Analysis Solutions for Quality Control of Hydrogen
Brochures and specifications | 2023 | ShimadzuInstrumentation
Hydrogen is emerging as a key energy vector for decarbonization, supporting fuel cells for power generation and transportation. Ensuring hydrogen quality is critical, as trace contaminants can poison catalysts, degrade materials, and impair system performance.
This work reviews analytical solutions for quality control of hydrogen across its lifecycle: impurity analysis in fuel and carrier systems, evaluation of hydrogen carriers, assessment of hydrogen embrittlement in metals, catalyst performance monitoring, and non-destructive testing of high-pressure hydrogen tanks.
Multiple advanced techniques address specific quality attributes:
GC-BID achieved CO detection limits below 0.1 ppm and bidirectional dual-detector GC systems enabled high-sensitivity batch analysis of hydrogen and trace hydrocarbons. FTIR delivered linear CO calibration (r2 > 0.999) at 0.25 cm−1 resolution. TOC analysis quantified organic impurities in ammonia water with ≤0.1 mg C/L accuracy. GC-BID methods detected ammonia at 1.2 ppm and methylamine at 2.5 ppm. GC-MS profiled 56 solvents including toluene/MCH with distinct TIC peaks. X-ray CT revealed progressive corrosion pits in copper pipes and CT-based structural data improved simulated composite elastic modulus accuracy from 59 % to 93 % agreement with tensile tests. EPMA and XPS exposed precious-metal distribution changes and oxide formation in degraded catalysts and MEAs. TMA measured polymer thermal expansion coefficients at cryogenic ranges, and universal testers with DIC characterized fatigue and delamination growth in gaskets and CFRP liners.
These analytical solutions enable compliance with ISO 14687-2019 hydrogen purity standards, rapid on-site catalyst and carrier assessments, materials integrity assurance for storage and transport, and predictive modeling for composite pressure vessels. Non-destructive methods reduce destructive sampling and support fast quality decisions in industrial and R&D environments.
Emerging directions include integration of real-time sensor networks for continuous hydrogen purity monitoring, machine-learning-driven defect detection in imaging data, multimodal instrumentation coupling for simultaneous chemical and structural insights, digital-twin-based lifecycle simulation of storage systems, and expanded use of portable analyzers in field deployments.
Comprehensive analytical platforms covering chromatography, spectroscopy, imaging, and mechanical testing form a robust toolkit for hydrogen quality control. These solutions underpin reliable, efficient, and safe development of a hydrogen energy infrastructure.
GC, GC/MSD, FTIR Spectroscopy, X-ray, TOC
IndustriesEnergy & Chemicals
ManufacturerShimadzu
Summary
Importance of the Topic
Hydrogen is emerging as a key energy vector for decarbonization, supporting fuel cells for power generation and transportation. Ensuring hydrogen quality is critical, as trace contaminants can poison catalysts, degrade materials, and impair system performance.
Objectives and Study Overview
This work reviews analytical solutions for quality control of hydrogen across its lifecycle: impurity analysis in fuel and carrier systems, evaluation of hydrogen carriers, assessment of hydrogen embrittlement in metals, catalyst performance monitoring, and non-destructive testing of high-pressure hydrogen tanks.
Methodology and Instrumentation
Multiple advanced techniques address specific quality attributes:
- Gas chromatography with barrier discharge ionization detector (GC-BID) for sub-ppm CO, CH4 and air-component profiling in hydrogen.
- GC-MS with PLOT columns for simultaneous detection of inorganic gases (N2, N2O, O2) and light hydrocarbons.
- Fourier transform infrared spectroscopy (FTIR) at high resolution for real-time CO quantification.
- Total organic carbon analyzer for trace organics in ammonia solutions.
- GC-BID methods for ppm-level ammonia and hydrogen in aqueous and organic carrier media.
- GC-MS for profiling organic hydrogen carriers and dehydrogenation products such as toluene and MCH.
- Microfocus X-ray CT for 3D visualization of corrosion, cracks, voids, and fiber orientation in composite components.
- Fatigue and endurance testing machines combined with non-contact extensometry to characterize gasket fatigue under compression.
- Energy dispersive X-ray fluorescence (EDX) for non-destructive multilayer plating thickness measurement and repeatability studies.
- Transportable gas analyzers for on-site monitoring of reforming catalysts via CO and CO2 dynamics.
- Electron probe microanalysis (EPMA) and X-ray photoelectron spectroscopy (XPS) for mapping and chemical-state analysis of automotive catalysts and MEA degradation.
- Thermomechanical analysis for thermal expansion and shrinkage of polymer liners and separator films down to cryogenic temperatures.
- Precision universal testers and digital image correlation for interlaminar fracture toughness (DCB) in CFRP.
- Ultrasonic optical flaw detection for surface and near-surface delamination in heterogeneous tank materials.
Key Results and Discussion
GC-BID achieved CO detection limits below 0.1 ppm and bidirectional dual-detector GC systems enabled high-sensitivity batch analysis of hydrogen and trace hydrocarbons. FTIR delivered linear CO calibration (r2 > 0.999) at 0.25 cm−1 resolution. TOC analysis quantified organic impurities in ammonia water with ≤0.1 mg C/L accuracy. GC-BID methods detected ammonia at 1.2 ppm and methylamine at 2.5 ppm. GC-MS profiled 56 solvents including toluene/MCH with distinct TIC peaks. X-ray CT revealed progressive corrosion pits in copper pipes and CT-based structural data improved simulated composite elastic modulus accuracy from 59 % to 93 % agreement with tensile tests. EPMA and XPS exposed precious-metal distribution changes and oxide formation in degraded catalysts and MEAs. TMA measured polymer thermal expansion coefficients at cryogenic ranges, and universal testers with DIC characterized fatigue and delamination growth in gaskets and CFRP liners.
Benefits and Practical Applications
These analytical solutions enable compliance with ISO 14687-2019 hydrogen purity standards, rapid on-site catalyst and carrier assessments, materials integrity assurance for storage and transport, and predictive modeling for composite pressure vessels. Non-destructive methods reduce destructive sampling and support fast quality decisions in industrial and R&D environments.
Future Trends and Potential Applications
Emerging directions include integration of real-time sensor networks for continuous hydrogen purity monitoring, machine-learning-driven defect detection in imaging data, multimodal instrumentation coupling for simultaneous chemical and structural insights, digital-twin-based lifecycle simulation of storage systems, and expanded use of portable analyzers in field deployments.
Conclusion
Comprehensive analytical platforms covering chromatography, spectroscopy, imaging, and mechanical testing form a robust toolkit for hydrogen quality control. These solutions underpin reliable, efficient, and safe development of a hydrogen energy infrastructure.
References
- ISO 14687-2019 Hydrogen Fuel – Product Specification
- SIP Energy Carriers: JST News April 2019
- NMIJ CRM 5208-a Multi-layer Plating Reference Material
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