Grating Resolving Power of Laser Beams with Gaussian Distribution

Click For Summary
SUMMARY

The discussion focuses on the grating resolving power of laser beams with Gaussian distribution, specifically addressing the limitations of applying the Rayleigh criterion to such beams. The formula for resolving power, R = λ/Δλ = mN, where m is the order and N is the number of illuminated slits, remains valid but does not account for the Gaussian beam's characteristics. The resolution of a diffraction grating spectrometer is not significantly improved by attempting to adapt this formula for Gaussian beams, as the resolving power is inherently reduced compared to uniform beams.

PREREQUISITES
  • Understanding of the Rayleigh criterion in optics
  • Familiarity with Gaussian beam properties
  • Knowledge of diffraction grating principles
  • Basic mathematics involving resolving power formulas
NEXT STEPS
  • Research the implications of Gaussian beam characteristics on optical resolution
  • Explore advanced topics in diffraction grating design
  • Study the effects of beam truncation on resolving power
  • Learn about the application of the Rayleigh criterion in various optical systems
USEFUL FOR

Optical engineers, physicists, and researchers involved in laser technology and diffraction optics will benefit from this discussion.

mikey1234
Messages
1
Reaction score
0
TL;DR
Grating resolving power for Gaussian Beams vs Uniform incidence
All resources I’ve found for grating resolving power assume uniform distribution on the grating and produce airy disks. Resolvance is determined by the Rayleigh criterion where the peak of one wavelength is at the minima of the adjacent one. This definition doesn’t seem applicable for Gaussian laser beams.

How does the grating resolving power of Lamda/(delta Lambda) = mN, where m is the order (assume 1) and N is the number of slits illuminated change for a diffraction limited laser beam with a Gaussian distribution? Let’s say our criterion for resolvance is separating the peaks by wo (1/e^2 width) diameter.
 
Science news on Phys.org
The resolution formula is used to estimate the resolution of a diffraction grating spectrometer, and there is very little to be gained by trying to do the calculation for a beam with a Gaussian distribution. The resolving power ## R=\frac{\lambda}{ \Delta \lambda}=N m ## is a nice simple one, and it would unnecessarily complicate matters to have some function of ## w_o ## in this formula.
 
Reply
  • Like
Likes   Reactions: hutchphd
The resolution power for truncated Gaussian beam would only decrease compare to the uniform beam.
 

Similar threads

Graduate Intensity of a Gaussian laser beam
  • · Replies 5 ·
Replies
5
Views
4K
Graduate Understanding Gaussian Beams: Definition, Equations, and Parameters
  • · Replies 1 ·
Replies
1
Views
4K
Undergrad Wave function of a laser beam?
  • · Replies 6 ·
Replies
6
Views
3K
Problem on Diffraction Grating and Laser Crystallography
  • · Replies 10 ·
Replies
10
Views
2K
Undergrad Can n-slit interference produce subwavelength stripes?
  • · Replies 6 ·
Replies
6
Views
2K
Rayleigh criterion (two wavelengths) + diffraction grating
  • · Replies 4 ·
Replies
4
Views
4K
Graduate Calculating Electric Field Distribution of a Laser Beam
  • · Replies 8 ·
Replies
8
Views
13K
What Is the Intensity Distribution and Resolving Power of an N-Slit Grating?
  • · Replies 1 ·
Replies
1
Views
3K
Optics: dispersive power of diffraction grating
  • · Replies 10 ·
Replies
10
Views
5K
Diffraction grating with slits out of phase
  • · Replies 2 ·
Replies
2
Views
4K