Langmuir, I. (1961). The Collected Works of Irving Langmuir Volume 3: Thermionic Phenomena: Papers from 1916–1937. Pergamon Press.
Langmuir, I. (1961). The Collected Works of Irving Langmuir Volume 4: Electrical Discharges: Papers from 1923–1931. Pergamon Press.
These two volumes from Nobel Prize winning scientist Irving Langmuir, include his early published papers resulting from his experiments with ionized gases (i.e. plasma). The books summarise many of the basic properties of plasmas. Langmuir coined the word plasma in about 1928.
Hannes Alfvén won the Nobel Prize for his development of magnetohydrodynamics (MHD) the science that models plasma as fluids. This book lays down the ground work, but also shows that MHD may be inadequate for low-density plasmas such as space plasmas.
Provided strong arguments for heliocentrism and contributed valuable insight into the movement of the planets, including the first mention of their elliptical path and the change of their movement to the movement of free floating bodies as opposed to objects on rotating spheres (two of Kepler's laws). One of the most important works of the Scientific Revolution.
— (1997). The harmony of the world. Translated into English with an introduction and notes by E. J. Aiton, A. M. Duncan and J. V. Field. Philadelphia: American Philosophical Society. ISBN978-0-87169-209-2.
A landmark article of stellar physics, analysing several key processes that might be responsible for the synthesis of chemical elements in nature and their relative abundances; it is credited with originating what is now the theory of stellar nucleosynthesis.
Reference textbook on cosmology, discussing both observational and theoretical issues.
J. C. Mather; E. S. Cheng; R.E. Eplee, Jr.; R. B. Isaacman; S. S. Meyer; R. A. Shafer; R. Weiss; E. L. Wright; C. L. Bennett; N. W. Boggess; E. Dwek; S. Gulkis; M. G. Hauser; M. Janssen; T. Kelsall; P. M. Lubin; S. H. Moseley, Jr.; T. L. Murdock; R. F. Silverberg; G. F. Smoot; D. T. Wilkinson (1990). "A Preliminary Measurement of the Cosmic Microwave Background Spectrum by the Cosmic Background Explorer (COBE) Satellite". The Astrophysical Journal. 354: L37–40. Bibcode:1990ApJ...354L..37M. doi:10.1086/185717.
Reported results from the COBE satellite, which was developed by NASA's Goddard Space Flight Center to measure the diffuse infrared and microwave radiation from the early universe to the limits set by our astrophysical environment. Measurements by a Far Infrared Absolute Spectrophotometer (FIRAS) confirmed that the cosmic microwave background (CMB) spectrum is that of a nearly perfect black body with a temperature of 2.725 ± 0.002 K. This observation matches the predictions of the hot Big Bang theory extraordinarily well, and indicates that nearly all of the radiant energy of the Universe was released within the first year after the Big Bang. The first paper presents initial results; the second, final results.
Bennett, C. L.; Banday, A. J.; Górski, K. M.; Hinshaw, G.; Jackson, P.; Keegstra, P.; Kogut, A.; Smoot, G. F.; Wilkinson, D. T.; Wright, E. L. (1996). "Four-Year COBE DMR Cosmic Microwave Background Observations: Maps and Basic Results". The Astrophysical Journal. 464 (1): L1–L4. arXiv:astro-ph/9601067. Bibcode:1996ApJ...464L...1B. doi:10.1086/310075.
Presents results from the Differential Microwave Radiometer (DMR) on the COBE satellite. This maps the cosmic radiation and searches for variations in brightness. The CMB was found to have intrinsic "anisotropy" for the first time, at a level of a part in 100,000. These tiny variations in the intensity of the CMB over the sky show how matter and energy was distributed when the Universe was still very young. Later, through a process still poorly understood, the early structures seen by DMR developed into galaxies, galaxy clusters, and the large scale structure that we see in the Universe today. The first paper presents initial results; the second, final results.
Presents results from the Diffuse Infrared Background Experiment (DIRBE) on the COBE satellite. This searches for the cosmic infrared background radiation produced by the first galaxies. Infrared absolute sky brightness maps in the wavelength range 1.25 to 240 micrometres were obtained to carry out a search for the cosmic infrared background (CIB). The CIB was originally detected in the two longest DIRBE wavelength bands, 140 and 240 micrometres, and in the short-wavelength end of the FIRAS spectrum. Subsequent analyses have yielded detections of the CIB in the near-infrared DIRBE sky maps. The CIB represents a "core sample" of the Universe; it contains the cumulative emissions of stars and galaxies dating back to the epoch when these objects first began to form.
James Clerk Maxwell reviewed this work in Nature and concluded that "there can be no doubt that the name of Van der Waals will soon be among the foremost in molecular science." Johannes Diderik van der Waals received the Nobel Prize in 1910 for his work on the equation of state for gases and liquids.
Described the famous effect of splitting of spectral lines in electric fields (c.f. Zeeman effect) as predicted by Voigt. Observed the same year (1913) as Lo Surdo; the work won a Nobel Physics prize for Stark.
Einstein, A. (1916). "Strahlungs-Emission und -Absorption nach der Quantentheorie" [Radiation Emission and Absorption according to the Quantum theory]. Verhandlungen der Deutschen Physikalischen Gesellschaft (in German). 18: 318–323. Bibcode:1916DPhyG..18..318E.
—— (1916). "Zur Quantentheorie der Strahlung" [On the Quantum Theory of Radiation]. Mitteilungen der Physikalischen Gessellschaft Zürich (in German). 18: 47–62.
Herzberg, Gerhard (1939) Molecular Spectra and Molecular Structure I. Diatomic Molecules
Herzberg, Gerhard (1945) Molecular Spectra and Molecular Structure II. Infrared and Raman Spectra of Polyatomic Molecules
Herzberg, Gerhard (1966) Molecular Spectra and Molecular Structure III. Electronic Spectra of Polyatomic Molecules
This three-volume series is the classic detailed presentation of molecular spectroscopy for physicists and chemists. Herzberg received the 1971 Nobel Prize in Chemistry for his spectroscopic research on the electronic structure and geometry of molecules.
Classic (first and original) English translation: — (1914). Mathematical discourses and demonstrations, relating to Two New Sciences. Translation by Henry Crew and Alfonso de Salvio.
Recent English translation: — (1974). Two New sciences, including Centers of gravity & Force of percussion. Translated and compiled by Stillman Drake. Madison: Wisconsin University Press. ISBN978-0-299-06404-4.
Two-book treatise regarded as the founding text of fluid mechanics and hydrostatics in particular. Contains an introduction of his famous principle.
Daniel Bernoulli (1738). Hydrodynamica, sive de viribus et motibus fluidorum commentarii (in Latin). Strasbourg. English translation: Hydrodynamics and Hydraulics by Daniel Bernoulli and Johann Bernoulli (Dover Publications, 1968).
Stokes, George Gabriel (1849). "On the theory of the internal friction of fluids in motion, and of the equilibrium and motion of elastic solids". Transactions of the Cambridge Philosophical Society. 8: 287. (Presented in 1845)
Kamerlingh Onnes, H., "Further experiments with liquid helium. C. On the change of electric resistance of pure metals at very low temperatures, etc. IV. The resistance of pure mercury at helium temperatures." Comm. Phys. Lab. Univ. Leiden; No. 120b, 1911.
Kamerlingh Onnes, H., "Further experiments with liquid helium. D. On the change of electric resistance of pure metals at very low temperatures, etc. V. The disappearance of the resistance of mercury." Comm. Phys. Lab. Univ. Leiden; No. 122b, 1911.
Kamerlingh Onnes, H., "Further experiments with liquid helium. G. On the electrical resistance of pure metals, etc. VI. On the sudden change in the rate at which the resistance of mercury disappears." Comm. Phys. Lab. Univ. Leiden; No. 124c, 1911.
These three papers develop the BCS theory of usual (not high TC) superconductivity, relating the interaction of electrons and the phonons of a lattice. The authors were awarded the Nobel prize for this work.
Guth, Eugen; Hermann, Mark (1934). "Zur innermolekularen, Statistik, insbesondere bei Kettenmolekiilen I" [For the intra-molecular, statistics, especially for chain molecules I]. Monatshefte für Chemie (in German). 65 (1): 93–121. doi:10.1007/BF01522052.
Contains the foundation of the kinetic theory of rubber elasticity, including the first theoretical description of statistical mechanics of polymers with application to viscosity and rubber elasticity, and an expression for the entropy gain during the coiling of linear flexible molecules.
Guth, Eugene; James, Hubert M. (1941). "Elastic and Thermoelastic Properties of Rubber like Materials". Industrial & Engineering Chemistry. 33 (5): 624–629. doi:10.1021/ie50377a017.
Presented earlier by Guth at the American Chemical Society meeting of 1939, this article contains the first outline of the network theory of rubber elasticity. The resulting Guth-James equation of state is analogous to van der Waal's equation.
Presents a more detailed version of the network theory of rubber elasticity. The paper used average forces to some extent instead of thermodynamical functions. In statistical thermodynamics, these two procedures are equivalent. After some controversy within the literature, the James-Guth network theory is now generally accepted for larger extensions. See, e.g., Paul Flory's comments in Proc. Royal Soc. A. 351, 351 (1976).
Flory, Paul J. (1992). Principles of polymer chemistry (15. pr. ed.). Ithaca: Cornell Univ. Press. ISBN978-0-8014-0134-3.
Flory, Paul J. (1969). Statistical mechanics of chain molecules. New York: Interscience Publishers. ISBN978-0-470-26495-9.
Reissued: Flory, Paul J.; J. G. Jackson; C. J. Wood (1989). Statistical mechanics of chain molecules (Repr. corr. ed.). Hanser Gardner. ISBN978-1-56990-019-2.
Gennes, Pierre-Gilles de (1996). Scaling concepts in polymer physics (5. print. ed.). Ithaca, New York: Cornell Univ. Press. ISBN978-0-8014-1203-5.
Doi, M.; Edwards, S.F. (1988). The theory of polymer dynamics (Reprinted ed.). Oxford: Clarendon Press. ISBN978-0-19-852033-7.
Ampère, André-Marie (1826). "Théorie mathématique des phénomènes électro-dynamiques: uniquement déduite de l'expérience" [Memoir on the Mathematical Theory of Electrodynamic Phenomena, Uniquely Deduced from Experience] (in French). Méquignon-Marvis. Cite journal requires |journal= (help) Online links at Google eBooks (accessed 2010-09-26), and archived from the original at the Internet Archive.
Faraday, Michael (1839–1855). Experimental researches in electricity (Reprinted 2000 from the 1st ed. 1839 (vol. 1), 1844 (vol. 2), 1855 (vol. 3) ed.). Santa Fe (N.M.): Green Lion Press. ISBN978-1-888009-15-6.
Contains a proof of Noether's Theorem (expressed as two theorems), showing that any symmetry of the Lagrangian corresponds to a conserved quantity. This result had a profound influence on 20th century theoretical physics.
Considered a founding text in the field of Fourier analysis (and by extension harmonic analysis), and a breakthrough for the solution of the classic (partial) differential equations of mathematical physics.
A finite system of deterministic nonlinear ordinary differential equations is introduced to represent forced dissipative hydrodynamic flow, simulating simple phenomena in the real atmosphere. All of the solutions are found to be unstable, and most of them nonperiodic, thus forcing to reevaluate the feasibility of long-term weather prediction. In this paper the Lorenz attractor is presented for the first time, and gave the first hint of what is now known as butterfly effect.
The first major publication of the Royal Society. It generated a wide public interest in, and often is considered the creator of, the science of microscopy. Also notable for coining the term "biological cell".
Huygens attained a remarkably clear understanding of the principles of wave-propagation; and his exposition of the subject marks an epoch in the treatment of Optical problems. Not appreciated until much later due to the mistaken zeal with which formerly everything that conflicted with the cherished ideas of Newton was denounced by his followers.
A key publication in the history of physics, arguably Newton's second most influential physics publication after Principia. Within he describes his famous experiments regarding colour and light, and ends with a set of queries about the nature of light and matter.
Hess, V. F. (1912). "Über Beobachtungen der durchdringenden Strahlung bei sieben Freiballonfahrten" [About Observations of penetrating Radiation during seven balloon-journeys]. Physikalische Zeitschrift (in German). 13: 1084–1091.
Gives an account of the author's discovery of high energy cosmic radiation. Awarded half of the 1936 Nobel Prize in Physics.
Chadwick's experiments confirmed the identity of the mysterious particle detected independently by Joliot-Curie & Joliot, and Bothe & Becker and predicted by Majorana and others to be a neutral nucleon in 1932, for which Chadwick was awarded the Nobel Prize in Physics in 1935.
A series of three articles by Hans Bethe summarizing the knowledge in the subject of Nuclear Physics at the time of publication. The set of three articles is colloquially referred to as "Bethe's bible".
This contains an account of an experiment first suggested by Wang, confirming the existence of a particle (the neutrino, more precisely the electron neutrino) first predicted by Pauli in 1940; a result that was rewarded almost forty years later with the 1995 Nobel Prize for Reines.
J. C. Street and E. C. Stevenson. "New Evidence for the Existence of a Particle Intermediate Between the Proton and Electron", Phys. Rev. 52, 1003 (1937).
Experimental confirmation of a particle first discovered by Anderson and Neddermeyer at Caltech in 1936; originally thought to be Yukawa's meson, but later shown to be a "heavy electron", now called muon.
This important experiment on a beam of particles through a magnetic field described the experimental observation that their deflection takes only certain quantized values was important in leading to the concept of a new quantum number, spin.
de Broglie, Louis (1924). Recherches sur la théorie des quanta (in French) (Researches on the theory of quanta), Thesis, Paris. Ann. de Physique (10) 3, 22 (1925)
M. Born and P. Jordan (1925), Zur Quantenmechanik (in German), Zeitschrift für Physik, 34, 858-888 (received September 27, 1925). [English translation in: B. L. van der Waerden, editor, Sources of Quantum Mechanics (Dover Publications, 1968) ISBN0-486-61881-1 (English title: On Quantum Mechanics).]
M. Born, W. Heisenberg, and P. Jordan (1926), Zur Quantenmechanik II (in German), Zeitschrift für Physik, 35, 557-615, (received November 16, 1925). [English translation in: B. L. van der Waerden, editor, Sources of Quantum Mechanics (Dover Publications, 1968) ISBN0-486-61881-1 (English title: On Quantum Mechanics II).]
These papers introduce the wave-mechanical description of the atom (Ger Wellenmechanik; not to be confused with classical wave mechanics), inspired by the wave–particle duality hypotheses of Einstein (1905) and de Broglie (1924), among others. This was only the second fully adequate formulation of (non-relativistic) quantum theory. Introduced the now famous equation named after the author.
Performed an experiment (with Lester Germer) which observed Bragg X-ray diffraction patterns from slow electrons; later independently replicated by Thomson, for which Davisson and Thomson shared the Nobel Prize in Physics in 1937. This confirmed de Broglie's hypothesis that matter has wave-like behaviour; in combination with the Compton effect discovered by Arthur Compton (who won the Nobel Prize for Physics in 1927), established the wave–particle duality hypothesis as a fundamental concept in quantum theory.
Quantum mechanics as explained by one of the founders of the field, Paul Dirac. First edition published on 29 May 1930. The second to last chapter is particularly interesting because of its prediction of the positron.
Mathematical Foundations of Quantum Mechanics, Beyer, R. T., trans., Princeton Univ. Press. 1996 edition: ISBN0-691-02893-1.
Rigorous axiomatic formulation of quantum mechanics as explained by one of the greatest pure and applied mathematicians in modern history. In this book all the modern mathematical machinery to deal with quantum theories, such as the general notion of Hilbert space, that of self-adjoint operator and a complete general version of the spectral theory for self-adjoint unbounded operators, was introduced for the first time.
Feynman, R P (1942). "The Principle of Least Action in Quantum Mechanics". Ph.D. Dissertation, Princeton University. Reprinted as Laurie M. Brown ed., (with title Feynman's Thesis: a New Approach to Quantum Theory). World Scientific, 2005. ISBN978-981-256-380-4.
The publications formulate what became known as the Klein–Gordon equation as the first relativistically invariant Schrödinger equation (however the equation was considered contemporaneously by Schrödinger - in his personal notes - and Fock, among others).
A. Salam (1968). "Weak and Electromagnetic Interactions". In N. Svartholm (ed.). Elementary Particle Physics: Relativistic Groups and Analyticity. Eighth Nobel Symposium at Lerum, Sweden. Conf. Proc. C680519 (1968). Stockholm: Almquvist and Wiksell. pp. 367–77.
The primary sources section of the latter article in particular contains many additional (early) publications of importance in the field.
Lorentz, Hendrik (1892). "De relatieve beweging van de aarde en den aether". Zittingsverlag Akad. (in Dutch). 5 (1): 74–79.
For a translation see: [en.wikisource.org]. Hendrik Lorentz was a major influence on Einstein's theory of special relativity. Lorentz laid the fundamentals for the work by Einstein and the theory was originally called the Lorentz-Einstein theory. After 1905 Lorentz wrote several papers on what he called "Einstein's principle of relativity".
Used concepts developed in the then-current textbooks (e.g., vector analysis and non-Euclidean geometry) to provide entry into mathematical physics with a vector-based introduction to quaternions and a primer on matrix notation for linear transformations of 4-vectors. The ten chapters are composed of 4 on kinematics, 3 on quaternion methods, and 3 on electromagnetism. Silberstein used biquaternions to develop Minkowski space and Lorentz transformations. The second edition published in 1924 extended relativity into gravitation theory with tensor methods, but was superseded by Eddington's text.
A modern introduction to special relativity, that explains well how the choice to divide spacetime into a time part and a space part is no different than two choices about how to assign coordinates to the surface of the earth.
A book on gravitation, often considered the "Bible" on gravitation by researchers. Published by W.H. Freeman and Company in 1973. It covers all aspects of the General Theory of Relativity and also considers some extensions and experimental confirmation. It is divided into two "tracks", the second of which covers more advanced topics. Its massive size (over 1200 pages) has inspired nicknames such as "the phone book".
A founding text in the field of Fourier analysis, and a breakthrough for the solution of the classic (partial) differential equations of mathematical physics. Contains an annunciation of Fourier's law.
—; E. Clapeyron; R. Clausius (2005). Reflections on the Motive Power of Fire – and other Papers on the Second Law of Thermodynamics. Edited with an introduction by E. Mendoza. New York: Dover Publications. ISBN978-0-486-44641-7.
— (October 1993). The Scientific Papers of J. Willard Gibbs (Vol. 1). Ox Bow Press. ISBN978-0-918024-77-0.
— (February 1994). The Scientific Papers of J. Willard Gibbs (Vol. 2). Ox Bow Press. ISBN978-1-881987-06-2.
Between 1876 and 1878 Gibbs wrote a series of papers collectively entitled "On the Equilibrium of Heterogeneous Substances", considered one of the greatest achievements in physical science in the 19th century and the foundation of the science of physical chemistry. In these papers Gibbs applied thermodynamics to the interpretation of physicochemical phenomena and showed the explanation and interrelationship of what had been known only as isolated, inexplicable facts. Gibbs' papers on heterogeneous equilibria included: some chemical potential concepts; some free energy concepts; a Gibbsian ensemble ideal (basis of the statistical mechanics field); and a phase rule.
^* Cavendish, Henry (1798). "Experiments to Determine the Density of the Earth". In MacKenzie, A. S. (ed.). Scientific Memoirs Vol.9: The Laws of Gravitation. American Book Co. (published 1900). pp. 59–105. Online copy of Cavendish's 1798 paper, and other early measurements of gravitational constant.
^H.Weyl, Gravitation und Elektrizität. Sitzungsber. Akademie der Wissenschaften Berlin, 465-480 (1918).
^H. Grassmann (1862). Extension Theory. History of Mathematics Sources. American Mathematical Society, London Mathematical Society, 2000 translation by Lloyd C. Kannenberg.
^ abFreeman, A. (1878). The Analytical Theory of Heat, Cambridge University Press, Cambridge UK, cited by Truesdell, C.A. (1980), The Tragicomical History of Thermodynamics, 1822–1854, Springer, New York, ISBN0-387-90403-4, page 52.
^ abcdTruesdell, C.A. (1980). The Tragicomical History of Thermodynamics, 1822–1854, Springer, New York, ISBN0-387-90403-4, page 52.
^Ambartsumian and Ivanenko (1930) "Об одном следствии теории дирака протонов и электронов" (On a Consequence of the Dirac Theory of Protons and Electrons), Доклады Академии Наук СССР (Doklady Akademii Nauk SSSR / Proceedings of the USSR Academy of Sciences) Ser. A, no. 6, pages 153-155. Available in Russian on-line.