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| [[Image:Goos-Hanchen-Shift.svg|right|thumbnail|300px|Ray diagram illustrating the physics of the Goos–Hänchen effect]]
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| The '''Goos–Hänchen effect''' (named after [[Fritz Goos|Hermann Fritz Gustav Goos]] (1883 – 1968)<ref>http://de.wikipedia.org/wiki/Fritz_Goos</ref> and [[Hilda Hänchen]] (1919 – 2013)) is an [[optical phenomenon]] in which [[Linear polarization|linearly polarized]] light undergoes a small lateral shift, when [[Total internal reflection|totally internally reflected]]. The shift is perpendicular to the direction of propagation, in the plane containing the incident and reflected beams. This effect is the linear polarization analog of the [[Imbert–Fedorov effect]]. | |
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| This effect occurs because the reflections of a finite sized beam will interfere along a line transverse to the average propagation direction. As shown in the figure, the superposition of two plane waves with slightly different angles of incidence but with the same frequency or wavelength is given by
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| :<math>\mathbf{\underline{E}}(x,z,t)=\mathbf{\underline{E}}^{TE/TM} \left( e^{j\mathbf{k}_1 \cdot \mathbf{r}} + e^{j\mathbf{k}_2 \cdot \mathbf{r}} \right) \cdot e^{-j \omega t}</math>
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| where
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| :<math> \mathbf{k}_{1} = k \left( \cos{\left( \theta_0 + \Delta \theta \right)} \mathbf{\hat{x}} +
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| \sin{\left( \theta_0 + \Delta \theta \right)} \mathbf{\hat{z}}
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| \right) </math>
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| and
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| :<math> \mathbf{k}_{2} = k \left( \cos{\left( \theta_0 - \Delta \theta \right)} \mathbf{\hat{x}} +
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| \sin{\left( \theta_0 - \Delta \theta \right)} \mathbf{\hat{z}}
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| \right) </math>
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| with
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| :<math> k = \begin{matrix}\frac{\omega }{c} \end{matrix} n_1 </math>.
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| It can be shown that the two waves generate an interference pattern transverse to the average propagation direction,
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| :<math> \mathbf{k}_0 = k \left( \cos{\theta_0} \mathbf{\hat{x}} + \sin{\theta_0} \mathbf{\hat{z}} \right) </math>
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| and on the interface along the <math>(y,z)</math> plane.
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| Both waves are reflected from the surface and undergo different phase shifts, which leads to a lateral shift of the finite beam. Therefore the '''Goos–Hänchen effect''' is a coherence phenomenon.
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| This effect continues to be a topic of scientific research, for example in the context of nanophotonics applications. The work by Merano et al.<ref>{{cite journal| author=M. Merano, A. Aiello, G. W. ‘t Hooft, M. P. van Exter, E. R. Eliel, and J. P. Woerdman | journal= Optics Express|volume= 15|pages= 15928–15934|year= 2007 | title=Observation of Goos Hänchen Shifts in Metallic Reflection|bibcode = 2007OExpr..1515928M |doi = 10.1364/OE.15.015928 |arxiv = 0709.2278 }}</ref> studied the Goos–Hänchen effect experimentally for the case of an optical beam reflecting from a metal surface (gold) at 826 nm. They report a substantial, negative lateral shift of the reflected beam in the plane of incidence for a p-polarization and a smaller, positive shift for the s-polarization case.
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| ==References==
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| <references/>
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| * Frederique de Fornel, ''Evanescent Waves: From Newtonian Optics to Atomic Optics'', Springer (2001), pp. 12–18
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| *F. Goos and H. Hänchen, ''Ein neuer und fundamentaler Versuch zur Totalreflexion'', ''Ann. Phys.'' (436) 7–8, 333–346 (1947). {{doi|10.1002/andp.19474360704}}
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| * M. Delgado and E. Delgado, ''Evaluation of a total reflection set-up by an interface geometric model''. ''Optik – International Journal for Light and Electron Optics'', Volume 113, Number 12, March 2003, pp. 520–526(7)
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| {{DEFAULTSORT:Goos-Hanchen effect}}
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| [[Category:Optical phenomena]]
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The writer's name is Christy. My spouse and I reside in Kentucky. For years she's been operating as a journey agent. To climb is some thing she would by no means give up.
Feel free to surf to my web site ... clairvoyance, find out here now,