Infrared Microscope AIMsight
Brochures and specifications | 2025 | ShimadzuInstrumentation
Infrared microscopy has become a cornerstone technique in materials characterization, contamination analysis and quality control. It enables non-destructive chemical identification and spatial mapping of microscopic features down to a few micrometers. Integrating advanced detectors, automated routines and spectral libraries enhances sensitivity, throughput and reproducibility, making this approach indispensable for research, industrial QA/QC and environmental monitoring.
This article reviews the AIMsight infrared microscope system, its integrated software modules and optional accessories. It highlights the system’s goals to automate sample loading, optimize signal-to-noise performance, streamline contaminant recognition and facilitate chemical imaging. The overview covers hardware configuration, software functionality, validation workflows and representative application examples in electronics, pharmaceuticals, packaging and microplastics analysis.
The AIMsight couples a wide-field visible camera with an FTIR microscope for combined visual and spectral observation. Key features include:
The AIMsight achieves best-in-class sensitivity for ultra-microanalysis, enabling acquisition of clean spectra from 10 µm beads and high-refractive-index samples such as carbon-loaded rubber. Automated contaminant recognition using a proprietary spectral library (patent JP 5205918) provides rapid identification of primary and secondary components without requiring user expertise. Chemical imaging of pharmaceutical powders and multi-layer films demonstrates spatial resolution of lactose, lipids and cellulose distributions. Microplastics mapping on PTFE filters correctly discriminates PE and PP particles of 20–40 µm size. Length measurement and spectrum advising functions further streamline analysis workflows.
By combining automated sample handling, guided diagnostics and self-validating software, the system minimizes user bias and training requirements. Real-world applications include:
Emerging developments will leverage M2M communication, IoT connectivity and AI-driven decision support to enable fully autonomous spectral imaging systems. Anticipated advances include cloud-based spectral libraries, real-time self-diagnosis, adaptive measurement protocols and expanded non-targeted screening capabilities. Integration with robotics and high throughput mapping will further boost productivity in routine and research environments.
The AIMsight infrared microscope platform delivers high sensitivity, automation and analytical versatility for micro-scale chemical analysis. Its modular instrumentation and software suite address diverse application demands, from contaminant identification to chemical imaging. By simplifying operation and ensuring data integrity, it supports consistent, high-quality results across industrial, environmental and research laboratories.
FTIR Spectroscopy, Microscopy
IndustriesManufacturerShimadzu
Summary
Importance of Topic
Infrared microscopy has become a cornerstone technique in materials characterization, contamination analysis and quality control. It enables non-destructive chemical identification and spatial mapping of microscopic features down to a few micrometers. Integrating advanced detectors, automated routines and spectral libraries enhances sensitivity, throughput and reproducibility, making this approach indispensable for research, industrial QA/QC and environmental monitoring.
Aims and Overview
This article reviews the AIMsight infrared microscope system, its integrated software modules and optional accessories. It highlights the system’s goals to automate sample loading, optimize signal-to-noise performance, streamline contaminant recognition and facilitate chemical imaging. The overview covers hardware configuration, software functionality, validation workflows and representative application examples in electronics, pharmaceuticals, packaging and microplastics analysis.
Methods and Instrumentation
The AIMsight couples a wide-field visible camera with an FTIR microscope for combined visual and spectral observation. Key features include:
- Detectors: Standard T2SL liquid-nitrogen-cooled MCT (30,000:1 S/N), optional peltier-cooled MCT or DLATGS for nitrogen-free operation.
- Objectives: ATR (Ge prism, 45°), grazing-angle (80°), Cassegrain for transmission/reflection, digital zoom up to 330×.
- Software: AMsolution for measurement and analysis; LabSolutions IR for database management (DB/CS compliant); modules for contaminant analysis, high-speed mapping, particle analysis, library creation, spectrum advising, length measurement and integration with KnowItAll.
- Validation: Automated performance checks against pharmacopeial standards (JP, USP, EP, ChP) using polystyrene films.
Main Results and Discussion
The AIMsight achieves best-in-class sensitivity for ultra-microanalysis, enabling acquisition of clean spectra from 10 µm beads and high-refractive-index samples such as carbon-loaded rubber. Automated contaminant recognition using a proprietary spectral library (patent JP 5205918) provides rapid identification of primary and secondary components without requiring user expertise. Chemical imaging of pharmaceutical powders and multi-layer films demonstrates spatial resolution of lactose, lipids and cellulose distributions. Microplastics mapping on PTFE filters correctly discriminates PE and PP particles of 20–40 µm size. Length measurement and spectrum advising functions further streamline analysis workflows.
Benefits and Practical Applications
By combining automated sample handling, guided diagnostics and self-validating software, the system minimizes user bias and training requirements. Real-world applications include:
- Failure analysis of electronic components: identifying rubber residues, fillers and plasticizers on button batteries.
- Pharmaceutical QA/QC: detecting foreign matter on tablets via transmission measurement in diamond cells.
- Packaging material characterization: layer thickness measurement and polymer identification in multi-layer films.
- Environmental monitoring: mapping and quantifying UV-degraded microplastics collected on filters.
Future Trends and Potential Uses
Emerging developments will leverage M2M communication, IoT connectivity and AI-driven decision support to enable fully autonomous spectral imaging systems. Anticipated advances include cloud-based spectral libraries, real-time self-diagnosis, adaptive measurement protocols and expanded non-targeted screening capabilities. Integration with robotics and high throughput mapping will further boost productivity in routine and research environments.
Conclusion
The AIMsight infrared microscope platform delivers high sensitivity, automation and analytical versatility for micro-scale chemical analysis. Its modular instrumentation and software suite address diverse application demands, from contaminant identification to chemical imaging. By simplifying operation and ensuring data integrity, it supports consistent, high-quality results across industrial, environmental and research laboratories.
References
- Shimadzu Corporation. AIMsight Infrared Microscope. First Edition January 2023.
- Kataoka T., Iga Y., Baihaqi R. A., et al. Geometric relationship between the projected surface area and mass of a plastic particle. Water Research. 2024;261:122061.
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