Transcript Document
The Design and Performance of
an Astigmatic Laser Mode
Converter
Alex Ellis, Stuyvesant High School
Dr. Harold Metcalf and Dr. John Noé,
Stony Brook University
A What?
An astigmatic mode converter is
a pair of cylindrical lenses,
accompanied by mode-matching
lenses, which introduce an
astigmatic phase shift to a laser
beam. In particular, it can
convert Hermite-Gaussian (HG)
rectangularly symmetric
transverse modes into LaguerreGaussian (LG) circularly
symmetric modes.
Hermite-Gaussian Modes
•Rectangularly symmetric
•Obtainable in spherical-planar
resonator by adjusting plane mirror
angle
HG0,1
•Also obtainable by an intra-cavity
crosswire, when the laser is operating
in a multimode
•Indices (m,n) refer to the number of
intensity minima in the x and y
directions
HG1,2
Laguerre-Gaussian Modes
(Optical Vortices)
•Circularly Symmetric
•Obtained by intra-cavity circular
absorbers, computer-generated
holograms, or an astigmatic mode
converter
LG3,0
•Photons have orbital angular
momentum of l*hbar
•Index l is the number of 2π phase
shifts around the diameter
LG1,1
Superpositions
HG0,1+HG1,0 = HG0,1 rotated 45°
HG0,1+i*HG1,0 =LG1,0
i represents a π/2 phase shift
Operating Principle of an
Astigmatic Mode Converter
Input
The Guoy Phase
45° rotated HG0,1
•HG: (m+n+1)ψ(z)
•LG: (l+2p+1)ψ(z)
Ψ(z) = arctan(z/z0)
Cylindrical Lenses
•First introduces path length difference, altering
the superposition due to the Guoy phase
(astigmatism in the region)
•Second one removes the introduced astigmatism
Mode Converter Rules
Localized Astigmatism and
Proper Guoy Phase Shift
Mode-Matching
A beam waist is required midway between the two cylindrical lenses
w0, z0
w0’, z0’
Apparatus – The Laser
Melles-Griot 05-LHB-570 Helium-Neon tube
R=600mm spherical mirror, 295mm from
plane mirror output coupler
Adjustment of OC gives multimodes, and an
intra-cavity crosswire on a translation stage
selects particular HG modes
Apparatus – The Mode Converter
f1 = 300mm
d1 = 513mm
fcyl = 150mm
d2 = 481mm
d3 = 212mm
w0 = 246um
z0 = 300mm
w0’ = 227um
z0’ = 256mm
Achieved Mode Conversions
HG0,1
LG1,0
HG0,2
LG2,0
HG0,3
LG3,0
HG1,1
LG1,0
HG1,2
LG1,1
Performance – Multimodes
CCD Image
Voltage in
Photodetector (V)
2.06
1.59
2.03
2.22
Optical
Intensity (mW)
0.44
0.34
0.43
0.47
Achieved HG
Modes (m,n)
01,02,03,
bad12
02,bad01
02,bad11,
bad12
01,01,02,03,bad01,
bad11,bad1202,03,
bad12
Performance – Mode Compositions
d1
d2
Performance – Mode Compositions
d1
d2
d1
d2
Analysis of this particular mode
gives PHG ≈ 73% and PLG ≈ 27%
Applications
•Generation of arbitrary order Bessel beams by
use of an axicon
•“Optical spanners” that both trap and spin
microscopic particles
•Further study involving the orbital angular
momentum of light
Acknowledgements
•Dr. Harold Metcalf
•Dr. John Noé
•Mr. Don Bucher
•Mrs. Anne Manwell
Further Research
•Change of mode converter parameters
due to the increased spot size of highorder HG modes
•Interferometry of LG beams with plane
waves to investigate the spiral phase
pattern
•Measurement of the l*hbar per photon
orbital angular momentum
Questions