Relevant bibliographies by topics / STERN-GERLACH EXPERIMENT

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Academic literature on the topic 'STERN-GERLACH EXPERIMENT'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 February 2022

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Journal articles on the topic "STERN-GERLACH EXPERIMENT"

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Schmidt-Böcking, Horst, Lothar Schmidt, Hans Jürgen Lüdde, Wolfgang Trageser, Alan Templeton, and Tilman Sauer. "The Stern-Gerlach experiment revisited." European Physical Journal H 41, no. 4-5 (2016): 327–64. http://dx.doi.org/10.1140/epjh/e2016-70053-2.

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Tekin, Bayram. "Stern–Gerlach experiment with higher spins." European Journal of Physics 37, no. 3 (2016): 035401. http://dx.doi.org/10.1088/0143-0807/37/3/035401.

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Sulcs, S., and B. C. Gilbert. "Eddy currents in the Stern–Gerlach experiment." Canadian Journal of Physics 80, no. 10 (2002): 1121–31. http://dx.doi.org/10.1139/p02-063.

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We calculate the effects of Larmor precession in the two-state Stern–Gerlach experiment performed with silver atoms. We compare the time constants and Q factors for an oscillating magnetic-dipole moment in free space and in close proximity to an iron magnet. Numerical modelling suggests that the original Stern–Gerlach experiment was too dissipative to have eliminated classical explanations. A recent experiment, also admitting a classical interpretation, is discussed briefly. A new experiment is proposed that should be able to confirm quantum mechanics unequivocally. PACS Nos.: 03.65Bz, 41.20Gz, 32.10Dk
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Schmidt-Böcking, Horst. "The Stern-Gerlach experiment re-examined by an experimenter." Europhysics News 50, no. 3 (2019): 15–19. http://dx.doi.org/10.1051/epn/2019302.

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The historic Stern-Gerlach experiment (SGE), which was performed in 1922 in Frankfurt, is reviewed from an experimental point of view. It is shown that the SGE apparatus is a purely classical momentum spectrometer, in which the trajectories of particles are measured. With modern detection devices the passage of each single atom can be identified and its trajectory in the magnetic field precisely determined. At the time of their experiment Stern and Gerlach achieved a hitherto unprecedented momentum resolution corresponding to an energy resolution of one μeV.
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Karpa, Leon, and Martin Weitz. "A Stern–Gerlach experiment for slow light." Nature Physics 2, no. 5 (2006): 332–35. http://dx.doi.org/10.1038/nphys284.

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Devereux, Michael. "Reduction of the atomic wavefunction in the Stern–Gerlach magnetic field." Canadian Journal of Physics 93, no. 11 (2015): 1382–90. http://dx.doi.org/10.1139/cjp-2015-0031.

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Observation of two separated beam spots at a detection screen downstream of a Stern–Gerlach magnet does not, in fact, demonstrate that the wavefunction of a neutral spin one-half particle has remained in a spin superposition while traveling through that magnetic field. The wavefunction may have been reduced to just one spin-direction eigenfunction, as D. Bohm suggested, by immediate momentum and energy transfer with the magnet, rather than by subsequent, which-way determination at the screen. The same two beam spots at the detector screen will result. Einsteinian relativity, and the understanding of Schrödinger evolution applicability through a static potential, forbid continuation of a spin superposition through the Stern–Gerlach field. A calculation for single wavepacket development there conforms to observations from the Stern–Gerlach experiment. And several experiments corroborate immediate reduction to a single spin eigenfunction in the magnetic field. Additionally, Ramsey’s separated, oscillating fields observations, and related experiments, do not rebut this understanding.
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Hannout, M., S. Hoyt, A. Kryowonos, and A. Widom. "Quantum measurement theory and the Stern–Gerlach experiment." American Journal of Physics 66, no. 5 (1998): 377–79. http://dx.doi.org/10.1119/1.18876.

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Platt, Daniel E. "A modern analysis of the Stern–Gerlach experiment." American Journal of Physics 60, no. 4 (1992): 306–8. http://dx.doi.org/10.1119/1.17136.

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Muller, C. W., and F. W. Metz. "Phase-space study of the Stern-Gerlach experiment." Journal of Physics A: Mathematical and General 27, no. 10 (1994): 3511–22. http://dx.doi.org/10.1088/0305-4470/27/10/026.

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Wennerström, Håkan, and Per-Olof Westlund. "A Quantum Description of the Stern–Gerlach Experiment." Entropy 19, no. 5 (2017): 186. http://dx.doi.org/10.3390/e19050186.

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Dissertations / Theses on the topic "STERN-GERLACH EXPERIMENT"

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Oliveira, Thiago Rodrigues de. "Decoerência em uma experiência de Stern-Gerlach dissipativa." [s.n.], 2004. http://repositorio.unicamp.br/jspui/handle/REPOSIP/277303.

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Orientador: Amir Ordacgi Caldeira<br>Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Fisica Gleb Wataghin<br>Made available in DSpace on 2018-08-04T01:41:57Z (GMT). No. of bitstreams: 1 Oliveira_ThiagoRodriguesde_M.pdf: 7229972 bytes, checksum: df8825145d26326f700bc04d2d767b90 (MD5) Previous issue date: 2004<br>Resumo: Não informado<br>Abstract: Not informed.<br>Mestrado<br>Física Estatística<br>Mestre em Física
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Key, Matthew Gareth. "A miniature magnetic waveguide for cold atoms." Thesis, University of Sussex, 2000. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.326928.

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Diamantis, Nikolaos G. [Verfasser]. "Introducing quantum mechanics with the help of the Stern-Gerlach experiment at secondary high school level : (an advanced course at the high school) / Nikolaos G. Diamantis." Dortmund : Universitätsbibliothek Technische Universität Dortmund, 2004. http://d-nb.info/1011531801/34.

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Kheswa, Bonginkosi Vincent. "Deflection of Ag-atoms in an inhomogeneous magnetic field." Thesis, Stellenbosch : Stellenbosch University, 2011. http://hdl.handle.net/10019.1/17891.

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Thesis (MSc)--Stellenbosch University, 2011.<br>ENGLISH ABSTRACT: In the current design of the high temperature gas cooled reactor, a small fraction of coated fuel particles will be defective. Hence, 110Ag may be released from the fuel spheres into the coolant gas (helium) and plate out on the cooler surfaces of the main power system. This poses a radiation risk to operating personnel as well as general public. The objectives of this thesis were to design and construct an apparatus in which silver-109 atoms may be produced and deflected in an inhomogeneous and homogeneous magnetic field, compare experimental and theoretical results, and make a recommendation based on the findings of this thesis to the idea of removing silver-110 atoms from the helium fluid by deflecting them with an inhomogeneous magnetic field onto target plates situated on the inner perimeter of a helium pipe. The experimental results for the deflection of the collimated Ag- atoms with the round-hole collimators showed a deflection of 1.77° and 2.05° of the Ag- atoms due to an inhomogeneous magnetic field when the target plate was positioned 13 and 30 mm away from the magnet, respectively. These values were considerably greater than 0.01° and 0.02° that were calculated for the average velocity of atoms, v = 500 m/s. The case where Ag- atoms were collimated with a pair of slits and the target plate positioned 13mm away from the magnet showed the following: An inhomogeneous magnetic field changes the rectangular shape of the beam to a roughly elliptical shape. The beam of Ag- atoms was not split into two separate beams. This was caused by the beam of Ag- atoms consisting of atoms travelling at different speeds. The maximum deflection of Ag- atoms was 1.16° in the z direction and 1.12° in the x direction. These values were also significantly greater than 0.01 mm calculated at v = 500 m/s. This huge difference between the theoretical and experimental results raised a conclusion that the size of each Ag deposit depended mostly on the exposure time that was given to it. It was noticed that the beam of Ag- atoms was not split into two separate beams, in both cases. The conclusion was that the technique of removing Ag- atoms from the helium stream by means of an inhomogeneous magnetic field may not be effective. This is due to the inability of the inhomogeneous magnetic field to split the beam of Ag- atoms into two separate beams in a vacuum of ~10-5 mbar. It would be even more difficult for an inhomogeneous magnetic field to split the beam of Ag- atoms in helium, due to the Ag- atoms having a shorter mean free path in helium compared to a vacuum.<br>AFRIKAANSE OPSOMMING: In die huidige ontwerp van die hoë temperatuur gas afgekoelde reaktor, is 'n klein fraksie van omhulde brandstof deeltjies foutief. 110Ag kan dus vrygestel word vanaf die brandstof sfere in die verkoelingsgas (helium) wat dan op die koeler oppervlaktes van die hoofkragstelsel presipiteer. Hierdie 110Ag deeltjies hou 'n bestraling risiko vir die bedryfpersoneel sowel as vir die algemene publiek in. Die doelwitte van hierdie verhandeling is eerstens om 'n apparaat te ontwerp en konstrueer wat silwer-109 atome produseer en nie-homogene en homogene magnetiese velde deflekteer,. Tweedens om die eksperimentele en teoretiese resultate met mekaar te vergelyk. Derdens om 'n aanbeveling te maak gebasseer op die bevindinge van hierdie verhandeling rakende die verwydering van silwer-110 atome uit die helium vloeistof deur hulle met 'n nie-homogene magneetveld te deflekteer op die teikenplate binne-in 'n helium pyp. Die eksperimentele resultate vir die defleksie van die gekollimeerde Ag-atome met die ronde gat kollimators toon ‘n defleksie van 1.77° en 2.05° van die Ag-atome as gevolg van ‘n nie-homogene magneetveld wanneer die teikenplaat 13mm en 30mm, onderskeidelik, vanaf die magneet geposisioneer is. Hierdie waardes is aansienlik groter as die teoretiese defleksies van 0.01° en 0.02o wat bereken is vir ‘n gemiddelde snelheid van 500 m/s vir die atome. Die geval waar Ag-atome met 'n paar splete gekollimeer is en die teikenplaat 13 mm weg van magneet geposisioneer is, is die volgende resultate verkry: 'n nie-homogene magneetveld verander die reghoekige vorm van die bondel na 'n rowwe elliptiese vorm. Die bondel Ag-atome is nie volkome twee afsonderlike bundels verdeel nie. Dit is omdat die bondel van Ag-atome bestaan uit atome wat teen verskillende snelhede beweeg. Die maksimum defleksie van Ag-atome is 1.16° in die z-rigting en 1.12° in die x-rigting. Hierdie waardes is ook aansienlik groter as 0.01° bereken teen 500 m/s. Hierdie groot verskil tussen die teoretiese en eksperimentele resultate dui daarop dat die grootte van elke Ag neerslag grootliks afhanklik is van die blootstellingstyd wat daaraan gegee is. Daar is vasgestel dat die straal van Ag-atome in beide gevalle nie in twee afsonderlike bondels verdeel nie. Die gevolgtrekking is dat die tegniek van die verwydering van Ag-atome uit die helium stroom deur middel van 'n nie-homogene magneetveld nie effektief is nie. Dit is te wyte aan die onvermoë van die nie-homogene magneetveld om die bondel Ag-atome te verdeel in twee afsonderlike bondels in 'n vakuum van ~ 10-5 mbar. Dit sou selfs nog moeiliker vir 'n nie-homogene magnetiese veld wees om die bundel Ag-atome in helium te verdeel, weens die korter gemiddelde beskikbare pad van Ag-atome in helium wanneer dit met 'n vakuum vergelyk word.
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Rohrmann, Urban [Verfasser], and Rolf [Akademischer Betreuer] Schäfer. "Das magnetische Verhalten Mangan-dotierter Zinncluster - Der Einfluss von Topologie und Temperatur auf das Ablenkverhalten atomarer Cluster in Stern-Gerlach-Experimenten / Urban Rohrmann. Betreuer: Rolf Schäfer." Darmstadt : Universitäts- und Landesbibliothek Darmstadt, 2014. http://d-nb.info/1110979290/34.

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Rohrmann, Urban. "Das magnetische Verhalten Mangan-dotierter Zinncluster - Der Einfluss von Topologie und Temperatur auf das Ablenkverhalten atomarer Cluster in Stern-Gerlach-Experimenten." Phd thesis, 2014. https://tuprints.ulb.tu-darmstadt.de/4208/1/PhD_Thesis_Rohrmann.pdf.

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Die magnetischen Eigenschaften isolierter Mangan-dotierter Zinncluster werden in Molekularstrahl-Experimenten untersucht. Der Einfluss von Topologie und Dynamik der Cluster auf das Verhalten im inhomogenen Magnetfeld wird analysiert. Dabei erweisen sich vor allem angeregte molekulare Vibrationen der Cluster als bedeutend. Zur Aufklärung der Clusterstrukturen werden die dielektrischen Eigenschaften der Cluster untersucht und mit dem für bestimmte Isomere erwarteten Verhalten verglichen. Durch quantenchemische Rechnungen (Dichtefunktionaltheorie) werden die Grundzustandsisomere, der Spinzustand des elektronischen Grundzustands, das elektrische Dipolmoment und die elektronische Polarisierbarkeit sowie die Schwingungsspektren der Cluster ermittelt. Temperaturabhängige Messungen zeigen, dass das magnetische Ablenkverhalten der Cluster im Vibrationsgrundzustand empfindlich von der Clustergeometrie abhängt. Der Anteil vibrationsangerechter Cluster wiederrum wird einheitlich in Richtung des Feldgradienten abgelenkt.
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Käfer, Christoph Anton [Verfasser]. "Stern-Gerlach experiments with Bose-Einstein condensates and the introduction of a new thermometry method in an optical dipole trap / vorgelegt von Christoph Anton Käfer." 2010. http://d-nb.info/1006161325/34.

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Books on the topic "STERN-GERLACH EXPERIMENT"

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Levin, Frank S. Spin ½ and the Periodic Table. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198808275.003.0011.

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Some major quantal developments are described in Chapter 10. The Stern-Gerlach experiment is encountered first, wherein a beam of silver atoms is deflected by a magnetic field, leading to a pair of traces on a detecting plate. Next is the proposal that electrons have a new attribute known as spin, used to explain the Stern-Gerlach result, thereby confirming the validity of this new attribute. To account for the structure of the periodic table, the central-field approximation is introduced. In it, electrons in an atom are treated like those in hydrogen, except that they have four not three quantum numbers, the fourth related to spin. The Pauli Exclusion Principle requires that no four can be the same for any electron in the atom, a feature that explains the occurrence of shells in the periodic table. The electronic structure of various atoms is stated, with silver being a giant spin ½ system.
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Ieda, J., and S. Maekawa. Spinmotive force. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.003.0007.

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This chapter begins with Faraday’s law, which states that electromotive forces power everything by virtue of the charge e of an electron, and introduces spinmotive forces which reflect the magnetic moment of an electron. This motive force reflects the energy conservation requirements of the spin-torque transfer process that is at the heart of spintronics. The Stern-Gerlach experiment that used spin-dependent forces established the existence of spin. It is shown here that conservative forces would exist even if an electron was not charged, and do exist for uncharged excitations, such as magnons or phonons. Such forces are especially important in ferromagnetic materials where the spinmotive force commonly drives an electronic charge current due to the higher mobility of the majority electrons.
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Book chapters on the topic "STERN-GERLACH EXPERIMENT"

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Weinert, Friedel. "Stern—Gerlach Experiment." In Compendium of Quantum Physics. Springer Berlin Heidelberg, 2009. http://dx.doi.org/10.1007/978-3-540-70626-7_214.

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Baaquie, Belal E. "The Stern–Gerlach Experiment." In The Theoretical Foundations of Quantum Mechanics. Springer New York, 2012. http://dx.doi.org/10.1007/978-1-4614-6224-8_10.

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Basdevant, Jean-Louis, and Jean Dalibard. "Analysis of a Stern—Gerlach Experiment." In Advanced Texts in Physics. Springer Berlin Heidelberg, 2000. http://dx.doi.org/10.1007/978-3-662-04277-9_10.

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Basdevant, Jean-Louis, and Jean Dalibard. "Analysis of a Stern–Gerlach Experiment." In The Quantum Mechanics Solver. Springer International Publishing, 2019. http://dx.doi.org/10.1007/978-3-030-13724-3_3.

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Friedrich, Bretislav, and Horst Schmidt-Böcking. "Otto Stern’s Molecular Beam Method and Its Impact on Quantum Physics." In Molecular Beams in Physics and Chemistry. Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-63963-1_5.

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AbstractMotivated by his interest in thermodynamics and the emerging quantum mechanics, Otto Stern (1888–1969) launched in 1919 his molecular beam method to examine the fundamental assumptions of theory that transpire in atomic, molecular, optical, and nuclear physics. Stern’s experimental endeavors at Frankfurt (1919–1922), Hamburg (1923–1933), and Pittsburgh (1933–1945) provided insights into the quantum world that were independent of spectroscopy and that concerned well-defined isolated systems, hitherto accessible only to Gedanken experiments. In this chapter we look at how Stern’s molecular beam research came about and review six of his seminal experiments along with their context and reception by the physics community: the Stern-Gerlach experiment; the three-stage Stern-Gerlach experiment; experimental evidence for de Broglie’s matter waves; measurements of the magnetic dipole moment of the proton and the deuteron; experimental demonstration of momentum transfer upon absorption or emission of a photon; the experimental verification of the Maxwell-Boltzmann velocity distribution via deflection of a molecular beam by gravity. Regarded as paragons of thoroughness and ingenuity, these experiments entail accurate transversal momentum measurements with resolution better than 0.1 atomic units. Some of these experiments would be taken up by others where Stern left off only decades later (matter-wave scattering or photon momentum transfer). We conclude by highlighting aspects of Stern’s legacy as reflected by the honors that have been bestowed upon him to date.
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Sauer, Tilman. "Multiple Perspectives on the Stern-Gerlach Experiment." In Boston Studies in the Philosophy and History of Science. Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-30229-4_12.

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Ulbricht, Hendrik. "Testing Fundamental Physics by Using Levitated Mechanical Systems." In Molecular Beams in Physics and Chemistry. Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-63963-1_15.

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AbstractWe will describe recent progress of experiments towards realising large-mass single particle experiments to test fundamental physics theories such as quantum mechanics and gravity, but also specific candidates of Dark Matter and Dark Energy. We will highlight the connection to the work started by Otto Stern as levitated mechanics experiments are about controlling the centre of mass motion of massive particles and using the same to investigate physical effects. This chapter originated from the foundations of physics session of the Otto Stern Fest at Frankfurt am Main in 2019, so we will also share a view on the Stern Gerlach experiment and how it related to tests of the principle of quantum superposition.
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Jorda, S., and H. Schmidt-Böcking. "Wilhelm Heinrich Heraeus—Doctoral Student at the University Frankfurt." In Molecular Beams in Physics and Chemistry. Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-63963-1_10.

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AbstractWilhelm Heinrich Heraeus (*1900 – †1985), the founder of the Wilhelm and Else Heraeus Foundation, wrote his doctoral thesis at the University of Frankfurt in 1922–23 under the supervision of Richard Wachsmuth and Walther Gerlach. Thereby, he became a witness of the Stern-Gerlach experiment, completed in Frankfurt in 1922. In his thesis, Heraeus investigated “The dependence of the thermoelectrical force of iron on its structure” and was able to show that earlier measurements by G. Borelius were incorrect and irreproducible. On 23 July 1923, Heraeus passed his doctoral examination in Frankfurt under Wachsmuth’s auspices.
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Ghatak, Ajoy, and S. Lokanathan. "Experiments with Spin Half Particles The Stern-Gerlach Experiment, Larmor Precession and Magnetic Resonance." In Quantum Mechanics: Theory and Applications. Springer Netherlands, 2004. http://dx.doi.org/10.1007/978-1-4020-2130-5_14.

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Huber, Josef Georg, Horst Schmidt-Böcking, and Bretislav Friedrich. "Walther Gerlach (1889–1979): Precision Physicist, Educator and Research Organizer, Historian of Science." In Molecular Beams in Physics and Chemistry. Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-63963-1_8.

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AbstractWalther Gerlach’s numerous contributions to physics include precision measurements related to the black-body radiation (1912–1916) as well as the first-ever quantitative measurement of the radiation pressure (1923), apart from his key role in the epochal Stern-Gerlach experiment (1921–1922). His wide-ranging research programs at the Universities of Tübingen, Frankfurt, and Munich entailed spectroscopy and spectral analysis, the study of the magnetic properties of matter, and radioactivity. An important player in the physics community already in his 20s and in the German academia in his later years, Gerlach was appointed, on Werner Heisenberg’s recommendation, Plenipotentiary for nuclear research for the last sixteen months of the existence of the Third Reich. He supported the effort of the German physicists to achieve a controlled chain reaction in a uranium reactor until the last moments before the effort was halted by the Allied Alsos Mission. The reader can find additional discussion of Gerlach’s role in the supplementary material provided with the online version of the chapter on SpringerLink. After returning from his detention at Farm Hall, he redirected his boundless elan and determination to the reconstruction of German academia. Among his high-ranking appointments in the Federal Republic were the presidency of the University of Munich (1948–1951) and of the Fraunhofer Society (1948–1951) as well as the vice-presidency of the German Science Foundation (1949–1961) and the German Physical Society (1956–1957). As a member of Göttinger Achtzehn, he signed the Göttingen Declaration (1957) against arming the Bundeswehr with nuclear weapons. Having made history in physics, Gerlach became a prolific writer on the history of physics. Johannes Kepler was his favorite subject and personal hero—as both a scientist and humanist.
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Conference papers on the topic "STERN-GERLACH EXPERIMENT"

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Zhu, Guangtian, Chandralekha Singh, Mel Sabella, Charles Henderson, and Chandralekha Singh. "Students’ Understanding of Stern Gerlach Experiment." In 2009 PHYSICS EDUCATION RESEARCH CONFERENCE. AIP, 2009. http://dx.doi.org/10.1063/1.3266744.

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Gondran, Michel, Alexandre Gondran, and Abdel Kenoufi. "Decoherence time and spin measurement in the Stern-Gerlach experiment." In FOUNDATIONS OF PROBABILITY AND PHYSICS - 6. AIP, 2012. http://dx.doi.org/10.1063/1.3688960.

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CARMICHAEL, H. J., P. KOCHAN, and L. TIAN. "COHERENT STATES AND OPEN QUANTUM SYSTEMS: A COMMENT ON THE STERN-GERLACH EXPERIMENT AND SCHRÖDINGER'S CAT." In Proceedings of the International Symposium. WORLD SCIENTIFIC, 1994. http://dx.doi.org/10.1142/9789814503839_0006.

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Yesharim, Ofir, Aviv Karnieli, Giuseppe Di Domenico, Sivan Trajtenberg-Mills, and Ady Arie. "Experimental Observation of the Stern Gerlach Effect in Nonlinear Optics." In CLEO: QELS_Fundamental Science. OSA, 2021. http://dx.doi.org/10.1364/cleo_qels.2021.fth1j.1.

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De Raedt, H., M. I. Katsnelson, H. C. Donker, and K. Michielsen. "Quantum theory as a description of robust experiments: application to Stern-Gerlach and Einstein-Podolsky-Rosen-Bohm experiments." In SPIE Optical Engineering + Applications, edited by Chandrasekhar Roychoudhuri, Al F. Kracklauer, and Hans De Raedt. SPIE, 2015. http://dx.doi.org/10.1117/12.2185704.

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Reports on the topic "STERN-GERLACH EXPERIMENT"

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Onel, Y. Polarizing matter and antimatter: A new method. The study of a repetitive Stern-Gerlach on stored polarized protons and the spin-splitter experiment: Progress report. Office of Scientific and Technical Information (OSTI), 1992. http://dx.doi.org/10.2172/10127400.

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