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Fundamental of Optical Engineering Lecture 8.  A linearly polarized plane wave with Ē vector described by is incident on an optical element under test.

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Presentation on theme: "Fundamental of Optical Engineering Lecture 8.  A linearly polarized plane wave with Ē vector described by is incident on an optical element under test."— Presentation transcript:

1 Fundamental of Optical Engineering Lecture 8

2  A linearly polarized plane wave with Ē vector described by is incident on an optical element under test. Describe the state of polarization of the output wave (linear, elliptrical, or circular) if the optical element is:

3  (a) A linear polarizer oriented to transmit light polarized in the e x direction.

4  (b) A half-wave plate with birefringence axes oriented to coincide with e x and e y.

5  (c) A half-wave plate with birefringence axes oriented at 45º relative to e x and e y.

6  (d) A quarter-wave plate with birefringence axes oriented to coincide with e x and e y.

7  (e) A quarter-wave plate with birefringence axes oriented at 45º relative to e x and e y.

8  (f) A half-wave plate with birefringence axes oriented at 25º relative to e x and e y.

9  (g) A quarter-wave plate with birefringence axes oriented at 25º relative to e x and e y.

10  A linearly polarized light propagating in the z-direction with polarization vector in the x- direction is incident on a birefringent crystal. What is the state of polarization of the light after passing through the crystal if: (a) the crystal is a quarter-wave plate with optic axis in the xy plane oriented at 30º relative to the y- axis?

11 ◦ (b) the crystal is a half-wave plate with optic axis in the y-direction?

12 ◦ (c) the crystal is a half-wave plate with optic axis in the xy plane oriented at 11º relative to the x-axis?

13 ◦ (d) the crystal is a quarter-wave plate with optic axis in the xy plane oriented at 45º relative to the y-axis?

14 ◦ (e) the crystal is a quarter-wave plate with optic axis in the z-direction?

15  For a birefringent median with n0 = 1.654 and nE = 1.485 as shown in the figure. Find the length L that makes it be (a) a full wave plate (b) a half wave plate (c) a ¼ -wave plate if the wavelength is 656 nm.

16

17  This makes use of electrooptic effect (applied electric fields used to change the optical properties).  There are 2 kinds of electrooptic effect: linear and quadratic.

18  The linear electrooptic effect is called “Pockels effect”.  This refers to the change in the indices of the ordinary and extranordinary rays proportional to applied electric field.  This effect exists only in crystals without an inversion symmetry such as LiNbO 3.

19  For a crystal with an inversion symmetry, the linear electrooptic effect can not exist, while the quadratic electrooptic effect known as “Kerr effect” is observed.  This is where the induced index change is proportional to the square of applied electric field.

20

21  V  (pi-voltage) or half-wave voltage is the applied voltage that makes the relative phase shift be  in a cube of material.  In general, = refractive index changes produced by applied voltage.

22  It is preferable to design L >> h to have a low applied voltage V.  After applying a voltage, indices are changed as

23  V  for the material is 2,700 V, L = 2 cm, and h = 0.5 mm. Find applied voltage V to have Δ  =  (complete extinction).

24  An electrooptic crystal has dimensions of 2x2x3 along the x,y, and z axes with n E = 1.487 and n O = 1.536. An input wave propagating in the z-direction at λ = 0.63 μ m is linearly polarized at a 45 º angle relative to the x- and y- axes. A voltage V applied across the crystal in the x-direction. The voltage is increased from V = 0 until, when V = 245 V, the output polarization from the crystal is the same as that observed for V = 0. Assume that optic axis is along the y- axis. ◦ (a) What is the total phase retardation, in rad, for V = 0? ◦ (b) What is pi-voltage for the material? ◦ (c) What is the refractive index change Δ n x produced by the applied voltage of 245 V, assuming Δ n y =0?

25

26  Recall: interference eq.

27  Assume that

28  Reflectance  We can consider R into 3 cases: ◦ n 1 = n 3. ◦ n 1 n 3, n 1 ≠ n 3. ◦ n 1 < n 2 < n 3.

29  Case 1: n 1 = n 3  From a definition: A ij = A ji

30  Max in R for  Min in R for

31  n 1 = 1.5, n 2 = 1.6, and λ = 0.63 μ m. Find t 2 for R max and R min.

32  Case 2: n 1 n 3, n 1 ≠ n 3.

33  Max in R for  Min in R for

34  n 1 = 1.5, n 2 = 1.6, n 3 = 1.4, λ = 0.63 μ m. Find t 2 for R max and R min.

35  Case 3: n 1 < n 2 < n 3

36  Max in R for  Min in R for

37  n 1 = 1.5, n 2 = 1.6, n 3 = 1.7, λ = 0.63 μ m. Find t 2 for R max and R min.

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