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Jerzy Karpiuk Photochemistry and Spectroscopy Laboratory, IPC PAS karpiuk@ichf.pl

Forgotten experiments and the Planck’s radiation formula. On the experimenal context at the birth of quantum physics. Jerzy Karpiuk Photochemistry and Spectroscopy Laboratory, IPC PAS karpiuk@ichf.edu.pl. 14.12.1900 – birth date * of quantum theory.

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Jerzy Karpiuk Photochemistry and Spectroscopy Laboratory, IPC PAS karpiuk@ichf.pl

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  1. Forgotten experiments and the Planck’s radiation formula.On the experimenal context at the birth of quantum physics. Jerzy KarpiukPhotochemistry and Spectroscopy Laboratory, IPC PAS karpiuk@ichf.edu.pl

  2. 14.12.1900 – birth date* of quantum theory "Das war eine rein formale Annahme, und ich dachte mir eigentlich nicht viel dabei, sondern eben nur das, dass ich unter allen Umständen,koste es, was es wolle, ein positives Resultat herbeiführen musste.” (1931) „It was a purely formal assumption and I really did not give it much thought except that no matter what the cost, I must bring about a positive end.” (1931) Max Karl Ernst Ludwig Planck (1858 –1947) * A. Sommerfeld, Atombau und Spektrallinien, 1919, p. 4

  3. Traditional point of view „It is rare in any form of progress or in any discovery that the success can be with truth attributed to one man... But of Planck it can be said, and it is universally true that the formation of the quantum theory is his alone.” H. T. Flint, Nature 181 (1958) 1098 „It is rare in any form of progress or in any discovery that the success can be with truth attributed to one man... But of Planck it can be said, and it is universally true that the formation of the quantum theory is his alone.” H. T. Flint, Nature 181 (1958) 1098 „Planck’s unique position is best illustrated by what is in my opinion the singular fact that he had no precursors or competitors whose thoughts moved in a similar direction.” E. Segrè, Phys. Bl. 23 (1967) 62 „Did Planck create them out of nothing?” H. Kangro, Early History of Planck’s Radiation Law (1976) p. 1

  4. Planck’s opinion ... M. Planck on the nomination for the Nobel Prize in physics for 1908: „It was not so that theoretical work paved the way for the experimental studies; more correctly is to say it was just the opposite." The Prize was then to be shared by „a leading theoretician and a leading experimentalist, in this caseperhaps Lummer". R. Torge: Otto Lummer, Fritz Reiche, Mieczysław Wolfke: Szkice biograficzne. Postępy Fizyki53 (2002) 201 „It seems as if the formula, once put in mathematical form, survived quite well, whereas the experiments on which it was first founded have relatively rapidly fallen into oblivion.” H. Kangro, Early History of Planck’s Radiation Law, 1976, p. 2

  5. „Rosencrantz i Guildenstern are dead” One of the great anticlimaxes in all of literature occurs at the end of Shakespeare’s Hamlet. On stage strewn with noble and heroic corpus —Hamlet, Laertes, Claudius, and Gertrude — the ambassadors from England arrive and announce that “Rosencrantz and Guildenstern are dead”. No one cares. A similar reaction might be produced among a group of physicists, or even among historians and philosophers of science, were someone to announce that “Lummer and Pringsheim are dead”. Jeden z największych zawodów w całej literaturze występuje pod koniec „Hamleta” Szekspira. Na scenę usłaną ciałami bohaterów – Hamleta, Laertesa, Klaudiusza i Gertrudy wkraczają ambasadorowie z Anglii I zawiadamiają, że “Rosenkranz i Guildestern nie żyją”. Nikt się tym nie przejmuje. Podobna reakcja mogłaby wystąpić wśród fizyków lub nawet historyków i filozofów nauki, gdyby ktoś zawiadomił, że “Lummer i Pringsheim nie żyją”. Allan Franklin, The Neglect of Experiment, 1986

  6. Kirchhoff’s problem – 1860 G. Kirchhoff: Über das Verhältnis zwischen dem Emissionsvermögen und dem Absorptions-vermögen der Körper für Licht und Wärme, Annalen der Physik 19 (1860) 275.

  7. Kirchhoff’s black body definition:a(ν,T) = 1 • Experimental problems: • radiation source • detector • method of spectral measurements When a space is surrounded by bodies of the same temperature, and no rays can penetrate through these bodies, every ray in the interior of the space is so constituted, with respect to its quality and intensity, as if it proceeded from a perfectly black body of the same temperature, and is therefore independent of the nature and form of the bodies, and only determined by the temperature.” G. Kirchhoff, Annalen der Physik 19 (1860) 275.

  8. Radiant heat: in the search for u(ν,T) Frederick William Herschel (1738-1822 ) 1800 – discovery of infrared radiation

  9. John Tyndall (1820- 1893) Refraction spectra visible radiation invisibleradiation red blue J. Tyndall, 1864: rock salt prism + thermopile electric carbon arc light spectrum Shift of the maximum with temperature F. W. Herschel, 1800: prism (glass) + thermometer J. H. Müller, 1859: rock salt prism + thermopile André P. P. Crova (1833- 1907) Light sources in order of increasing temperature: stearin candle,coal gas flame,electric arc light,sun

  10. Thermo-electric pile (1860-s) bismuth antimony "My assistant stands several feet off. I turn the thermopile towards him. The heat from his face, even at this distance, produces a deflection of 90 degrees [on the galvanometer dial]. I turn the instrument towards a distant wall, judged to be a little below the average temperature of the room. The needle descends and passes to the other side of zero, declaring by this negative deflection that the pile feels the chill of the wall." J. Tyndall, Heat considered as a mode of motion, 1864, Six lectures on light , 1872-3

  11. J. Stefan (1879) + L. Boltzmann (1884) = Stefan-Boltzmann law Stefan-Boltzmann law • Deduced by J. Stefan from J. Tyndall’s experiments • L. Boltzmann derived theoretically the law studying a heat engine with light as a working matter „From weak red heat (about 525 C) to complete white heat (about 1200 C) the intensity of radiation increases from 10.4 to 122, thus nearly 12-fold (more precisely 11.7). The ratio of the absolute temperature 273 + 1200 and 273 + 525 raised to the fourth power gives 11.6.” J. Stefan, Über die Beziehung zwischen der Wärmestrahlung und der Temperatur, Mathemat. –Naturwiss. Classe Abteilung 279 (1879), pp. 391–428.

  12. Samuel P. Langley’s bolometer - 1878 Bolometerimproved resistance thermometer1880: T  10-5 °C, ± 1% Two platinum strips, covered with lampblack, one strip was shielded from the radiation and one exposed to it. The strips formed two branches of a Wheatstone bridge which was fitted with a sensitive galvanometer and connected to a battery. „Langley's bolometer was so sensitive that it could detect thermal radiation from a cow a quarter of a mile away.”

  13. Bolometer in the service of photometry 0°C – 10 m100 °C – 7.5 m Michelson equation (1887) described well Langley’s results. In the derivation Michelson used Maxwell’s velocity distribution law. „...we are facing a big problem, awaiting for solution. I mean the relationship between the temperature and radiation, as we do know virtually nothing about the issue, but once we know it, we will have a new view on almost all the processes occurring in nature.” S. P. Langley, 1889 (S. Barr, Am. J. Phys.28 (1960) 42) W. Michelson, J. de Phys. 6 (1887) 467.

  14. Platinum plate 1 cm2 with Tm Pt (2042 K) (1884) Hefner candle, standard in Germany (1883 – 1947)(amyl acetate, PTR) sensitive to fluctuations in air humidity A search for reliable luminosity standard Competition between electrical and gas lighting Light sources of that time (incandescent lamp [1879] of gas lamp radiated a lot of energy in the invisible part of the spectrum –radiometry must have been developed. • Carcel lamp, standard in France(rapeseed oil - 42 g/h)

  15. The place of birth of quantum physics: Physikalisch-Technische Reichsanstalt 1887H. von Helmholtz PTR Observatory (clock hall) and not the lecture room of the Physical Institute at Berlin’s University

  16. 1898 Act on electrical units We Wilhelm, by the grace of God German Emperor, King of Prussia, etc. do order in the name of the German Empire… The Ohm is a unit of electrical resistance. It is equal to the resistance of a mercury column at a temperature of melting ice, with a length, at consistently identical cross section of 1 mm2, of 106.3 cm, and a mass of 14,4521 gram. PTR, 1898

  17. Radiation Laboratory at PTR Lummer-Broduhn spectral bolometer surface bolometer

  18. The purpose of optical studies is to confirm the fundamental laws of heat and light radiation. Development of detection techniques Lummer’s bolometr: T  10-7 °C, ± 1% PTR Report 1899/1900:

  19. Microstructural detectors (1890-s)

  20. Ferdinand Kurlbaum 1857 - 1927 Otto Lummer 1860 - 1925 Ernst Pringsheim 1859 - 1917 Heinrich Rubens 1865 - 1922 Friedrich Paschen 1865 - 1947 Wilhelm Wien 1864 - 1928

  21. J. Stefan (1879) + L. Boltzmann (1884) = Stefan-Boltzmann law Radiation laws • W. Wien (1893) - Wien displacement law • W. Wien (1896) - Wien law (until mid 1900 in agreement with experimental data) Stefan-Boltzmann law confirmed up to ± 1% (surface bolometer) Wien displacement law confirmed (linear bolometer)

  22. Wien law - 1896 W. Wien, Annalen der Physik 58 (1896) 662.

  23. Initially the importance of „blackness” of the bodies for emitted radiation was neglected.(„man hat überhaupt außer acht gelassen”) As black bodies blackened metal plates were used that can be used as black bodies only in a limited T range (Ch. Christiansen, 1880) Wien i Lummer (1895): „we have to abandon these artificially blackened plates”: (“man muß überhaupt von den künstlich geschwärzten Blechen absehen” und stattdessen “die Strahlung eines schwarzen Körpers als den Zustand des Wärmegleichgewichts aufzufassen... Um hierauf auch eine praktisch brauchbare Methode zu gründen, durch die man die Strahlung eines schwarzen Körpers in beliebiger Annäherung herstellen kann, muss man einen Hohlraum auf gleichmässige Temperatur bringen und durch die Öffnung seine Strahlung nach aussen gelangen lassen”.) Should black body be black? W. Wien, O. Lummer, Annalen der Physik56 (1895) 453.

  24. O. Lummer & E. Pringsheim: 1895 - 1898 liquid air boiling water boiling niter hot gas -188°C 680°C 1200°C • Cavities: • cylindrical and spherical, metal • double-wall, spherical, porcelain • surface blackened with lampblack, FeO or UO2 100°C D. Hoffmann, On the Experimental Context of Planck’s Foundation of Quantum Theory, 2000

  25. Electrically annealed black body(Lummer & Kurlbaum, 1898) 4 cm 40 cm Black body: platinum plate 0,01 mm 100 A / 1500°C graphite - 2100°C (1903) Lummer:Betriebsblindheitprofessional blindness W. Wien, O. Lummer, Annalen der Physik56 (1895) 453.

  26. H. J. Kostkowski, R. D. Lee, Theory and methods of optical pyrometry, NBS Special Publication 300: Precision measurements and calibration. Temperature, Washington 1968, p. 361

  27. Precision measurements of black body spectrum Tests of Wien energy distribution law (since 1899 - Wien-Planck e.d.l.) Spectrobolometer

  28. Deviations from Wien distribution Feb. 1899:measurements up to 6 m, T: 800 - 1400°C„indicate small deviations from Wien-Planck distribution” O. Lummer, E. Pringsheim, Verh. Deutsch. Phys. Gesell. 1 (1899) 36.

  29. Deviations from Wien distribution Nov. 1899: measurements up to 8,3 m, T up to 1650°C:„the discrepances between the theory and experiment are of systematic nature” O. Lummer, E. Pringsheim, Verh. Deutsch. Phys. Gesell. 1 (1899) 226.

  30. Wien law is not generally valid, but … justified Feb. 1900: in mesurements up to 18 m, T up to 1772°C: „the differences between the theory and experiment reached 50%” Feb. 1900: being aware of the above, Planck publishes justification of Wien law using a non-mechanistic, purely thermodynamic approach to the radiation field O. Lummer, E. Pringsheim, Verh. Deutsch. Phys. Gesell. 2 (1900) 163. M. Planck „Entropie und Temperatur strahlender Wärme”, Annalen der Physik 1 (1900) 719.

  31. Entropy and energy of a system of n „resonators” M. Planck „Entropie und Temperatur strahlender Wärme”, Annalen der Physik 1 (1900) 719.

  32. Wien (PTR, 1896) Thiesen (PTR, Feb. 1900) Lummer & Pringsheim (PTR, Feb. 1900) Planck (Oct. 19, 1900) Equations

  33. Deviations from Wien distribution H. Rubens i F. Kurlbaum, Oct. 1900 Reststrahlen-method: measurements up to 50 m. Clear divergences from Wien distribution. (die Abweichungen lassen sich nicht wegdiskutieren)

  34. 19 Oct. 1900

  35. Feb. 1900 Planck, 19 Oct. 1900 Un, dUn and ΔUn are not sufficient to calculate dSn U is needed! Wien Planck M. Planck „Über eine Verbesserung der Wien’schen Spektralgleichung”, Verh. Deutsch. Phys. Gesell. 2 (1900) 202.

  36. Planck, 19 Oct. 1900 «…at last I reached the point of constructing an absolutely arbitrary expressions for entropy which, though more complicated than the Wien’s expression, seems to satisfy with the same perfection every requirement of the thermodynamic and electromagnetic theories.» M. Planck „Über eine Verbesserung der Wien’schen Spektralgleichung”, Verh. Deutsch. Phys. Gesell. 2 (1900) 202.

  37. Planck, 14 Dec. 1900 Discretization procedure M. Planck „Zur Theorie des Gesetzes der Energieverteilung im Normalspectrum”, Verh. Deutsch. Phys. Gesell. 2 (1900) 237.

  38. Es wäre erhebend, wenn wir die Gehirnsubstanz auf eine Waage legen könnten, die von den theoretischen Physikern auf dem Altar dieser universellen Funktion hingeopfert wurde; und es ist dieses grausamen Opfers kein Ende abzusehen! Noch mehr: auch die klassische Mechanik fiel ihr zu Opfer, und es ist nicht abzusehen, ob. Maxwells Gleichungen der Elektrodynamik die Krisis überdauern werden, welche diese Funktion f mit sich gebracht hat. A. Einstein, 1913

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