Quantum Mechanics: Symbolism of Atomic Measurements, Band 1

Cover
Springer Science & Business Media, 2001 - 484 Seiten
Julian Schwinger had plans to write a textbook on quantum mechanics since the 1950s when he was teaching the subject at Harvard University regularly. * t Roger Newton remembers: [A] group of us (Stanley Deser, Dick Arnowitt, Chuck Zemach, Paul Martin and I forgot who else) wrote up lecture notes on his Quantum Mechanics course but he never wanted them published because he "had not yet found the perfect way to do quantum mechanics. " The only text of those days that got published eventually - following a sug gestion by, and with the help of, Robert Kohler:!: - were the notes to the lectures that Schwinger presented at Les Houches in 1955. The book was reissued in 1991, with this Special Preface by Schwinger [3]: The first two chapters of this book are devoted to Quantum Kine matics. In 1985 I had the opportunity to review that development in connection with the celebration of the 100th anniversary of Hermann Weyl's birthday. [ . . . ] In presenting my lecture [4] I felt the need to alter only one thing: the notation. Lest one think this rather triv ial, recall that the ultimate abandonment, early in the 19th century, of Newton's method of fluxions in favor of the Leibnizian calculus, stemmed from the greater flexibility of the latter's notation.
 

Inhalt

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1
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27
III
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IV
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V
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VI
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VII
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VIII
46
LXII
239
LXIII
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LXIV
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LXV
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LXVI
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LXVII
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LXVIII
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LXIX
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IX
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XIV
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XV
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XVI
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XIX
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L
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LI
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LII
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LIII
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LVI
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LIX
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LX
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LXX
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LXXX
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LXXXIV
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LXXXIX
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XC
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XCI
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XCII
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XCIV
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XCV
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XCVI
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XCVIII
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XCIX
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C
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CI
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CII
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CIII
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CIV
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CVI
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CIX
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Keine Leseprobe verfügbar - 2011

Häufige Begriffe und Wortgruppen

2mel Aa(r action principle adjoint Ai(o algebraic amplitude analogous angle angular momentum approximation arbitrary asymptotic atoms b₁ beam classical physics commutation relations components consider constant cos² Coulomb degree of freedom differential equation dt dt eigenvalues eigenvectors electron energy equations of motion Evaluate example expectation value f(dr factor gives Hamilton operator Hamiltonian Hermitian operator identical particles infinitesimal integral interaction j₁ J₂ k₁ Lagrangian linear magnetic field matrix measurement symbols microscopic multiplication n₁ obeys orthonormal oscillator particles photon physical properties polynomials potential probability probability amplitude Problem produced quantum mechanics quantum number result rotation Schrödinger equation Show sin(wt sin² situation spin Stern-Gerlach Stern-Gerlach experiment symmetrical t₁ t₂ transformation function unitary operator variables vector Verify wave function write Ze² zero ән

Verweise auf dieses Buch

Autoren-Profil (2001)

Julian Schwinger, an American physicist, developed his prowess for mathematics and physics at a very early age. At the age of 17, he received his B.A. from Columbia University and his Ph.D. three years later. By 1946 Schwinger had become a full professor at Harvard University. Schwinger's most notable contribution to physics was uniting electromagnetic theory and quantum dynamics into the theory of quantum electrodynamics (the foundations of which had been laid by Paul Dirac, Werner Heisenberg, and Wolfgang Pauli). During World War II, Schwinger, Richard Feynman, Sin-Itiro Tomonaga, and Frank Dyson developed the mathematical formulation of quantum electrodynamics to conform with Albert Einstein's theory of relativity. This new theory, which proved to be useful in measuring and explaining the behavior of atomic and subatomic particles, resulted in a Nobel Prize in physics for Feynman and Tomonaga in 1963. Schwinger also conducted significant research into the properties of synchrotron radiation, produced when a rapidly moving charged particle is diverted by a magnetic field.

Bibliografische Informationen

TitelQuantum Mechanics: Symbolism of Atomic Measurements, Band 1
Physics and astronomy online library
Autor/inJulian Schwinger
HerausgeberBerthold-Georg Englert
Ausgabeillustriert
VerlagSpringer Science & Business Media, 2001
ISBN3540414088, 9783540414087
Länge484 Seiten
  
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