Lasers PH 645/ OSE 645/ EE 613 Summer 2010 Section 1: T/Th 2:45-4:45 PM Engineering Building 240

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1 Lasers PH 645/ OSE 645/ EE 613 Summer 2010 Section 1: T/Th 2:45-4:45 PM Engineering Building 240 John D. Williams, Ph.D. Department of Electrical and Computer Engineering 406 Optics Building - UAHuntsville, Huntsville, AL Ph. (256) williams@eng.uah.edu Office Hours: Tues/Thurs 2-3PM JDW, ECE Summer 2010

Chapter 12: Stable Laser Resonators and Gaussian Beams Stable curved mirror cavities Properties of Gaussian beams Properties of real Laser beams Propagation of Gaussian beams using ABCD matrices

2 Chapter 12: Stable Laser Resonators and Gaussian Beams Stable curved mirror cavities Properties of Gaussian beams Properties of real Laser beams Propagation of Gaussian beams using ABCD matrices Chapter 12 Homework: 3,6,7,9,11 Cambridge University Press, 2004 ISBN-13: All figures presented from this point on were taken directly from (unless otherwise cited): W.T. Silfvast, laser Fundamentals 2 nd ed., Cambridge University Press, 2004.

3 Stable 2 Mirror Cavity Designs

4 ABCD Matrix Elements for Transmission and Reflection

5 ABCD Matrix Elements for Transmission and Reflection

6 ABCD Matrix Consider a beam traveling from r1 to r2. The beam travels at an angle θ. Assuming no index change or reflection, then the value θ2 = the incident angle This can be written in matrix form as Where the ABCD translation matrix is

7 ABCD Matrix for lenses A ray passing through two lenses of focal length f1 and f2 can be written as

8 Stability Criteria for Two Mirror Cavities One can visualize the optical conditions of two semispherical mirrors as that of two thin lenses bending light as it refracts through.

9 Graphical Conditions for Stability

10 Graphical Conditions for Stability

11 Graphical Conditions for Stability For N successive applications present within a resonator cavity

12 Graphical Conditions for Stability

13 Conditions on the Verge of Stability

14 Gaussian Beams Consider a Gaussian beam with a geometric beam radius, w (beam waist) Where w o is the waist of the beam at the focal plane

15 Gaussian Beams Consider a Gaussian beam with a geometric beam radius, w Beam wavefront of curvature is Angular spread function for z > z R

16 Gaussian Properties of 2 Mirror Cavities

17 Gaussian Properties of 2 Mirror Cavities

18 Gaussian Properties of 2 Mirror Cavities

19 Gaussian Properties of 2 Mirror Cavities

20 Gaussian Properties of 2 Mirror Cavities

21 Gaussian Properties of 2 Mirror Cavities

22 Plane Parallel and Long Radius Cavities Two plain mirrors parallel to one another Mode operation is on the edge of stability with g 1 g 2 =1 Just inside stability where the radius of curvature for each mirrors is significantly larger than the distance between the mirrors. g 1 g 2 1

at mirror 1 flat mirror and another curved mirror focusing the

23 Symmetrical Mirror Cavities Two curved mirrors of equal radius mirrors parallel to one another Minimum waist at center waist at mirror 1 flat mirror and another curved mirror focusing the beam waist at curved mirror waist at flat mirror = minimum waist

24 Concave-Convex Mirror Cavities Two curved mirrors One focusing and the other defocusing such that Minimum waist lies outside the cavity providing a large diameter beam throughout the gain medium with a relatively uniform volume

25 Near Centric (Spherical) Mirror Cavities Two curved mirrors focusing at a point d/2 Minimum waist at center waist at mirror g 1 =1+ d/r 1, g 2 =1 R 1 =d, R 2 = ω 2 0 = dλ d + d π 2d + d 1/ 2

26 Mode Volume of a Hermite-Gaussian Mode Mode volume of an electric field in a cavity Using the identity

27 Example of Laser Beam Power using Gaussian Mode Calculations

28 Example of Laser Beam Power using Gaussian Mode Calculations This is the maximum power available in the laser if all of the cavity power was converted to stimulated emission

29 Properties of Real Laser Beams Previous sections referred to the propagation of plane wave and Gaussian (diffraction limited) beams Higher order modes are not Gaussian shaped Thus, real world multimode lasers are neither of the shapes previously discussed There is however a parameter that does allow one to model such systems Lets start with a diffraction limited (Gaussian beam). The product of the waist and the angular spread is The minimum possible product would be In a real beam defined my multiples of different diffraction limited beams, on can define the divergence as And the minimum waist as Yielding: M 2 is the propagation constant

30 Properties of Real Laser Beams One can solve for the propagation constant in terms of geometric measurables as: And therefore the waist of the beam at any point z within the cavity as Notice that if M = 1 then we have the same equations used to represent a Gaussian beam Finally, one can determine the Raleigh range as With a concept as simple as M2, it is possible to align laser mirrors to generate the desired mode quality easily and effectively It is also possible to examine aberrations induced in the beam and measure the astigmatism of the beam with ease

31 Gaussian Beam Propagation using Matricies Gaussian beams are evaluated using a complex beam parameter, q, which evaluates the shape of the beam at the prescribed wavelength One can evaluate the beam parameter at any point 2 from a known point 1 using

Optics II. Reflection and Mirrors

Optics II. Reflection and Mirrors Optics II Reflection and Mirrors Geometric Optics Using a Ray Approximation Light travels in a straight-line path in a homogeneous medium until it encounters a boundary between two different media The