Design Simulation of Czerny-Turner Configuration-based Raman Spectrometer using physical optics propagation algorithm

TL;DR

This paper presents a simulation-based design of a Czerny-Turner Raman spectrometer using physical optics propagation, demonstrating potential for an efficient, cost-effective optical diagnostic tool.

Contribution

It introduces a detailed optical system simulation approach for a Raman spectrometer based on the Czerny-Turner configuration, integrating physical optics propagation algorithms.

Findings

High image efficiency predicted for the designed system

Spectral range of 530 to 630 nm successfully observed

Simulation results support potential for cost-effective spectrometer design

Abstract

We report the design simulation of the Raman spectrometer using optical system design software Zemax. The design is based on the Czerny-turner configuration which includes an optical system consisting of an entrance slit, two concave mirrors, reflecting type diffraction grating, and an image detector. The system's modelling approach is suggested by introducing the corresponding relationship between detector pixels and wavelength, linear CCD receiving surface length, and image surface dimension. Simulations have been carried out using the POP (Physical Optics Propagation) algorithm. Spot diagram, relative illumination, irradiance plot, Modulation Transfer Function (MTF), geometric, and encircled energy simulated for designing the Raman spectrometer. The simulation results of the Raman spectrometer's using a 527 nm wavelength laser as an excitation light source are presented. The present optical system is designed in sequential mode and a Raman spectrum observed in the range of 530 to 630 nm. The analysis shows that the system's image efficiency is higher, predicting that it is possible to build an efficient and cost-effective Raman spectrometer for optical diagnostics.