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The law of reflection A ray departing from P in the direction B ,with rmpBectt o the mirror normal (isre&cted symmef r i c e at tk same a g k 8. P' This is because the symmetric path POP' has minimum length. Campxe, for example, the altanative POP'. Clearly, IPOI JUP'I < I P ~ I ~ +P ' I . - P mirror + Comider tbe c~di32wtion af OP' backwards through the mirror. To QQ observer in the direction af P , the ray will appew to b v e originated at P". or dielectric interface = NUS -- MIT 2.7112.710 02/06/08wkl -b-29 Reflection from mirrors Projected: left-handed triad mirror (front view) In: right-handed triad MIT 2.71/2.710 02/06/08 wk1-b- 30 Out: left-handed triad The law of refraction (Snell's Law) Taking derivatives with respect to x 7 a(cP&) las; s - b-z =~&4-22'&4#=Q =+-n a 0 = a's&@' Tbis re&& is k n o w as 's &ew,or e = NUS -- MIT 2.7112.710 02106108 wkl-b-31 Snell's Law as minimum time principle Beach, running speed vr- Which path should the lifeguard follow to reach the drowning person in minimum time? MIT 2.7112.710 02106108 wkl -b-32 Snell's Law as momentum conservation principle MIT 2.7112.710 02/06/08wkl -b- 33 'w NUS Two types of refraction air glass from lower to higher index (towards optically denser material) angle wrt normal decreases the maximum angle that can enter the optically dense medium is such that glass air from higher to lower index (towards optically less dense material) angle wrt normal increases if the combination of and is such that then Snell’s law in the less dense medium cannot be satisfied. This situation is known as Total Internal Reflection (TIR) MIT 2.71/2.710 02/06/08 wk1-b- 34 Total Internal Reflection (TIR) air at critical angle, the refracted light propagates parallel to the interface the result is called a “surface wave” glass at angles of incidence higher than critical, the light is totally internally reflected almost as if the glass-air interface were a mirror air glass MIT 2.71/2.710 02/06/08 wk1-b- 35 in both cases of surface wave and TIR, there is an exponential tail of electric field leaking into the medium of lower optical density; this is called the evanescent wave. Typically, the evanescent wave is a few wavelengths long but it can be much longer near the critical angle We will learn more about evanescent waves after we cover the electromagnetic nature of light Frustrated Total Internal Reflection (FTIR) r > 6, glass nc If another dielectric appsoacbes within a Eew distant canatants from the TLR interface, the tail of the exponentially evmescent wave becomes propagating; i.e. the light couples out of the medium. This situati,~ is known as h s t r a t e d Total injernol &ejbtion ( F T B ) . In quantum mechanics, there is an analogous &ect b o r n as tunneling. We will compute the amount of energy coupled out of the medium of incidence later, after we study the ekctramgnetic nature of light. lllii Prisms air air TIR glass air 45° air air TIR glass 45° air retro-reflector air TIR glass TIR pentaprism MIT 2.71/2.710 02/06/08 wk1-b- Fingerprint sensors finger right-angle prism laser illumination MIT 2.71/2.710 02/06/08 wk1-b- digital camera Optical waveguides no TIR TIR TIR “planar” waveguide: high-index dielectric material sandwiched between lower-index dielectrics MIT 2.71/2.710 02/06/08 wk1-b- Numerical Aperture (NA) of a waveguide NA is the sine of the largest angle that is waveguided air (n=1) no TIR TIR TIR i.e., NA is the incident angle of acceptance of the waveguide high index contrast (n1/n2) ⇔ high NA MIT 2.71/2.710 02/06/08 wk1-b- GRadient INdex (GRIN) waveguide lowest index highest index MIT 2.71/2.710 02/06/08 wk1-b- 41 TIR Optical fibers: step cladding cladding (lower index) core (higher index) Core diameter = 8-10µm (commercial grade) Cladding diameter = 250µm (commercial grade) Index contrast Δn = 0.007 (very low NA) attenuation = 0.25dB/km MIT 2.71/2.710 02/06/08 wk1-b- Optical fibers: GRIN cladding (lower index) core of gradually decreasing index optical rays “swirl” in a helical trajectory around the axis of the core MIT 2.71/2.710 02/06/08 wk1-b- GRIN waveguides in nature: insect eyes Images removed due to copyright restrictions. Please see http://commons.wikimedia.org/wiki/File:Superposkils.gif Image by Thomas Bresson at Wikimedia Commons. MIT 2.71/2.710 02/06/08 wk1-b- Dispersion 101 3.5 Fused silica (SiO2) 3.0 Refractive index n (�) 2.5 10-1 2.0 1.5 k n 10-2 Absorption constant k (�) 100 1.0 10-3 0.5 0 -1 10 0 10 1 10 10-4 Wavelength � / µm Dispersion = the dependence of refractive index n on wavelength �. Figure by MIT OpenCourseWare. Adapted from Fig. 2.4 in Bach, Hans, and Norbert Neuroth. The Properties of Optical Glass. New York, NY: Springer, 2004. MIT 2.71/2.710 02/06/08 wk1-b-45 Dispersion from a prism incident white light (all visible wavelengths) rainbow exit red air glass green blue Newton’s prism MIT 2.71/2.710 02/06/08 wk1-b- Dispersion measures Reference color lines C (H- λ=656.3nm, red), D (Na- λ=589.2nm, yellow), F (H- λ=486.1nm, blue) e.g., crown glass has Dispersive power Dispersive index aka Abbe’s number e.g. for crown glass: V=0.01704 or v=58.698 MIT 2.71/2.710 02/06/08 wk1-b- Paraboloidal reflector: perfect focusing What should the shape function s(x) be in order for the incoming parallel ray bundle to come to perfect focus? The easiest way to find the answer is to invoke Fermat’s principle: since the rays from infinity follow the minimum path before they meet at P, it follows that they must follow the same path. focus at F A paraboloidal reflector focuses a normally incident plane wave to a point MIT 2.71/2.710 02/09/09 wk2-a- 3 3 MIT OpenCourseWare http://ocw.mit.edu 2.71 / 2.710 Optics Spring 2009 For information about citing these materials or our Terms of Use, visit: http://ocw.mit.edu/terms.
