High Volume Optical Component Testing
Applications | 2020 | Agilent TechnologiesInstrumentation
Manufacturers of multilayer optical coatings rely on precise measurement of thin film transmission and reflectance to ensure product performance. Traditional methods require separate instruments or reconfiguration between near-normal transmission and reflectance measurements, introducing alignment errors and sample repositioning uncertainties. The Agilent Cary 7000 Universal Measurement Spectrophotometer (UMS) with Solids Autosampler addresses these challenges by performing automated multi-angle photometric spectroscopy (MPS) on the same sample location without intervention.
This study demonstrates high-throughput, unattended measurement of optical properties for multiple uncoated fused silica samples. The goal is to validate the Cary 7000 UMS and Solids Autosampler for routine QA/QC workflows and to compare measured spectra against Fresnel theory predictions across a wide wavelength (250–2500 nm) and angle range.
Samples: 1 mm thick fused silica plates and an 11-sample holder (38 × 42.5 × 1 mm each).
Measurements: Absolute specular reflectance and direct transmittance at angles of incidence ±7° and ±45°, in S and P polarization. Data averaged between positive and negative AOI to correct system asymmetries. Absorptance A was calculated as 1–R–T.
Single-sample tests on a 1 mm silica plate yielded excellent agreement with Fresnel theory up to 82° AOI, with residuals within ±0.05%. Multi-sample analysis of 11 plates produced 16 spectra per sample in ~40 minutes, completing the full run in under 8 hours unattended. Residual errors at 1500 nm averaged 0.05% (standard deviation ~0.05%) across conditions. Key factors ensuring accuracy included angle averaging, precision sample mounting, and an initial baseline without drift correction.
The integrated UMS and autosampler enables rapid, cost-effective QA/QC for high-volume optical component production. Automated multi-angle data supports accurate reverse engineering of coating stacks, analysis of dielectric loss oscillations, and optimization of coating processes. Eliminating sample repositioning reduces systematic errors and enhances reproducibility.
Automated MPS is expected to become standard in industrial optics QA/QC, extending to complex multilayer and diffuse materials. Future developments may include integrated machine learning for real-time data evaluation, closed-loop feedback in coating deposition, and inline process monitoring for continuous quality control.
The Agilent Cary 7000 UMS with Solids Autosampler provides precise, reproducible multi-angle R/T measurements of fused silica in an unattended workflow, closely matching Fresnel predictions. This approach significantly reduces QA/QC time and cost while improving the depth of optical characterization for industrial coatings.
NIR Spectroscopy, UV–VIS spectrophotometry
IndustriesMaterials Testing
ManufacturerAgilent Technologies
Summary
Importance of the Topic
Manufacturers of multilayer optical coatings rely on precise measurement of thin film transmission and reflectance to ensure product performance. Traditional methods require separate instruments or reconfiguration between near-normal transmission and reflectance measurements, introducing alignment errors and sample repositioning uncertainties. The Agilent Cary 7000 Universal Measurement Spectrophotometer (UMS) with Solids Autosampler addresses these challenges by performing automated multi-angle photometric spectroscopy (MPS) on the same sample location without intervention.
Objectives and Study Overview
This study demonstrates high-throughput, unattended measurement of optical properties for multiple uncoated fused silica samples. The goal is to validate the Cary 7000 UMS and Solids Autosampler for routine QA/QC workflows and to compare measured spectra against Fresnel theory predictions across a wide wavelength (250–2500 nm) and angle range.
Methodology
Samples: 1 mm thick fused silica plates and an 11-sample holder (38 × 42.5 × 1 mm each).
Measurements: Absolute specular reflectance and direct transmittance at angles of incidence ±7° and ±45°, in S and P polarization. Data averaged between positive and negative AOI to correct system asymmetries. Absorptance A was calculated as 1–R–T.
Used Instrumentation
- Agilent Cary 7000 Universal Measurement Spectrophotometer (UV-Vis-NIR, 250–2500 nm, variable angle MPS)
- Agilent Solids Autosampler (32-position multi-sample, radial and rotational positioning, automated operation)
Main Results and Discussion
Single-sample tests on a 1 mm silica plate yielded excellent agreement with Fresnel theory up to 82° AOI, with residuals within ±0.05%. Multi-sample analysis of 11 plates produced 16 spectra per sample in ~40 minutes, completing the full run in under 8 hours unattended. Residual errors at 1500 nm averaged 0.05% (standard deviation ~0.05%) across conditions. Key factors ensuring accuracy included angle averaging, precision sample mounting, and an initial baseline without drift correction.
Benefits and Practical Applications
The integrated UMS and autosampler enables rapid, cost-effective QA/QC for high-volume optical component production. Automated multi-angle data supports accurate reverse engineering of coating stacks, analysis of dielectric loss oscillations, and optimization of coating processes. Eliminating sample repositioning reduces systematic errors and enhances reproducibility.
Future Trends and Applications
Automated MPS is expected to become standard in industrial optics QA/QC, extending to complex multilayer and diffuse materials. Future developments may include integrated machine learning for real-time data evaluation, closed-loop feedback in coating deposition, and inline process monitoring for continuous quality control.
Conclusion
The Agilent Cary 7000 UMS with Solids Autosampler provides precise, reproducible multi-angle R/T measurements of fused silica in an unattended workflow, closely matching Fresnel predictions. This approach significantly reduces QA/QC time and cost while improving the depth of optical characterization for industrial coatings.
References
- Death D.L.; Francis R.J.; Bricker C.; Burt T.; Colley C. The UMA: A new tool for Multi-angle Photometric Spectroscopy. OSA Topical Meeting on Optical Interference Coatings 2013.
- Tikhonravov A.V.; Amotchkina T.V.; Trubetskov M.K.; Francis R.J.; Janicki V.; Sancho-Parramon J.; Zorc H.; Pervak V. Optical characterization and reverse engineering based on multiangle spectroscopy. Appl. Opt. 2012, 51, 245–254.
- Amotchkina T.V.; Trubetskov M.K.; Tikhonravov A.V.; Janicki V.J.; Sancho-Parramon J.; Razskazovskaya O.; Pervak V. Oscillations in the spectral behavior of total losses (1–T–R) in dielectric films. Opt. Express 2012, 20, 16129–16144.
- Amotchkina T.V.; Trubetskov M.K.; Tikhonravov A.V.; Schlichting S.; Ehlers H.; Ristau D.; Death D.; Francis R.J.; Pervak V. Quality control of oblique incidence optical coatings based on normal incidence measurement data. Opt. Express 2013, 21, 21508–21522.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
Similar PDF
Optical Characterization of Materials Using Spectroscopy
2023|Agilent Technologies|Guides
Applications of UV-Vis-NIR Optical Characterization of Materials Using Spectroscopy Application Compendium
> Return to table of contents Table of contents Introduction 4 Optics 5 Characterizing Sub-Nanometer Narrow Bandpass Filters Evaluation of the Cary Specular Reflectance Accessory for…
Key words
optical, opticalreturn, returnreflectance, reflectancecontents, contentstable, tableangle, angleincidence, incidencemeasurements, measurementswavelength, wavelengthtransmittance, transmittancereflection, reflectionspectrophotometer, spectrophotometermeasurement, measurementcoating, coatingbeam
Quality Control of Beam Splitters and Quarter-Wave-Mirrors
2020|Agilent Technologies|Technical notes
Application Note Materials testing and research Quality Control of Beam Splitters and Quarter-Wave-Mirrors Multi-angle UV-Vis-NIR measurements of multiple layer optical coatings Author Introduction David Death Farinaz Haq Agilent Technologies, Australia Optical coatings and coating technologies have matured over many years…
Key words
incidence, incidencecoating, coatingmeasurements, measurementstransmittance, transmittancesitu, situnormal, normalcoatings, coatingsoptical, opticalreflectance, reflectancelayer, layerreverse, reverseengineering, engineeringaoi, aoisuprasil, suprasildeposited
Coated Wafer Mapping Using UV-Vis Spectral Reflection and Transmission Measurements
2020|Agilent Technologies|Applications
Application Note Materials testing and research Coated Wafer Mapping Using UV-Vis Spectral Reflection and Transmission Measurements Using an Agilent Cary 7000 Universal Measurement Spectrophotometer (UMS) with Solids Autosampler Author Travis Burt Farinaz Haq Agilent Technologies, Inc. Introduction Spectral reflection (R)…
Key words
zto, ztowafer, wafergap, gapband, bandtin, tintransmission, transmissiondiameter, diameterreflection, reflectionoxide, oxidezinc, zincangles, angleshipims, hipimsdcms, dcmsgraded, gradedmapping
Agilent Cary 7000 universal measurement spectrophotometer
2022|Agilent Technologies|Brochures and specifications
Advance Your Materials Agilent Cary 7000 universal measurement spectrophotometer
A More Powerful Approach to Measuring Solid Samples Do you measure the optical properties of coatings, thin films, optical components, solar cells, or glass? Do you measure reflectance AND transmission? Do…
Key words
optical, opticalreflectance, reflectancetransmission, transmissioncary, carynir, nirsolar, solarabsolute, absolutewavelength, wavelengthvis, viswinuv, winuvyour, yourmeasurements, measurementsmaterials, materialsmoving, movingscattering
