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Physics 202 Professor P. Q. Hung 311B, Physics Building Physics 202 – p. 1/2 Interference and Diffraction Interference Light is electromagnetic waves. Shine two light beams on a given spot and observe the superposition of these two beams. Physics 202 – p. 2/2 Interference and Diffraction Interference Light is electromagnetic waves. Shine two light beams on a given spot and observe the superposition of these two beams. Superposition of two waves can lead to constructive interference or destructive interference. Physics 202 – p. 2/2 Interference and Diffraction Interference Physics 202 – p. 3/2 Interference and Diffraction Interference Physics 202 – p. 4/2 Interference and Diffraction Interference Constructive interference: Start with two identical sources in phase, i.e. oscillating in the same way. If they continue to oscillate in phase when they reach a given point, the interference is constructive ⇒ Brightest or most intense spot. The condition for this to be so is that their difference in path lengths should be a integral multiple of the wavelength. l2 − l1 = mλ m = 0, ±1, ±2, ... Physics 202 – p. 5/2 Interference and Diffraction Interference Destructive interference: Start with two identical sources in phase, i.e. oscillating in the same way. If they are out of phase (crest-to-trough) when they reach a given point, the interference is destructive ⇒ Dark spot. The condition for this to be so is that their difference in path lengths should be a half-integral multiple of the wavelength. l2 − l1 = (m − 12 )λ m = 0, ±1, ±2, ... Physics 202 – p. 6/2 Interference and Diffraction Young’s double-slit experiment Young’s experiment demonstrated the wave nature of light by showing that two coherent light beams can interfere with each other. Physics 202 – p. 7/2 Interference and Diffraction Young’s double-slit experiment If light were just “corpuscules”, the screen would be illuminated just behind these two slits. Physics 202 – p. 8/2 Interference and Diffraction Young’s double-slit experiment If light were just “corpuscules”, the screen would be illuminated just behind these two slits. Observation: Light is spread throughout the screen with bright and dark fringes. ⇒ Wave nature of light. Physics 202 – p. 8/2 Interference and Diffraction Young’s double-slit experiment Huygens’s principle Physics 202 – p. 9/2 Interference and Diffraction Young’s double-slit experiment Path Difference Physics 202 – p. 10/2 Interference and Diffraction Young’s double-slit experiment Bright Fringes: ∆l = d sin θ = mλ m = 0, ±1, ±2, ... Physics 202 – p. 11/2 Interference and Diffraction Young’s double-slit experiment Bright Fringes: ∆l = d sin θ = mλ m = 0, ±1, ±2, ... Dark Fringes: ∆l = d sin θ = (m − 12 )λ m = 0, ±1, ±2, ... Physics 202 – p. 11/2 Interference and Diffraction Young’s double-slit experiment Physics 202 – p. 12/2 Interference and Diffraction Young’s double-slit experiment: Example Red light is used in a double-slit experiment with the slits separated by a distance d = 1.20 × 10−4 m. Here λ = 664 nm in vacuum. The screen is located at a distance L = 2.75 m from the slits. Find the distance y on the screen between the central bright fringe and the third-order bright fringe. Physics 202 – p. 13/2 Interference and Diffraction Young’s double-slit experiment: Example The angle of the 3rd order bright fringe is given by (3)(664×10−9 m) sin θ3 = 1.20×10−4 m = 0.0166. Physics 202 – p. 14/2 Interference and Diffraction Young’s double-slit experiment: Example The angle of the 3rd order bright fringe is given by (3)(664×10−9 m) sin θ3 = 1.20×10−4 m = 0.0166. y = L tan θ3 ≈ 4.56 cm Physics 202 – p. 14/2 Interference and Diffraction Reflection of an interface When light travels from a medium of lower index of refraction to a region of higher index of refraction, the reflected wave suffers a 1800 phase change. Physics 202 – p. 15/2 Interference and Diffraction Reflection of an interface When light travels from a medium of lower index of refraction to a region of higher index of refraction, the reflected wave suffers a 1800 phase change. When light travels from a medium of higher index of refraction to a region of lower index of refraction, the reflected wave suffers a no phase change. Physics 202 – p. 15/2 Interference and Diffraction Reflection of an interface Physics 202 – p. 16/2 Interference and Diffraction Reflection of an interface: Air Wedge Physics 202 – p. 17/2 Interference and Diffraction Reflection of an interface: Air Wedge Physics 202 – p. 18/2 Interference and Diffraction Reflection of an interface: Air Wedge Constructive interference: Let d be the thickness of the air gap at any point. 2 d = (m − 12 )λ m = 1, 2, 3, .. Physics 202 – p. 19/2 Interference and Diffraction Reflection of an interface: Air Wedge Constructive interference: Let d be the thickness of the air gap at any point. 2 d = (m − 12 )λ m = 1, 2, 3, .. Destructive interference: 2d = mλ m = 1, 2, 3, .. Physics 202 – p. 19/2 Interference and Diffraction Reflection of an interface: Air Wedge example A very fine wire 7.33 × 10−3 mm in diameter is placed between two flat glass plates (see Fig. 28-9). Light whose wavelength in air is 600 nm falls perpendicular to the plates, and a series of bright and dark bands is seen. How many bright and dark bands will there be? Will the area next to the wire bright or dark? (2)(7.33 × 10−3 mm)/(6 × 10−7 m) = 24.5. Half-integer area next to the wire will be bright. Physics 202 – p. 20/2 Interference and Diffraction Reflection of an interface: Air Wedge example A very fine wire 7.33 × 10−3 mm in diameter is placed between two flat glass plates (see Fig. 28-9). Light whose wavelength in air is 600 nm falls perpendicular to the plates, and a series of bright and dark bands is seen. How many bright and dark bands will there be? Will the area next to the wire bright or dark? (2)(7.33 × 10−3 mm)/(6 × 10−7 m) = 24.5. Half-integer area next to the wire will be bright. Total of 25 dark lines and 25 bright lines. Physics 202 – p. 20/2 Interference and Diffraction Reflection of an interface: Newton’s ring Like an air wedge Physics 202 – p. 21/2 Interference and Diffraction Reflection of an interface: Thin Film Physics 202 – p. 22/2 Interference and Diffraction Reflection of an interface: Thin Film Let n > 1 be the index of refraction inside the thin film of thickness t. Constructive interference: 2 t = (m + 12 ) λvacuum n m = 0, 1, 2, .. Physics 202 – p. 23/2 Interference and Diffraction Reflection of an interface: Thin Film Let n > 1 be the index of refraction inside the thin film of thickness t. Constructive interference: 2 t = (m + 12 ) λvacuum n m = 0, 1, 2, .. Destructive interference: 2 t = m λvacuum n m = 0, 1, 2, .. Physics 202 – p. 23/2 Interference and Diffraction Reflection of an interface: Thin Film and color Physics 202 – p. 24/2 Interference and Diffraction Reflection of an interface: Thin Film with one phase change Physics 202 – p. 25/2 Interference and Diffraction Reflection of an interface: Thin Film example A soap bubble appears green (λ = 540 nm) at a point on its front surface nearest the viewer. What is its minimum thickness? Assume n = 1.35 Minimum thickness ⇒ m = 0. Here we have constructive interference. Physics 202 – p. 26/2 Interference and Diffraction Reflection of an interface: Thin Film example A soap bubble appears green (λ = 540 nm) at a point on its front surface nearest the viewer. What is its minimum thickness? Assume n = 1.35 Minimum thickness ⇒ m = 0. Here we have constructive interference. t= λ 4n = 5.4×10−7 m 4 ×1.35 = 100 nm. Physics 202 – p. 26/2
