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The Course of Theoretical Physics is a ten-volume series of books covering theoretical physics that was initiated by Lev Landau and written in collaboration with his student Evgeny Lifshitz starting in the late 1930s.

Key Information

It is said that Landau composed much of the series in his head while in an NKVD prison in 1938–1939.[1] However, almost all of the actual writing of the early volumes was done by Lifshitz, giving rise to the witticism, "not a word of Landau and not a thought of Lifshitz".[2] The first eight volumes were finished in the 1950s, written in Russian and translated into English in the late 1950s by John Stewart Bell, together with John Bradbury Sykes, M. J. Kearsley, and W. H. Reid. The last two volumes were written in the early 1980s. Vladimir Berestetskii [ru] and Lev Pitaevskii also contributed to the series. The series is often referred to as "Landau and Lifshitz", "Landafshitz" (Russian: "Ландафшиц"),[3][4] or "Lanlifshitz" (Russian: "Ланлифшиц") in informal settings.

Impact

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The presentation of material is advanced and typically considered suitable for graduate-level study.[5][6] Despite this specialized character, it is estimated that a million volumes of the Course were sold by 2005.[7]

The series has been called "renowned" in Science and "celebrated" in American Scientist.[8][9] A note in Mathematical Reviews states, "The usefulness and the success of this course have been proved by the great number of successive editions in Russian, English, French, German and other languages."[9] At a centenary celebration of Landau's career, it was observed that the Course had shown "unprecedented longevity."[10]

In 1962, Landau and Lifshitz were awarded the Lenin Prize for their work on the Course. This was the first occasion on which the Lenin Prize had been awarded for the teaching of physics.[7]

English editions

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Course of Theoretical Physics

The following list does not include reprints and revised editions.

Volume 1

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  • Landau, Lev D.; Lifshitz, Evgeny M. (1960). Mechanics. Vol. 1 (1st ed.). Pergamon Press. ASIN B0006AWV88.

Volume 1 covers classical mechanics without special or general relativity, in the Lagrangian and Hamiltonian formalisms.

Volume 2

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Volume 2 covers relativistic mechanics of particles, and classical field theory for fields, specifically special relativity and electromagnetism, general relativity and gravitation.

Volume 3

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Volume 3 covers quantum mechanics without special relativity.

Volume 4

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The original edition comprised two books, labelled part 1 and part 2. The first covered general aspects of relativistic quantum mechanics and relativistic quantum field theory, leading onto quantum electrodynamics. The second continued with quantum electrodynamics and what was then known about the strong and weak interactions. These books were published in the early 1970s, at a time when the strong and weak forces were still not well understood. In the second edition, the corresponding sections were scrapped and replaced with more topics in the well-established quantum electrodynamics, and the two parts were unified into one, thus providing a one-volume exposition on relativistic quantum field theory with the electromagnetic interaction as the prototype of a quantum field theory.

Volume 5

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Volume 5 covers general statistical mechanics and thermodynamics and applications, including chemical reactions, phase transitions, and condensed matter physics.

Volume 6

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Volume 6 covers fluid mechanics in a condensed but varied exposition, from ideal to viscous fluids, includes a chapter on relativistic fluid mechanics, and another on superfluids.

Volume 7

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Volume 7 covers elasticity theory of solids, including viscous solids, vibrations and waves in crystals with dislocations, and a chapter on the mechanics of liquid crystals.

Volume 8

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Volume 8 covers electromagnetism in materials, and includes a variety of topics in condensed matter physics, a chapter on magnetohydrodynamics, and another on nonlinear optics.

Volume 9

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Volume 9 builds on the original statistical physics book, with more applications to condensed matter theory.

Volume 10

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Volume 10 presents various applications of kinetic theory to condensed matter theory, and to metals, insulators, and phase transitions.

See also

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Notes

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Course of Theoretical Physics

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The Course of Theoretical Physics is a ten-volume series of influential textbooks that systematically covers the foundational principles and major branches of theoretical physics, from classical mechanics to non-equilibrium processes, authored primarily by Soviet physicists Lev Davidovich Landau and Evgeny Mikhailovich Lifshitz.[1] Initiated by Landau in the late 1930s as a comprehensive educational resource for advanced students and researchers, the series emphasizes physical insight, general variational principles, and logical interconnections between topics while deliberately avoiding excessive mathematical formalism, historical narratives, or experimental details.[1] It reflects the rigorous style of the Landau school of theoretical physics and has served as a cornerstone reference for generations of physicists worldwide due to its concise yet profound treatment of core concepts.[1] The series was originally planned as nine volumes but expanded to ten, with the first English editions appearing between 1951 and 1981 through Pergamon Press (later Butterworth-Heinemann).[1] Following Landau's death in 1968, subsequent volumes were completed by Lifshitz in collaboration with Lev Petrovich Pitaevskii and Vladimir Borisovich Berestetskii, ensuring continuity with Landau's vision.[1] The volumes are:
  • Volume 1: Mechanics (L.D. Landau and E.M. Lifshitz, 1960): Foundations of classical mechanics using principles like relativity and least action.[1]
  • Volume 2: The Classical Theory of Fields (L.D. Landau and E.M. Lifshitz, 1951): Electromagnetic and gravitational fields based on special relativity.[1]
  • Volume 3: Quantum Mechanics: Non-Relativistic Theory (L.D. Landau and E.M. Lifshitz, 1958): Core non-relativistic quantum mechanics with emphasis on physical applications.[1]
  • Volume 4: Relativistic Quantum Theory (V.B. Berestetskii, E.M. Lifshitz, and L.P. Pitaevskii, 1971): Relativistic quantum field theory, including quantum electrodynamics.[1]
  • Volume 5: Statistical Physics (L.D. Landau and E.M. Lifshitz, 1951): Equilibrium statistical mechanics and thermodynamics.[1]
  • Volume 6: Fluid Mechanics (L.D. Landau and E.M. Lifshitz, 1959): Hydrodynamics of liquids and gases, including superfluidity.[1]
  • Volume 7: Theory of Elasticity (L.D. Landau and E.M. Lifshitz, 1959): Deformations in solids, with later additions on dislocations and liquid crystals.[1]
  • Volume 8: Electrodynamics of Continuous Media (L.D. Landau, E.M. Lifshitz, and L.P. Pitaevskii, 1960): Electromagnetic interactions in matter, expanded in later editions to include nonlinear optics.[1]
  • Volume 9: Statistical Physics, Part 2 (E.M. Lifshitz and L.P. Pitaevskii, 1980): Quantum statistics of condensed matter, focusing on Bose and Fermi systems.[1]
  • Volume 10: Physical Kinetics (E.M. Lifshitz and L.P. Pitaevskii, 1981): Kinetic theory of gases, plasmas, and non-equilibrium phenomena.[1]
Later editions, up to the third for some volumes, incorporated updates while preserving the original structure, and the series remains widely used in graduate education and research for its enduring clarity and depth.[1]

Introduction

Overview and Purpose

The Course of Theoretical Physics is a ten-volume series that offers a comprehensive survey of the fundamental principles and methods in theoretical physics, encompassing classical and modern topics from mechanics and field theories to quantum mechanics, statistical physics, and continuum mechanics. The volumes are structured to progress sequentially, with each building on the foundational concepts introduced earlier to foster a unified understanding of the discipline.[1] The primary purpose of the series is to deliver a rigorous, concise exposition of theoretical physics, presupposing only undergraduate-level familiarity with physics and mathematics, while prioritizing the derivation of general principles, physical insights, and problem-solving techniques over detailed historical narratives or experimental validations. This approach emphasizes logical coherence and simplicity, focusing on established theories and avoiding speculative or overly specialized applications to ensure accessibility for graduate students and researchers seeking a solid theoretical foundation.[1] Initiated by Lev Landau in the 1930s as part of his renowned "theoretical minimum" examinations—rigorous assessments designed to gauge essential knowledge in theoretical physics for aspiring students at the Institute of Physical Problems—the series embodies the core curriculum Landau deemed indispensable for theoretical work. Developed in close collaboration with Evgeny Lifshitz, it serves as an enduring pedagogical resource that interlinks diverse branches of physics into a cohesive framework.[2]

Authors and Collaboration

Lev Davidovich Landau (1908–1968) was a pioneering Soviet theoretical physicist renowned for his foundational contributions across multiple domains of the field, including superfluidity, phase transitions, and quantum liquids, for which he received the 1962 Nobel Prize in Physics.[3] In 1932, Landau established the Theoretical Department at the Ukrainian Physico-Technical Institute in Kharkov (now Kharkiv), Ukraine, where he founded the influential "Landau school" of theoretical physics, training a generation of physicists through rigorous seminars and examinations.[3] Central to his pedagogical philosophy was the "theoretical minimum," a series of demanding exams covering essential topics in mathematics and physics, designed to test deep mastery rather than rote knowledge; these exams emphasized minimalism in presentation—concise, rigorous derivations without unnecessary details—and directly shaped the stylistic approach of the Course of Theoretical Physics.[4] Evgeny Mikhailovich Lifshitz (1915–1985) served as Landau's primary collaborator on the series, contributing expertise in exposition and mathematical clarity that complemented Landau's conceptual brilliance.[5] As one of Landau's earliest PhD students, admitted in 1933 at the Kharkov institute, Lifshitz quickly became a key partner, co-authoring early papers and handling much of the drafting and refinement of the volumes' content.[5] Following Landau's severe car accident on January 7, 1962, which left him in a coma for weeks and severely impaired his ability to work, Lifshitz assumed responsibility for the bulk of the writing, revisions, and completions, ensuring the series maintained its high standards of precision and brevity.[5][3] The collaboration between Landau and Lifshitz originated in the 1930s at the Kharkov institute, where Lifshitz joined as Landau's first graduate student, and continued after Landau's relocation to Moscow in 1937 to head the Theoretical Department at the Institute for Physical Problems of the USSR Academy of Sciences.[5][3] Their partnership, marked by Landau's provision of core ideas and Lifshitz's meticulous elaboration, spanned over five decades of iterative development, beginning with initial drafts in the late 1930s and extending through multiple editions into the 1980s.[1] After Landau's death in 1968, Lifshitz collaborated with other members of the Landau school, such as Lev Pitaevskii, to finalize later volumes, incorporating updates while preserving the original minimalist rigor.[1][5]

Publication History

Original Russian Editions

The original Russian editions of the Course of Theoretical Physics were published primarily by the State Technical-Theoretical Publishing House (Gostekhizdat) in the late 1930s and 1940s, transitioning to Fizmatgiz and later Nauka as the series expanded. The project originated in the Soviet physics community, where Lev Landau sought to create a rigorous textbook series to train theoretical physicists, particularly for advancing atomic and nuclear research amid the era's scientific and industrial demands. The first volume to appear was not the inaugural one in the eventual numbering but Statistical Physics (later designated Volume 5), reflecting the non-sequential development of the work during its early phases. Volumes 6 and 7 originated from the 1944 combined publication Механика сплошных сред, separated in subsequent editions (around 1953).[6][7] Publication was significantly interrupted by World War II, with the German invasion of the Soviet Union in 1941 halting progress after the release of Volume 2; wartime conditions delayed subsequent volumes until the mid-1940s, when efforts resumed under strained resources. The series' timeline unfolded as follows:
VolumeTitle (Russian)First Publication YearPublisherNotes
5Статистическая физика1938GostekhizdatInitial volume published; focused on foundational statistical concepts.[6]
1Механика1940GostekhizdatCo-authored initially with L. M. Piatigorsky; preface dated 1938 but release delayed due to Landau's 1938 arrest and imprisonment.[8][9]
2Теория поля1941GostekhizdatReleased just before wartime disruptions; second edition in 1948.[6]
7Теория упругости1953GostekhizdatFirst separate edition; originally part of combined 1944 volume on continuous media, published during the war.[6][7]
3Квантовая механика1948GostekhizdatPost-war resumption; multiple revisions followed.[6]
6Гидродинамика1953GostekhizdatFirst separate edition; expanded from earlier continuous media notes in 1944 combined volume.[6][7]
8Электродинамика сплошных сред1957FizmatgizPart of the mid-1950s acceleration.[6]
9Статистическая физика, часть 21959FizmatgizCompanion to Volume 5.[6]
4 (Part 1)Релятивистская квантовая теория1972NaukaAuthored by V. B. Berestetskii, E. M. Lifshitz, and L. P. Pitaevskii; part of the series completed after Landau's death in 1968.[2][6]
4 (Part 2)Релятивистская квантовая теория1975NaukaCompleted by Lifshitz and Pitaevskii.[2]
10Физическая кинетика1979NaukaFirst edition; revised edition in 1988 incorporating Lifshitz's revisions after his 1985 death; marked completion of the full set.[6]
Landau's receipt of the 1962 Nobel Prize in Physics for his work on superfluidity occurred shortly after his accident, further complicating the series' momentum as collaborators like Evgeny Lifshitz assumed greater responsibility. The complete ten-volume set, spanning over 5,000 pages across editions, solidified its role as a cornerstone of Soviet theoretical physics education.[2][6]

Translations and International Editions

The English translations of the Course of Theoretical Physics began appearing in 1951 under Pergamon Press with Volume 2, with subsequent volumes following and the first complete set published by the late 1970s. These editions were primarily translated by J. B. Sykes, who served as the general editor, along with collaborators such as J. S. Bell for specific volumes like Mechanics. From the 1980s onward, publication shifted to Elsevier and its imprint Butterworth-Heinemann, which reissued the series in updated formats. The third English edition, released between 1976 and 1980, drew from the latest revised Russian editions and included enhancements such as expanded problem sets and detailed subject indices to aid pedagogical use.[1] The series has been adapted into several other languages, reflecting its global influence in physics education. The full set was translated into German as Lehrbuch der Theoretischen Physik and published by Akademie-Verlag in East Berlin, with volumes appearing from the 1960s onward. In French, it is titled Cours de physique théorique and was issued by the Soviet foreign-language publisher Éditions Mir starting in the 1970s, often in affordable paperback formats for international distribution. Chinese editions, such as the third edition of Mechanics, have been produced by domestic publishers like World Publishing Corporation, incorporating localized typesetting and terminology adjustments. Spanish versions, known as Física teórica, have been released by publishers including Reverté, with volumes like the first on mechanics available in both print and digital forms since the late 20th century. International editions sometimes feature variations to accommodate regional preferences, such as modified mathematical notation for consistency with local curricula or supplementary appendices on applications relevant to specific scientific communities. According to the preface in later volumes, the series was fully translated into six languages, while individual volumes appeared in ten additional ones, underscoring its widespread dissemination beyond the Soviet Union.

Pedagogical Approach

Theoretical Framework

The Course of Theoretical Physics establishes its unified conceptual foundation through a systematic progression from Lagrangian and Hamiltonian formulations of mechanics to relativistic field theories, employing variational principles to derive fundamental equations with maximal generality and elegance. This core framework prioritizes general physical principles, such as the relativity principle and the principle of least action, to construct a cohesive structure that avoids unnecessary complications and emphasizes the interconnectedness of physical laws across domains. By grounding the exposition in these principles, the series fosters a deep appreciation for the logical architecture of theoretical physics, treating it as a single, evolving discipline rather than isolated topics.[10][11] A hallmark of this foundation is the emphasis on symmetry as the origin of conservation laws, deriving quantities like energy, momentum, and angular momentum directly from spacetime invariances such as time translation, spatial translation, and rotational symmetry, rather than presenting them as disparate postulates. This approach, which implicitly aligns with the logic of Noether's theorem through case-by-case derivations, underscores the series' commitment to conceptual clarity and the avoidance of ad hoc assumptions, focusing instead on universal principles that reveal the underlying unity of classical and quantum phenomena. Such derivations not only simplify proofs but also highlight how symmetries dictate the form of physical laws, providing a robust scaffold for transitioning from classical to quantum realms.[11] The logical progression of the volumes reflects this framework: volumes 1 and 2 lay the classical groundwork in mechanics and field theory, volumes 3 and 4 extend to non-relativistic and relativistic quantum theory, and volumes 5 through 10 explore many-body systems, statistical mechanics, and continua such as fluids, elastic media, and electrodynamics. This sequence assumes active engagement from readers, who are expected to solve the challenging end-of-chapter problems to internalize the material and bridge theoretical insights with practical understanding. The series integrates exact solvable cases with scaling arguments to yield approximate yet physically revealing solutions, enabling efficient navigation of complex systems without exhaustive computation.[10][1] To support this unified presentation, the series adopts consistent notation throughout, including cgs (Gaussian) units for physical quantities and boldface type for vectors, which streamlines cross-volume references and minimizes notational distractions. While relying on mathematical tools such as tensor calculus for rigor—covered in detail under mathematical methods—the framework prioritizes physical intuition over formal proofs, ensuring that general principles guide all developments without reliance on specialized or arbitrary conventions.[12][11]

Mathematical Methods and Notation

The Course of Theoretical Physics employs a standardized notation system to maintain consistency across its volumes, facilitating clear communication of complex physical concepts. Greek letters are commonly used to denote fields, such as ϕ\phi for the scalar potential, and for specific indices like spin components α,β\alpha, \beta. Operators are consistently marked with circumflexes (hats), as in H^\hat{H} for the Hamiltonian. Index conventions distinguish between Latin letters (e.g., i,ki, k) for vector components and Greek letters (e.g., μ,ν\mu, \nu) for tensor indices in three or four dimensions, with Einstein summation convention implied over repeated indices to streamline tensorial expressions.[13][14] Mathematical methods in the series emphasize powerful analytical tools tailored to theoretical physics problems. Green's functions are extensively applied to solve linear differential equations in field theories and boundary value problems, providing integral representations for responses to sources. Perturbation theory forms a core technique for handling weakly interacting systems, enabling systematic expansions around unperturbed solutions in both classical and quantum contexts. Dimensional analysis is routinely invoked to identify scaling relations and validate derivations, underscoring the physical dimensions underlying equations. Each chapter concludes with advanced problems that challenge readers to apply these methods to develop problem-solving proficiency.[13][12] Derivations follow a step-by-step yet concise style, balancing rigor with brevity to highlight essential logical progressions. Proofs prioritize symmetry principles, such as invariance under transformations, over lengthy algebraic manipulations, allowing elegant resolutions to otherwise cumbersome calculations—for instance, using rotational or Lorentz symmetry to constrain forms of equations. This approach extends briefly to applications like Lagrangian formulations in mechanics. Appendices in each volume detail requisite special functions, including Bessel functions Jn(x)J_n(x) and Legendre polynomials Pl(cosθ)P_l(\cos\theta), with asymptotic behaviors and integral representations to support derivations throughout the text.[12]

Volumes

Volume 1: Mechanics

Volume 1 of the Course of Theoretical Physics, titled Mechanics, lays the groundwork for the entire series by presenting the fundamentals of classical mechanics in a rigorous, analytical framework. Authored primarily by Lev Landau with contributions from Evgenii Lifshitz, this 169-page volume emphasizes the transition from Newtonian descriptions to more advanced variational and Hamiltonian methods, suitable for advanced undergraduates and graduate students in physics.[15] The text assumes familiarity with basic calculus and vector analysis but derives key principles from first principles, such as Galileo's relativity principle and Hamilton's principle of least action, to formulate the equations of motion for systems of particles.[16] It systematically covers Newtonian mechanics before delving into conservation laws, which are derived as consequences of symmetries in the Lagrangian, highlighting Noether's theorem in a concise manner without explicit proof. The core of the volume focuses on the Lagrangian formulation, where generalized coordinates are introduced to handle constraints efficiently, leading to Lagrange's equations of the second kind:
ddt(Lq˙i)Lqi=0, \frac{d}{dt} \left( \frac{\partial L}{\partial \dot{q}_i} \right) - \frac{\partial L}{\partial q_i} = 0,
with L=TVL = T - V as the Lagrangian, kinetic energy TT, and potential VV. This approach unifies the treatment of diverse systems, from particles in potentials to rigid bodies, where the dynamics of rotation is analyzed using Euler angles and the inertia tensor. Conservation laws for energy, linear momentum, and angular momentum are explored, with applications to central force problems and reduced mass systems. The integration of equations of motion is illustrated through examples like the Kepler problem, emphasizing integrable systems and action-angle variables. Rigid body dynamics receives dedicated attention, including the stability of rotation about principal axes and the tennis racket theorem as a demonstrative example of intermediate axis instability.[16] Shifting to Hamiltonian mechanics, the text introduces canonical coordinates (q,p)(q, p), where the Hamiltonian H(q,p)H(q, p) generates the dynamics via Hamilton's equations:
q˙i=Hpi,p˙i=Hqi. \dot{q}_i = \frac{\partial H}{\partial p_i}, \quad \dot{p}_i = -\frac{\partial H}{\partial q_i}.
This formulation facilitates canonical transformations, preserved through generating functions, and Poisson brackets, defined as
{A,B}=i(AqiBpiApiBqi), \{A, B\} = \sum_i \left( \frac{\partial A}{\partial q_i} \frac{\partial B}{\partial p_i} - \frac{\partial A}{\partial p_i} \frac{\partial B}{\partial q_i} \right),
which underpin symmetries and constants of motion. The Hamilton-Jacobi equation,
St+H(q,Sq)=0, \frac{\partial S}{\partial t} + H\left(q, \frac{\partial S}{\partial q}\right) = 0,
is solved for separable systems, enabling complete integration and the identification of action variables. Small oscillations around equilibrium are treated via normal mode analysis, diagonalizing the quadratic forms for coupled oscillators to reveal frequencies and modes. The volume introduces phase space as the (q,p)(q, p) manifold, where Liouville's theorem asserts the incompressibility of phase flow, ρt=0\frac{\partial \rho}{\partial t} = 0 for the density ρ\rho, laying conceptual groundwork for later statistical treatments.[16] Throughout, over 150 problems reinforce the material, ranging from derivations to applications in celestial mechanics and vibrations. This discrete-system focus extends naturally to continuous media in Volume 2.

Volume 2: The Classical Theory of Fields

Volume 2 of the Course of Theoretical Physics, titled The Classical Theory of Fields, develops the foundations of relativistic classical field theory, extending the non-relativistic mechanics from Volume 1 to incorporate special relativity and continuous fields, particularly electromagnetic ones.[17] This volume emphasizes the covariant formulation of physical laws, enabling a unified treatment of particles and fields under Lorentz transformations, and serves as essential preparation for subsequent volumes on quantum and relativistic theories. Spanning approximately 400 pages, it includes over 200 problems designed to reinforce conceptual and computational skills, with solutions often requiring application of the derived principles. The treatment begins with special relativity kinematics, establishing the principle of relativity and the invariance of physical laws across inertial frames. Four-vectors are introduced as the natural objects for describing events, velocities, and forces in spacetime, ensuring Lorentz covariance. The Lorentz transformations form the core of this section, given by
x=γ(xvt),t=γ(tvxc2), x' = \gamma (x - vt), \quad t' = \gamma \left( t - \frac{vx}{c^2} \right),
where γ=(1v2/c2)1/2\gamma = (1 - v^2/c^2)^{-1/2}, illustrating the mixing of space and time coordinates and the relativity of simultaneity.[17] These transformations are derived from the constancy of the speed of light and the linearity of coordinate changes, leading to the Minkowski metric ds2=c2dt2dx2dy2dz2ds^2 = c^2 dt^2 - dx^2 - dy^2 - dz^2. Relativistic mechanics of particles follows, generalizing Newton's laws to include relativistic energy E=γmc2E = \gamma m c^2 and momentum p=γmv\mathbf{p} = \gamma m \mathbf{v}, with the four-momentum pμ=(E/c,p)p^\mu = (E/c, \mathbf{p}) conserved in the absence of external forces. In the non-relativistic limit, these reduce to the formulations in Volume 1, recovering classical energy and momentum for vcv \ll c.[17] Electromagnetic fields are analyzed next, starting from the relativistic perspective rather than the historical three-vector form. The electromagnetic field tensor FμνF^{\mu\nu} encapsulates electric and magnetic fields, with Maxwell's equations expressed covariantly as μFμν=(4π/c)jν\partial_\mu F^{\mu\nu} = (4\pi/c) j^\nu and λFμν+μFνλ+νFλμ=0\partial_\lambda F_{\mu\nu} + \partial_\mu F_{\nu\lambda} + \partial_\nu F_{\lambda\mu} = 0, where jνj^\nu is the four-current. Field potentials Aμ=(ϕ/c,A)A^\mu = (\phi/c, \mathbf{A}) are introduced, satisfying Fμν=μAννAμF^{\mu\nu} = \partial^\mu A^\nu - \partial^\nu A^\mu, and gauge invariance is highlighted, allowing transformations AμAμ+μΛA^\mu \to A^\mu + \partial^\mu \Lambda without altering physical observables. This gauge freedom simplifies the equations in the Lorenz gauge μAμ=0\partial_\mu A^\mu = 0.[17] The energy-momentum tensor TμνT^{\mu\nu} for the electromagnetic field is derived, given by Tμν=(1/4π)(FμλFνλ(1/4)gμνFλσFλσ)T^{\mu\nu} = (1/4\pi) (F^{\mu\lambda} F^\nu{}_\lambda - (1/4) g^{\mu\nu} F_{\lambda\sigma} F^{\lambda\sigma}), which satisfies μTμν=(1/c)Fνλjλ\partial_\mu T^{\mu\nu} = - (1/c) F^{\nu\lambda} j_\lambda and describes the flow of energy and momentum in field interactions with matter. The action principle unifies these developments, with the Lagrangian density for the electromagnetic field L=(1/16π)FμνFμν(1/c)AμjμL = -(1/16\pi) F_{\mu\nu} F^{\mu\nu} - (1/c) A_\mu j^\mu, leading to the field equations via the variation δS=0\delta S = 0 where S=Ld4xS = \int L \, d^4 x. Relativistic particle dynamics in fields is treated using the Lorentz force in covariant form dpμ/dτ=(e/c)Fμνuνdp^\mu / d\tau = (e/c) F^{\mu\nu} u_\nu, with a brief preview of the Dirac equation's role in quantizing spin-1/2 particles under these fields.[17] The 1975 revised edition incorporates clarifications and additional examples while maintaining the concise, problem-oriented style characteristic of the series.

Volume 3: Quantum Mechanics: Non-Relativistic Theory

Volume 3 of the Course of Theoretical Physics, titled Quantum Mechanics: Non-Relativistic Theory, provides a systematic exposition of non-relativistic quantum mechanics for single- and few-particle systems, building on classical mechanics from Volume 1. Authored primarily by Lev Landau with contributions from Evgeny Lifshitz, this 689-page volume emphasizes rigorous mathematical derivations and physical intuition, assuming familiarity with advanced calculus and classical physics. It comprises 18 chapters that progress from foundational principles to applications in atomic, molecular, and nuclear physics, incorporating approximately 250 problems, many with detailed solutions to reinforce conceptual understanding.[18] The volume opens with the basic concepts of quantum mechanics, including the uncertainty principle and the interpretation of the wave function as a probability amplitude. It introduces the postulate that physical observables correspond to Hermitian operators, with eigenvalues representing measurable values and eigenfunctions describing system states. The time evolution of the wave function is governed by the time-dependent Schrödinger equation,
iψt=H^ψ, i \hbar \frac{\partial \psi}{\partial t} = \hat{H} \psi,
where H^\hat{H} is the Hamiltonian operator, \hbar is the reduced Planck's constant, and ψ\psi is the wave function. This framework unifies quantum phenomena under a deterministic evolution for the probability density, contrasting with classical determinism for trajectories.[19] Central to the treatment is the time-independent Schrödinger equation for stationary states,
H^ψ=Eψ, \hat{H} \psi = E \psi,
which determines energy eigenvalues EE and eigenfunctions ψ\psi for bound systems. The volume derives solutions for key potentials, such as the harmonic oscillator and hydrogen atom, highlighting quantization rules and selection principles. Angular momentum is analyzed in depth, with the orbital angular momentum operator L^=r×p\hat{\mathbf{L}} = \mathbf{r} \times \mathbf{p} and its commutation relations [L^x,L^y]=iL^z[\hat{L}_x, \hat{L}_y] = i \hbar \hat{L}_z (cyclic permutations), leading to spherical harmonics Ylm(θ,ϕ)Y_{lm}(\theta, \phi) as eigenfunctions. For central potentials, the radial equation reduces to an effective one-dimensional problem, enabling separation of variables and computation of bound-state spectra.[18] Perturbation theory addresses systems close to exactly solvable ones, expanding energies and wave functions in powers of a small parameter λ\lambda. For non-degenerate cases, the first-order energy correction is ΔE(1)=ψ0V^ψ0\Delta E^{(1)} = \langle \psi_0 | \hat{V} | \psi_0 \rangle, where V^\hat{V} is the perturbation and ψ0\psi_0 the unperturbed state; degenerate perturbation theory resolves level splittings via secular equations. The quasi-classical approximation, or WKB method, approximates wave functions in slowly varying potentials as
ψ(x)Cp(x)exp(ixp(x)dx), \psi(x) \approx \frac{C}{\sqrt{p(x)}} \exp\left( \frac{i}{\hbar} \int^x p(x') dx' \right),
with p(x)=2m(EV(x))p(x) = \sqrt{2m(E - V(x))}, yielding quantization conditions x1x2p(x)dx=(n+1/2)π\int_{x_1}^{x_2} p(x) dx = (n + 1/2) \pi \hbar for bound states and tunneling probabilities. This connects quantum mechanics to classical turning points and adiabatic invariants, such as action variables preserved under slow changes.[19] Spin is introduced as an intrinsic angular momentum, with the Pauli spin operators satisfying σiσj=δij+iϵijkσk\sigma_i \sigma_j = \delta_{ij} + i \epsilon_{ijk} \sigma_k, enabling the Dirac equation's non-relativistic limit for electrons. The volume treats identical particles, distinguishing bosons (symmetric wave functions) and fermions (antisymmetric), with the Pauli exclusion principle arising from antisymmetrization. For two particles, the total wave function Ψ(1,2)\Psi(1,2) must satisfy exchange symmetry, impacting atomic shell structures. Applications include the helium atom's ground-state energy via variational methods and diatomic molecule binding via the Born-Oppenheimer approximation, separating electronic and nuclear motions.[18] Scattering theory covers elastic and inelastic collisions, using partial waves to expand the asymptotic wave function ψeikz+f(θ)eikr/r\psi \sim e^{ikz} + f(\theta) e^{ikr}/r. The scattering amplitude f(θ)f(\theta) relates to phase shifts δl\delta_l via f(θ)=(1/(2ik))l(2l+1)(e2iδl1)Pl(cosθ)f(\theta) = (1/(2ik)) \sum_l (2l+1) (e^{2i\delta_l} - 1) P_l(\cos \theta), with low-energy s-wave dominance for potentials. Inelastic processes, such as transitions induced by time-dependent perturbations, are treated using Fermi's golden rule for transition rates Γ=(2π/)fV^i2ρ(Ef)\Gamma = (2\pi/\hbar) |\langle f | \hat{V} | i \rangle|^2 \rho(E_f), where ρ\rho is the density of final states. Motion in magnetic fields yields Landau levels, with energy En=ωc(n+1/2)E_n = \hbar \omega_c (n + 1/2), ωc=eB/mc\omega_c = eB/mc, quantizing cyclotron orbits into degenerate bands. Polyatomic molecules and nuclear models, like the shell model, extend these ideas, emphasizing symmetry groups such as SO(3) for rotations. The revised third edition incorporates updates like Regge poles in scattering, enhancing its relevance to contemporary quantum theory.[20]

Volume 4: Relativistic Quantum Theory

Volume 4 of the Course of Theoretical Physics, titled Relativistic Quantum Theory in its first edition and Quantum Electrodynamics in the second, was co-authored by V. B. Berestetskii, E. M. Lifshitz, and L. P. Pitaevskii, continuing the series initiated by L. D. Landau. The first edition appeared in two parts: Part 1 in 1971 and Part 2 in 1974, with the Russian originals published in 1972 and 1975, respectively; the second edition, revised and expanded, was released in 1982 and spans approximately 650 pages. This volume shifts from the non-relativistic framework of Volume 3 to integrate special relativity with quantum principles, laying the groundwork for quantum field theory through a detailed treatment of relativistic wave equations and their quantization, particularly in the context of quantum electrodynamics (QED). It emphasizes invariant formulations and practical calculations, distinguishing it by its rigorous yet accessible derivation of key results for particles interacting via electromagnetic fields.[21] The book begins with the quantization of the electromagnetic field, describing photons as relativistic particles with spin 1, governed by the Maxwell equations in covariant form. It then addresses relativistic particles of spin 0, deriving the Klein-Gordon equation for scalar fields, which incorporates the relativistic energy-momentum relation E2=p2c2+m2c4E^2 = p^2 c^2 + m^2 c^4, leading to the wave equation (+m2c22)ψ=0(\square + \frac{m^2 c^2}{\hbar^2}) \psi = 0 in natural units where =c=1\hbar = c = 1. Solutions reveal negative energy states, interpreted through second quantization as particle-antiparticle pairs, with the Compton wavelength λ=hmc\lambda = \frac{h}{m c} setting the scale for relativistic quantum effects, such as pair production thresholds. For spin-1/2 particles like electrons, the volume introduces the Dirac equation, iγμμψmcψ=0i \hbar \gamma^\mu \partial_\mu \psi - m c \psi = 0, where γμ\gamma^\mu are the Dirac matrices satisfying the Clifford algebra {γμ,γν}=2gμν\{\gamma^\mu, \gamma^\nu\} = 2 g^{\mu\nu}. This first-order equation naturally yields the spinor nature and predicts the positron as a hole in the negative energy sea, providing the theoretical basis for antimatter discovery. To connect relativistic and non-relativistic descriptions, the authors discuss the Foldy-Wouthuysen transformation, a unitary operation that decouples positive and negative energy components in the Dirac Hamiltonian, yielding an effective non-relativistic Schrödinger-like equation with relativistic corrections such as spin-orbit coupling and Darwin terms. The core of the volume develops QED as the interaction between Dirac fields and the quantized photon field via minimal coupling, $ \mathcal{L} = \bar{\psi} (i \gamma^\mu D_\mu - m) \psi - \frac{1}{4} F_{\mu\nu} F^{\mu\nu} $, where Dμ=μ+ieAμD_\mu = \partial_\mu + i e A_\mu. Perturbation theory is formulated invariantly using the S-matrix, with Feynman diagrams introduced as graphical tools for computing scattering amplitudes, representing virtual particle exchanges in processes like Compton scattering and electron-positron annihilation. These diagrams facilitate the evaluation of cross-sections, such as bremsstrahlung radiation, using the operator method for high-precision results. A significant portion addresses renormalization, essential for handling ultraviolet divergences in QED loop integrals. The volume outlines the renormalization procedure by introducing counterterms for mass, charge, and field renormalizations, demonstrating how bare parameters absorb infinities to yield finite, observable predictions, as formalized in Dyson's linked-cluster expansion. Chapters on exact propagators and vertex functions detail the renormalization group flow and asymptotic behaviors at high energies, including the running of the fine-structure constant α\alpha. The book concludes with applications to hadron electrodynamics, touching on vector meson dominance, while leaving advanced topics like full weak interaction treatments to later editions or external references. Throughout, the emphasis is on conceptual clarity and computational techniques, making it a foundational text for understanding relativistic quantum field theory.[21]

Volume 5: Statistical Physics, Part 1

Volume 5 of the Course of Theoretical Physics, titled Statistical Physics, Part 1, provides a systematic development of equilibrium statistical mechanics, deriving macroscopic thermodynamic properties from microscopic quantum and classical principles. Spanning 544 pages, the volume emphasizes the foundational role of probability distributions in describing systems of many particles, bridging the non-relativistic quantum mechanics treated in Volume 3 to the study of interacting many-body systems.[22] It assumes familiarity with basic quantum many-particle concepts, such as wave functions for identical particles, to extend these into statistical treatments without delving into detailed derivations of quantum foundations. The book begins by establishing the core framework of statistical physics through the concept of phase space, which represents the configuration and momentum states of a system as points in a high-dimensional space. For classical systems, phase space volume corresponds to the number of accessible microstates, while quantum considerations discretize this into state counts. This approach underpins the microcanonical ensemble, applicable to isolated systems with fixed energy, volume, and particle number, where the entropy $ S $ emerges as $ S = k \ln \Omega $, with $ \Omega $ the phase space volume consistent with the total energy. The volume rigorously connects this to thermodynamic potentials, ensuring consistency across ensembles.[22] Central to the treatment are the canonical and grand canonical ensembles, which introduce temperature and chemical potential to model systems in contact with heat baths or reservoirs. In the canonical ensemble, for a system at temperature $ T $, the probability of a state with energy $ E_i $ is proportional to $ e^{-\beta E_i} $, where $ \beta = 1/(kT) $ and $ k $ is Boltzmann's constant. The canonical partition function is defined as
Z=ieβEi, Z = \sum_i e^{-\beta E_i},
from which the Helmholtz free energy follows as
F=kTlnZ. F = -kT \ln Z.
This free energy yields average energies, entropies, and pressures via standard thermodynamic relations, such as $ \langle E \rangle = -\partial \ln Z / \partial \beta $. The grand canonical ensemble extends this by allowing particle exchange, with the grand partition function $ \mathcal{Z} = \sum_N e^{\beta \mu N} Z_N $, where $ \mu $ is the chemical potential, enabling descriptions of systems like gases in equilibrium with a reservoir. These ensembles facilitate derivations of equation-of-state relations and response functions.[22] For quantum systems, the volume derives Fermi-Dirac and Bose-Einstein statistics from the indistinguishability of particles. Fermions obey the Pauli exclusion principle, leading to the distribution $ \langle n \rangle = 1 / (e^{\beta (\epsilon - \mu)} + 1) $ for occupation numbers, while bosons follow $ \langle n \rangle = 1 / (e^{\beta (\epsilon - \mu)} - 1) $. These are applied to ideal gases, calculating properties like pressure $ P = (2/3) (U/V) $ for non-relativistic fermions and the phenomenon of Bose-Einstein condensation below a critical temperature. The treatment highlights how quantum statistics modify classical results, particularly at low temperatures or high densities.[22] Unique to this volume is its emphasis on fluctuations and correlation functions, which quantify deviations from mean-field behavior in equilibrium. Fluctuations in energy or particle number are computed from partition function derivatives, such as the variance $ \langle (\Delta E)^2 \rangle = kT^2 C_V $, where $ C_V $ is the heat capacity, revealing the scale of statistical noise in macroscopic observables. Correlation functions, like the pair correlation $ g(r) $, describe spatial distributions and are linked to thermodynamic stability. For ideal gases, exact solutions are provided, while virial expansions address weak interactions: the pressure is expanded as $ P = (kT / v) [1 + B_2(T)/v + B_3(T)/v^2 + \cdots] $, where $ v $ is the specific volume and $ B_n $ are virial coefficients derived from cluster integrals over phase space. These concepts underscore the transition from ideal to non-ideal behavior without invoking phase transitions, which are reserved for later volumes.[22]

Volume 6: Fluid Mechanics

Volume 6 of the Course of Theoretical Physics, titled Fluid Mechanics and authored by L. D. Landau and E. M. Lifshitz, presents a rigorous treatment of hydrodynamics within the framework of theoretical physics, spanning 552 pages in its second English edition published in 1987. This volume integrates classical field theory approaches, briefly referencing concepts from Volume 2 on the classical theory of fields, to describe fluid motion as a continuum.[23] It emphasizes both non-relativistic and relativistic aspects, with applications extending to astrophysical contexts such as stellar interiors and shock propagation in cosmic plasmas. The book opens with the dynamics of ideal fluids, deriving the core equations of motion. The continuity equation governs mass conservation:
ρt+(ρv)=0, \frac{\partial \rho}{\partial t} + \nabla \cdot (\rho \mathbf{v}) = 0,
where ρ\rho denotes fluid density and v\mathbf{v} the velocity field.[23] The Euler equations describe momentum balance for inviscid, incompressible flow:
vt+(v)v=1ρp+f, \frac{\partial \mathbf{v}}{\partial t} + (\mathbf{v} \cdot \nabla) \mathbf{v} = -\frac{1}{\rho} \nabla p + \mathbf{f},
with pp as pressure and f\mathbf{f} as external forces per unit mass. For irrotational flows (×v=0\nabla \times \mathbf{v} = 0), Bernoulli's principle emerges, stating that along a streamline, 12v2+pρ+Φ=\constant\frac{1}{2} v^2 + \frac{p}{\rho} + \Phi = \constant, where Φ\Phi is the gravitational potential; this relation highlights energy conservation in steady flows.[23] A key result is Kelvin's circulation theorem, which asserts that the circulation Γ=vdl\Gamma = \oint \mathbf{v} \cdot d\mathbf{l} around a material contour in a barotropic ideal fluid remains constant in time, underscoring the inviscid conservation of vorticity. Subsequent chapters address viscous effects, introducing the Navier-Stokes equations as an extension of the Euler equations to include internal friction. For incompressible Newtonian fluids, these read:
ρ(vt+(v)v)=p+μ2v+ρf, \rho \left( \frac{\partial \mathbf{v}}{\partial t} + (\mathbf{v} \cdot \nabla) \mathbf{v} \right) = -\nabla p + \mu \nabla^2 \mathbf{v} + \rho \mathbf{f},
where μ\mu is the dynamic viscosity coefficient, capturing dissipative terms proportional to velocity gradients.[23] The volume explores viscosity's role in phenomena like Poiseuille flow in pipes and Couette flow between rotating cylinders, emphasizing energy dissipation rates such as $ \Phi = \mu \left( \frac{\partial v_i}{\partial x_j} + \frac{\partial v_j}{\partial x_i} \right)^2 / 2 $. Turbulence basics are introduced through dimensional analysis and the Reynolds number Re=ρvL/μ\mathrm{Re} = \rho v L / \mu, which delineates laminar from turbulent regimes; the book discusses Kolmogorov's scaling for energy cascades in isotropic turbulence without delving into full numerical solutions.[23] Shock waves receive detailed attention, with derivations of jump conditions across discontinuities using conservation laws for mass, momentum, and energy, leading to the Rankine-Hugoniot relations that relate pre- and post-shock states. These are applied to supersonic flows and combustion fronts, with relevance to astrophysical shocks in stellar atmospheres.[23] The text introduces magnetohydrodynamics (MHD) by incorporating electromagnetic fields into the fluid equations, yielding the induction equation B/t=×(v×Bη×B)\partial \mathbf{B}/\partial t = \nabla \times (\mathbf{v} \times \mathbf{B} - \eta \nabla \times \mathbf{B}) for magnetic diffusivity η\eta, and discussing Alfvén waves in conducting plasmas. The final sections extend to relativistic hydrodynamics, formulating the theory for perfect fluids via the energy-momentum tensor Tμν=(ϵ+p)uμuν+pgμνT^{\mu\nu} = ( \epsilon + p ) u^\mu u^\nu + p g^{\mu\nu}, where ϵ\epsilon is energy density, uμu^\mu the four-velocity, and gμνg^{\mu\nu} the metric tensor.[23] Conservation laws μTμν=0\partial_\mu T^{\mu\nu} = 0 and μ(nuμ)=0\partial_\mu (n u^\mu) = 0 (for particle number density nn) yield relativistic Euler equations, with shock wave solutions adapted for high-speed astrophysical flows. Viscous and heat-conducting extensions are briefly outlined, maintaining the volume's focus on foundational principles over exhaustive derivations.[23]

Volume 7: Theory of Elasticity

Volume 7 of the Course of Theoretical Physics provides a comprehensive exposition of the theory of elasticity, focusing on the mechanical behavior of deformable solids under various conditions. Authored by Lev Landau and Evgeny Lifshitz, this 187-page work integrates tensor analysis and thermodynamic principles to describe deformations in both isotropic and anisotropic materials, with particular emphasis on applications to crystalline structures. The text assumes small deformations and adiabatic processes, deriving key relations from energy considerations and variational methods. It includes approximately 100 problems distributed throughout the chapters to reinforce conceptual understanding and problem-solving skills.[24][25] The foundational framework begins with the definitions of stress and strain tensors. The strain tensor, which quantifies the symmetric part of the displacement gradient, is given by
ϵij=12(uixj+ujxi),\epsilon_{ij} = \frac{1}{2} \left( \frac{\partial u_i}{\partial x_j} + \frac{\partial u_j}{\partial x_i} \right),
 where uiu_i are the components of the displacement vector. This tensor captures infinitesimal deformations in the solid. The stress tensor σij\sigma_{ij} represents the internal forces per unit area, and in equilibrium without body forces, it satisfies σ=0\nabla \cdot \sigma = 0. For elastic materials, Hooke's law connects stress and strain linearly; in isotropic media, this takes the form σij=λδijϵkk+2μϵij\sigma_{ij} = \lambda \delta_{ij} \epsilon_{kk} + 2\mu \epsilon_{ij}, with λ\lambda and μ\mu as the Lamé constants determining compressibility and shear rigidity, respectively.[25][24] Extensions to crystalline solids address anisotropy, where the generalized Hooke's law involves a fourth-rank elastic modulus tensor λiklm\lambda_{iklm} relating σik=λiklmϵlm\sigma_{ik} = \lambda_{iklm} \epsilon_{lm}, with the number of independent components varying by crystal symmetry—for cubic crystals, this reduces to three parameters. Thermal effects are incorporated through expansion coefficients, such as the isotropic relation ϵii=α(TT0)\epsilon_{ii} = \alpha (T - T_0), where α\alpha is the linear thermal expansion coefficient and T0T_0 a reference temperature; anisotropic cases use a tensor form ϵik=αik(TT0)\epsilon_{ik} = \alpha_{ik} (T - T_0). These concepts apply to both single crystals and polycrystalline aggregates, elucidating phenomena like thermal stresses in heterogeneous materials. The volume derives equilibrium equations for structural elements, such as rods under torsion and bending, and plates undergoing small or large deflections, using minimum energy principles to obtain governing differential equations.[25][24] Elastic waves in solids form a central dynamic topic, propagating longitudinal and transverse modes with speeds determined by the elastic moduli and density. The wave equation ρ2uit2=σikxk\rho \frac{\partial^2 u_i}{\partial t^2} = \frac{\partial \sigma_{ik}}{\partial x_k} governs these motions, leading to discussions of surface waves (Rayleigh waves) and anharmonic vibrations that introduce nonlinear effects and energy dissipation. Dislocations, as line defects crucial for plasticity, are analyzed in detail, including edge and screw types characterized by the Burgers vector. The volume treats dislocation motion by modeling the core as a continuous distribution of infinitesimal dislocations within a periodic lattice potential, balancing misfit energy and elastic strain energy to estimate the Peierls stress—the minimum stress required to move the dislocation. This highlights the atomic-scale origins of yield strength in crystals.[25][24] Viscoelasticity extends the purely elastic framework by accounting for time-dependent responses in solids, particularly under combined thermal and mechanical loads. The volume treats viscosity through relaxation equations, such as the rate of change of the deviation tensor $ \frac{da_{ik}}{dt} + \frac{a_{ik}}{\tau} = 2\mu \frac{du_{ik}}{dt} $, where τ\tau is a relaxation time and aika_{ik} the viscous stress deviation. Thermal conduction is linked via the diffusion equation dTdt=κΔT\frac{dT}{dt} = \kappa \Delta T, with κ\kappa the thermal diffusivity, illustrating coupled thermoelastic effects like wave attenuation. Throughout, the emphasis remains on solids' static and dynamic responses, contrasting with fluid behaviors by prioritizing shear resistance and lattice effects in crystals.[25][24]

Volume 8: Electrodynamics of Continuous Media

Volume 8 of the Course of Theoretical Physics, titled Electrodynamics of Continuous Media, was authored by Lev Davidovich Landau and Evgenii Mikhailovich Lifshitz, with the second edition revised by Lev Petrovich Pitaevskii and published in 1984 by Pergamon Press (now Elsevier). This 460-page work systematically develops the theory of electromagnetic phenomena in various types of matter, building on the foundational vacuum field theory from earlier volumes to address the interactions of fields with continuous media.[26][27] The text emphasizes macroscopic descriptions, deriving the behavior of electromagnetic fields from the constitutive relations that characterize material responses, such as dielectrics, conductors, ferromagnets, and plasmas.[28] The volume opens with treatments of electrostatics in conductors and static magnetic fields, establishing the basic equations for field distributions in materials with free charges and currents. Central to the discussion is the concept of polarization in dielectrics, where the electric displacement field D\mathbf{D} relates to the electric field E\mathbf{E} via the permittivity tensor ϵij\epsilon_{ij}, accounting for anisotropic responses in crystals. Magnetization and permeability are analogously introduced for magnetic media. Maxwell's equations in matter take the form ×H=4πJ+Dt\nabla \times \mathbf{H} = 4\pi \mathbf{J} + \frac{\partial \mathbf{D}}{\partial t} and ×E=Bt\nabla \times \mathbf{E} = -\frac{\partial \mathbf{B}}{\partial t}, with D=ϵE\mathbf{D} = \epsilon \mathbf{E} and B=μH\mathbf{B} = \mu \mathbf{H}, enabling the analysis of field propagation and boundary conditions at interfaces.[29][26] A key focus is the propagation of electromagnetic waves in media, including dispersion where the permittivity depends on frequency, leading to phenomena like absorption and refractive index variation. The Fresnel equations govern reflection and refraction at dielectric boundaries, providing the amplitude transmission and reflection coefficients for plane waves incident on interfaces. Kramers-Kronig relations connect the real and imaginary parts of the dielectric function, ensuring causality in the response of matter to fields. The text extends these ideas to spatial dispersion, where permittivity varies with wave vector, and incorporates nonlinear optics in the revised edition, discussing effects like second-harmonic generation in non-centrosymmetric media.[30][26] Specialized chapters address plasmas, treated as ionized gases where collective oscillations and wave propagation are analyzed using the dielectric tensor for longitudinal and transverse modes, and superconductors, where the London equations describe perfect diamagnetism and the Meissner effect. Diffraction of X-rays in crystals is covered through dynamic theory, incorporating multiple scattering and extinction effects. Ferromagnetism and antiferromagnetism receive expanded treatment in the second edition, including spin-wave excitations and domain structures. The volume concludes with magnetohydrodynamics, integrating electromagnetic forces into fluid dynamics for conducting fluids like liquid metals. Throughout, the emphasis is on rigorous derivations from fundamental principles, with applications to optics, solid-state physics, and geophysics.[31][32][26]

Volume 9: Statistical Physics, Part 2

Volume 9 of the Course of Theoretical Physics, titled Statistical Physics, Part 2: Theory of the Condensed State, was authored by E. M. Lifshitz and L. P. Pitaevskii and published in 1980, spanning 397 pages.[33] Completed after Lev Landau's death, it extends the foundational equilibrium statistical mechanics from Volume 5 by focusing on advanced quantum aspects of condensed matter, particularly the quantum theory of superfluids, superconductors, and Fermi liquids. The volume systematically explores how macroscopic properties emerge from microscopic interactions in these systems, using Green's function methods and emphasizing low-temperature phenomena.[34] The book begins with the normal Fermi liquid, describing quasiparticle excitations in interacting Fermi systems like liquid helium-3 and metals. It introduces Green's functions for Fermi systems at zero temperature to compute response functions and collective modes. Superfluidity is treated in detail, covering the two-fluid model for helium-4, quantized vortices, and the Landau-Ginzburg phenomenological approach near the lambda transition. The lambda-transition in helium-4 exemplifies quantum phase coherence below Tλ2.17T_\lambda \approx 2.17 K, with zero viscosity and superfluid density.[35][34] Green's functions at nonzero temperatures extend the analysis to finite-temperature effects, including thermal excitations in Fermi and Bose systems. Superconductivity is analyzed using the BCS theory framework, discussing Cooper pairs, energy gaps, and the Meissner effect in type-I and type-II superconductors. Electrons in crystal lattices cover band theory, phonons, and electron-phonon interactions leading to resistivity. Magnetism includes ferromagnetism, antiferromagnetism, and spin waves. The volume concludes with electromagnetic and hydrodynamic fluctuations, linking microscopic correlations to macroscopic noise in condensed matter. Throughout, the focus is on rigorous quantum field-theoretic methods for many-body problems in condensed states.[34]

Volume 10: Physical Kinetics

Physical Kinetics is the tenth and final volume in the Course of Theoretical Physics series, authored primarily by Lev Landau and Evgeny Lifshitz, with completion by Lifshitz and Lev Pitaevskii following Landau's death in 1968. English edition published in 1981, this 420-page work provides a rigorous treatment of non-equilibrium statistical mechanics, focusing on the microscopic description of transport phenomena and relaxation processes in physical systems. It integrates kinetic theory with broader principles from prior volumes, such as equilibrium distributions, to analyze irreversible processes without delving into static phase transitions. The volume emphasizes practical applications, including those in semiconductors, where kinetic descriptions elucidate charge carrier dynamics under non-equilibrium conditions.[36] Central to the volume is the Boltzmann transport equation, which governs the time evolution of the single-particle distribution function f(r,p,t)f(\mathbf{r}, \mathbf{p}, t) in dilute gases and other systems:
vf+Fmpf=St{f}, \mathbf{v} \cdot \nabla f + \frac{\mathbf{F}}{m} \cdot \nabla_p f = \mathrm{St}\{f\},
where v=p/m\mathbf{v} = \mathbf{p}/m is the particle velocity, F\mathbf{F} is the external force, and St{f}\mathrm{St}\{f\} denotes the collision integral accounting for binary scattering events. This integro-differential equation, originally derived by Ludwig Boltzmann in 1872, forms the foundation for deriving macroscopic transport laws. The collision integral is evaluated using detailed balance principles, ensuring conservation of particle number, momentum, and energy during collisions. The H-theorem, also introduced by Boltzmann, proves the monotonic increase of the entropy functional H=flnfdrdpH = \int f \ln f \, d\mathbf{r} d\mathbf{p}, establishing the thermodynamic arrow of time and the approach to equilibrium in isolated systems. To obtain transport coefficients, the volume employs the Chapman-Enskog expansion, a perturbative method that assumes the distribution function deviates slightly from local equilibrium, f=f(0)+ϵf(1)+f = f^{(0)} + \epsilon f^{(1)} + \cdots, where ϵ\epsilon is a small parameter related to gradients. This yields expressions for diffusion, viscosity, and thermal conductivity; for instance, the thermal conductivity κ\kappa in a monatomic gas is κ=52kB2Tmλnvˉ\kappa = \frac{5}{2} \frac{k_B^2 T}{m} \lambda n \bar{v}, with λ\lambda the mean free path and vˉ\bar{v} the average speed, highlighting the role of microscopic scattering in macroscopic heat flow. Unique discussions include hypersonic waves, where high-frequency sound propagation involves non-equilibrium effects like viscosity and thermal conduction, leading to attenuation and dispersion beyond hydrodynamic limits. Applications extend to semiconductors, modeling electron-phonon interactions via Boltzmann kinetics to predict mobility and conductivity under electric fields.[36] The latter chapters address Fermi liquid theory, adapting kinetic methods to interacting Fermi systems like metals and liquid helium-3. Here, the transport equation is reformulated for quasiparticles, with the collision integral incorporating Pauli exclusion via Fermi-Dirac statistics. Landau's seminal 1957 theory posits that low-energy excitations in Fermi liquids behave as weakly interacting quasiparticles, enabling calculations of specific heat, electrical conductivity, and thermal resistivity that match experimental observations in metals. For example, the electrical conductivity σ=ne2τ/m\sigma = ne^2 \tau / m^*, where mm^* is the effective mass and τ\tau the relaxation time from quasiparticle scattering, underscores the theory's predictive power for non-equilibrium transport in degenerate electron gases. This framework, rooted in Landau's original formulation, provides a cornerstone for understanding kinetic processes in quantum many-body systems.[36] Later reprints and digital editions, available as of 2025, preserve the core content with minor errata corrections.[37]

Impact and Legacy

Influence on Physics Education

The Course of Theoretical Physics series by Lev Landau and Evgeny Lifshitz has profoundly shaped graduate-level physics education, serving as a cornerstone reference in curricula across numerous universities. At institutions such as the Massachusetts Institute of Technology (MIT), it is recommended for advanced quantum mechanics courses within PhD core requirements, praised for its depth suitable for students with strong foundational knowledge.[38] Similarly, the University of Chicago incorporates Volume 1 (Mechanics) in its graduate classical mechanics outlines, emphasizing its role in developing rigorous analytical skills.[39] The University of Alaska Fairbanks employs it as a key text in graduate classical mechanics syllabi, highlighting its insightful, condensed treatment of fundamental principles.[40] Often referred to as the "bible for theorists,"[41] the series provides a unified framework for theoretical physics, influencing problem sets and qualifying exams that test conceptual mastery and mathematical precision. Adopted globally in physics departments, the series has been translated into multiple languages and integrated into training programs in diverse countries, reflecting its enduring status as a standard resource for aspiring theorists. By the 2010s, digital editions became freely accessible through institutional libraries, such as at the École Polytechnique Fédérale de Lausanne (EPFL), facilitating broader dissemination and use in online learning environments.[42] Individual volumes have garnered thousands of citations in academic literature—for instance, Volume 6 (Fluid Mechanics) alone exceeds 5,600 as of 2025—underscoring its pervasive influence on pedagogical materials and research training.[43] This widespread adoption has inspired supplementary resources in theoretical physics education, promoting a concise, physicist-oriented approach over verbose expositions. As of 2025, it continues to be recommended in recent syllabi, such as the University of Alaska Fairbanks' graduate course.[40] A distinctive feature of the series is its emphasis on self-study through challenging problems that encourage independent derivation of key results, mirroring the research process and fostering deep conceptual understanding. As noted in educational analyses, Landau designed the texts to train physicists in practical problem-solving akin to active research, rather than rote learning. However, critiques highlight its high mathematical rigor, which can overwhelm beginners by assuming prior intuition and omitting detailed derivations, prompting modern adaptations like lecture supplements to ease entry for students. Despite such challenges, the series continues to cultivate generations of theorists, with its problems remaining a benchmark for assessing readiness in advanced programs.[44][10]

Academic and Scientific Reception

The Course of Theoretical Physics series by Lev Landau and Evgeny Lifshitz has received widespread acclaim in the academic community for its unparalleled depth, rigor, and systematic treatment of core theoretical concepts, serving as a foundational reference for generations of physicists. Reviewers have highlighted its excellence in distilling complex subjects into concise, insightful expositions, with one noting that the volumes provide "almost uniformly excellent" coverage suitable for advanced undergraduates and beginning graduate students.[45] The series' influence is underscored by the 1960 Lenin Prize awarded to Landau and Lifshitz for the initial volumes, recognizing their contributions to theoretical understanding. Furthermore, Landau's development of superfluidity theory, central to the series' treatment of condensed matter physics, earned him the 1962 Nobel Prize in Physics "for his pioneering theories for the condensed state of matter, particularly liquid helium." Despite its strengths, the series has faced criticisms for its terse, highly mathematical style, which assumes strong prior knowledge and can render it challenging or inaccessible for those new to the subjects.[10] This density prioritizes elegance over pedagogical hand-holding, often leaving derivations implicit or requiring supplementary resources for full comprehension. By the 2020s, certain areas, particularly relativistic quantum theory and quantum electrodynamics, have been viewed as outdated relative to modern developments in quantum field theory, such as renormalization group methods and effective field theories not covered in depth.[46] Additionally, the pre-digital-era focus excludes computational techniques and numerical methods that have become essential in contemporary theoretical physics. The scientific legacy of the series endures through its enduring frameworks, which continue to inform advancements in diverse fields. For instance, the Landau-Lifshitz formulation of nonequilibrium thermodynamics and fluctuations has been applied to black hole thermodynamics, providing tools for analyzing stability and phase transitions in gravitational systems.[47] In condensed matter physics, the series' exposition of superfluidity and related phenomena remains a cornerstone for research in quantum liquids and low-temperature systems. Revised editions, including reprints through the 2010s by publishers like Butterworth-Heinemann, have incorporated updates to bridge some gaps while preserving the original structure. Overall, the work's high citation rates in seminal papers reflect its ongoing role in shaping theoretical advancements.

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  32. Course of Theoretical Physics, Volume 9, Volume 9: Statistical ...
  33. Statistical Physics - 1st Edition - Elsevier Shop
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