Novel cases of diffraction of light from a grating: Theory and experiment

TL;DR

This study explores new diffraction phenomena from gratings at various orientations using theory and experiments, revealing that diffraction maxima follow a second degree curve for arbitrary orientations.

Contribution

It investigates unexplored diffraction cases at non-normal incidences using Fresnel-Kirchhoff theory and experimental validation, expanding understanding beyond traditional normal incidence scenarios.

Findings

Diffraction maxima align along a second degree curve for arbitrary grating orientations.

Theoretical predictions match experimental observations across different orientations.

Unexplored diffraction cases are systematically analyzed and characterized.

Abstract

A popular pedagogical approach for introducing diffraction is to assume normal incidence of light on a single slit or a plane transmission grating. Interesting cases of diffraction from a grating at orientations other than normal incidence remain largely unexplored. In this article, we report our study of these unexplored cases, which was taken up as an undergraduate student project. We define various cases of orientation of the grating and use the Fresnel-Kirchhoff formula to arrive at the diffracted intensity distribution. An experimental arrangement consisting of a laser, a grating mount, a digital camera, and a calibrated plane screen is employed to record our observations. We discuss for each case the theoretical and experimental results and establish the conformity between the two. Finally, we analyze the details of various cases and conclude that for an arbitrary orientation of the grating, the diffraction maxima fall along a second degree curve.