- Stern–Gerlach experiment
In

quantum mechanics , the**Stern–Gerlach experiment**[*Walther Gerlach & Otto Stern, "Das magnetische Moment des Silberatoms", "Zeitschrift für Physik"*] , named after**9**, 353-355 (1922).Otto Stern andWalther Gerlach , is an important 1922 experiment on thedeflection of particles, often used to illustrate basic principles of quantum mechanics. It can be used to demonstrate that electrons and atoms have intrinsically quantum properties, and howmeasurement in quantum mechanics affects the system being measured.**Basic theory and description**Otto Stern andWalther Gerlach devised an experiment to determine whether particles had any intrinsicangular momentum . In a classical system, such as the earth orbiting the sun, the earth has angular momentum from both its revolution around the sun, and the rotation about its axis (its spin). If the electron is treated like a classicaldipole with two halves of charge spinning quickly, it will begin to precess in amagnetic field , because of the torque that the magnetic field exerts on the dipole (see Torque-induced precession).If the particle travels in a homogeneous magnetic field, the forces exerted on opposite ends of the dipole cancel each other out and the trajectory of the particle is unaffected. If the experiment is conducted using electrons, an electric field of appropriate magnitude and oriented transverse to the charged particle's path is used to compensate for the tendency of any charged particle to curl in its path through a magnetic field (see cyclotron motion), and the fact that electrons are charged can safely be ignored. The Stern–Gerlach experiment can be conducted using electrically neutral particles and the same conclusion is reached, since it is designed to test angular momentum only, not any electrostatic phenomena.

magnetic field, then the force on one end of the dipole will be slightly greater than the opposing force on the other end of the dipole. This leads to the particle being deflected in the inhomogeneous magnetic field. The direction in which the particles are deflected is typically called the "z" direction.

If the particles are classical, "spinning" particles, then the distribution of their spin angular momentum vectors is taken to be truly random and each particle would be deflected up or down by a different amount, producing an even distribution on the screen of a detector. Instead, the particles passing through the device are deflected either up or down by a specific amount. This can only mean that spin angular momentum is quantized, i.e. it can only take on discrete values. There is not a continuous distribution of possible angular momenta.

Electrons are spin +½ particles. These have only two possible spin angular momentum values, called spin-up and spin-down. The exact value in the z direction is +ħ/2 or -ħ/2. If this value arises as a result of the particles rotating the way a planet rotates, then the individual particles would have to be spinning impossibly fast. The speed of rotation would be in excess of the speed of light and is thus impossible. [

*cite book|first=Sin-itiro|last=Tomonaga|title=The Story of Spin|publisher=University of Chicago Press|year=1997|isbn=0-226-80794-0 p. 35*] Thus, the spin angular momentum has nothing to do with rotation and is a purely quantum mechanical phenomenon. That is why it is sometimes known as the "intrinsic angular momentum."For electrons, two possible values for spin exist, as well as for the

proton and theneutron , which are composite particles made up of threequarks each, which are themselves spin-½ particles. Other particles may have a different number of possible values. Deltabaryons (Δ^{++}, Δ^{+}, Δ^{0}, Δ^{−}), for example, are spin +3/2 particles and have four possible values for spin angular momentum.Vector mesons , as well asphotons ,W and Z bosons andgluons are spin +1 particles and have three possible values for spin angular momentum.To describe the experiment with spin +½ particles mathematically, it is easiest to use Dirac's

bra-ket notation. As the particles pass through the Stern-Gerlach device, they are "being observed." The act of observation in quantum mechanics is equivalent to measuring them. Our observation device is the detector and in this case we can observe one of two possible values, either spin up or spin down. These are described by the angular momentum quantum number j, which can take on one of the two possible allowed values, either +ħ/2 or -ħ/2. The act of observing (measuring) corresponds to the operator J_{z}. In mathematical terms,:$|psi\; angle\; =\; c\_1left|psi\_\{j\; =\; +frac\{hbar\}\{2\; ight\; angle\; +\; c\_2left|psi\_\{j\; =\; -frac\{hbar\}\{2\; ight\; angle.$

The constants c

_{1}and c_{2}are complex numbers. The squares $scriptstyle\; |c\_1|^2$ and $scriptstyle\; |c\_2|^2$ of their absolute values determine the probabilities that in the state $|scriptstyle\; psi\; angle$ one of the two possible values of j is found. The constants must also be normalized in order that the probability of finding either one of the values be unity. However, this information is not sufficient to determine the values of c_{1}and c_{2}, because they may in fact be complex numbers. Therefore the measurement yields only the absolute values of the constants.**equential experiments**If we combine some Stern–Gerlach apparati we can clearly see that they do not act as simple selectors, but alter the states observed (as in light polarization), according to

quantum mechanics laws:**History**The Stern–Gerlach experiment was performed in

Frankfurt ,Germany in 1922 byOtto Stern andWalther Gerlach . At the time, Stern was an assistant toMax Born at theUniversity of Frankfurt 's Institute for Theoretical Physics, and Gerlach was an assistant at the same university's Institute for Experimental Physics.At the time of the experiment, the most prevalent model for describing the

atom was theBohr model , which describedelectrons as going around the positively-charged nucleus only in certain discreteatomic orbital s orenergy levels . Since the electron wasquantized to be only in certain positions in space, the separation into distinct orbits was referred to asspace quantization .**Impact**The Stern–Gerlach experiment had one of the biggest impacts on modern physics:

*In the decade that followed, scientists showed using similar techniques, that the nucleus of some atoms also have quantized angular momentum. It is the interaction of this nuclear angular momentum with the spin of the electron that is responsible for the

hyperfine structure of the spectroscopic lines.*In the thirties, using an extended version of the S–G apparatus,

Isidor Rabi and colleagues showed that by using a varying magnetic field, one can force the magnetic momentum to go from one state to the other. The series of experiments culminated in 1937 when they discovered that state transitions could be induced using time varying fields or RF fields. The so called**Rabi oscillation**is the working mechanism for theMagnetic Resonance Imaging equipment found in hospitals.* Later

Norman F. Ramsey , modified the Rabi apparatus to increase the interaction time with the field. The extreme sensitivity due to frequency of the radiation makes this very useful for keeping accurate time, and is still used today inatomic clock s.* In the early sixties, Ramsey and

Daniel Kleppner used a S–G system to produce a beam of polarized hydrogen as the source of energy for the HydrogenMaser , which is still one of the most popular atomic clocks.* The direct observation of the spin is the most direct proof of quantization in quantum mechanics.

* The Stern-Gerlach experiment has become a paradigm of quantum measurement. In particular, it has been assumed to satisfy von Neumann projection. According to more recent insights, based on a quantum mechanical description of the influence of the inhomogeneous magnetic field [

*M.O. Scully, W.E. Lamb, and A. Barut, "On the theory of the Stern-Gerlach apparatus", "Foundations of Physics"*] , this can be true only in an approximate sense. Von Neumann projection can be rigorously satisfied only if the magnetic field is homogeneous. Hence, von Neumann projection is even incompatible with a proper functioning of the Stern-Gerlach device as an instrument for measuring spin.**17**, 575-583 (1987).**ee also***

Photon polarization

*Stern-Gerlach-Medaille **References*** Friedrich, Bretislav and Herschbach, Dudley. [

*http://www.physicstoday.org/vol-56/iss-12/p53.html "Stern and Gerlach: How a Bad Cigar Helped Reorient Atomic Physics"*] "Physics Today", December 2003.**External links*** [

*http://www.if.ufrgs.br/~betz/quantum/SGPeng.htm Stern-Gerlach Experiment Java Applet Animation*]

* [*http://phet.colorado.edu/simulations/sims.php?sim=SternGerlach_Experiment Stern-Gerlach Experiment Flash Model*]

* [*http://galileo.phys.virginia.edu/classes/252/Angular_Momentum/Angular_Momentum.html Detailed explanation of the Stern-Gerlach Experiment*]

* [*http://www.aip.org/pt/vol-56/iss-12/p53.html "Physics Today" article about the history of the Stern-Gerlach experiment*]

* [*http://plato.stanford.edu/entries/physics-experiment/figure13.html Image of experiment result*]

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**Stern-Gerlach experiment**— Šterno ir Gerlacho eksperimentas statusas T sritis Standartizacija ir metrologija apibrėžtis Eksperimentas, įrodantis, kad atomo magnetinio momento projekcija į magnetinio lauko stiprio kryptį įgyja tik tam tikras kvantuotas vertes. atitikmenys:… … Penkiakalbis aiškinamasis metrologijos terminų žodynas**Stern-Gerlach experiment**— Šterno ir Gerlacho eksperimentas statusas T sritis fizika atitikmenys: angl. Stern Gerlach experiment vok. Stern Gerlach Versuch, m rus. опыт Штерна Герлаха, m pranc. expérience de Stern Gerlach, f … Fizikos terminų žodynas**Stern-Gerlach-Experiment**— Tafel am physikalischen Institut in Frankfurt am Main Mit Hilfe des Stern Gerlach Versuchs wurde 1922 von den Physikern Otto Stern und Walther Gerlach erstmals die Richtungsquantelung von Drehimpulsen von Atomen beobachtet. Der Stern Gerlach… … Deutsch Wikipedia**Stern-Gerlach Experiment**— Tafel am physikalischen Institut in Frankfurt am Main Mit Hilfe des Stern Gerlach Versuchs wurde 1922 von den Physikern Otto Stern und Walther Gerlach erstmals die Richtungsquantelung von Drehimpulsen von Atomen beobachtet. Der Stern Gerlach… … Deutsch Wikipedia**Stern-Gerlach experiment**— ▪ physics demonstration of the restricted spatial orientation of atomic and subatomic particles with magnetic polarity, performed in the early 1920s by the German physicists Otto Stern (Stern, Otto) and Walther Gerlach (Gerlach, Walther). In the … Universalium**Stern-Gerlach-Medaille**— The Stern Gerlach Medaille is the most prestigious German Award for experimental physicists, named after the scientist of the Stern–Gerlach experiment, Otto Stern and Walther Gerlach.The prize, awarded annually since 1993, is handed out by the… … Wikipedia**Stern-Gerlach-Versuch**— Šterno ir Gerlacho eksperimentas statusas T sritis Standartizacija ir metrologija apibrėžtis Eksperimentas, įrodantis, kad atomo magnetinio momento projekcija į magnetinio lauko stiprio kryptį įgyja tik tam tikras kvantuotas vertes. atitikmenys:… … Penkiakalbis aiškinamasis metrologijos terminų žodynas**Stern-Gerlach-Versuch**— Šterno ir Gerlacho eksperimentas statusas T sritis fizika atitikmenys: angl. Stern Gerlach experiment vok. Stern Gerlach Versuch, m rus. опыт Штерна Герлаха, m pranc. expérience de Stern Gerlach, f … Fizikos terminų žodynas**Stern-Gerlach-Versuch**— Tafel am Physikalischen Verein in Frankfurt am Main Mit Hilfe des Stern Gerlach Versuchs wurde 1922 von den Physikern Otto Stern und Walther Gerlach erstmals die Richtungsquantelung von Drehimpulsen von Atomen beobachtet. Der Stern Gerlach… … Deutsch Wikipedia**Stern-Gerlach-Apparatur**— Tafel am physikalischen Institut in Frankfurt am Main Mit Hilfe des Stern Gerlach Versuchs wurde 1922 von den Physikern Otto Stern und Walther Gerlach erstmals die Richtungsquantelung von Drehimpulsen von Atomen beobachtet. Der Stern Gerlach… … Deutsch Wikipedia