorie generalie de la mesure dans son application a l'etude de systemes dynamiques de la mecanique non-lineaire". Annals of Mathematics. Second Series (in French). 38 (1): 65–113.
doi:
10.2307/1968511.
JSTOR1968511. Zbl. 16.86.
^N. N. Bogoliubov and
N. M. Krylov (1939). Fokker–Planck equations generated in perturbation theory by a method based on the spectral properties of a perturbed Hamiltonian. Zapiski Kafedry Fiziki Akademii Nauk Ukrainian SSR 4: 81–157 (in Ukrainian).
^N. N. Bogoliubov, O. S. Parasyuk (1955). "[A theory of multiplication of causal singular functions]". Doklady Akademii Nauk SSSR (in Russian). 100: 25–28.