Integrating sphere port error in diffuse reflectance measurements

Luke J. Sandilands; Thomas Cameron

doi:10.1364/AO.497962

Applied Optics
Vol. 62,
Issue 29,
pp. 7700-7705
(2023)
•https://doi.org/10.1364/AO.497962

Integrating sphere port error in diffuse reflectance measurements

Luke J. Sandilands and Thomas Cameron

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Luke J. Sandilands and Thomas Cameron, "Integrating sphere port error in diffuse reflectance measurements," Appl. Opt. 62, 7700-7705 (2023)

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Table of Contents Category
- Instrumentation and Measurements
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About this Article
History
- Original Manuscript: June 15, 2023
- Revised Manuscript: September 11, 2023
- Manuscript Accepted: September 12, 2023
- Published: October 5, 2023

Abstract

The impact of a finite thickness integrating sphere port on the measurement of diffuse reflectance is addressed in a combined numerical and experimental study. It is shown that for a finite thickness port, additional light losses occur due to scattering between the sphere port wall and the test sample, causing the sample reflectance to be underestimated. Monte Carlo ray tracing is applied to obtain quantitative estimates of the resulting measurement error for the case of a diffusely reflecting sample. The effects of sample reflectance, port geometry, and illumination beam size on the measurement error are explored. Experimental data collected with a pair of integrating sphere reflectometers with different port geometries support the validity of the numerical results. It is argued that finite port thickness may be an important source of measurement error, even for a well-designed integrating sphere port, and a strategy for minimizing this error is discussed.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Term	Symbol
Incident and escaping flux	$ϕ_{i}$ , $ϕ_{e}$
Port wall reflectance	$ρ_{w}$
True sample reflectance	$ρ_{s}$
Apparent reflectance	$ρ_{s}^{'}$
Radiative transfer parameters	$κ_{0}$ , $κ_{1}$ , $κ_{2}$
Port error	$Δ ρ = ρ_{s}^{'} - ρ_{s}$
Port radius	$a$
Port thickness	$h$
Beam radius	$r$
Port aspect ratio	$h / 2 a$
Number of incident and escaping rays	$N_{i}$ , $N_{e}$

Parameter	Sphere A	Sphere B
Sphere radius [mm]	75	75
Port radius [mm]	12.5	11.3
Port thickness [mm]	0.75	$3.2 \pm 0.7$
Beam dimensions [mm]	$14.0 \times 7.5$	$7.0 \times 7.0$
Port aspect ratio	0.034	$0.142 \pm 0.031$

Term	Symbol
Incident and escaping flux	$ϕ_{i}$ , $ϕ_{e}$
Port wall reflectance	$ρ_{w}$
True sample reflectance	$ρ_{s}$
Apparent reflectance	$ρ_{s}^{'}$
Radiative transfer parameters	$κ_{0}$ , $κ_{1}$ , $κ_{2}$
Port error	$Δ ρ = ρ_{s}^{'} - ρ_{s}$
Port radius	$a$
Port thickness	$h$
Beam radius	$r$
Port aspect ratio	$h / 2 a$
Number of incident and escaping rays	$N_{i}$ , $N_{e}$

Parameter	Sphere A	Sphere B
Sphere radius [mm]	75	75
Port radius [mm]	12.5	11.3
Port thickness [mm]	0.75	$3.2 \pm 0.7$
Beam dimensions [mm]	$14.0 \times 7.5$	$7.0 \times 7.0$
Port aspect ratio	0.034	$0.142 \pm 0.031$

Abstract

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Applied Optics