High-Sensitivity Analysis of Formic Acid in Methanol Solution Using Jetanizer
Applications | 2025 | ShimadzuInstrumentation
Formic acid is a key impurity in methanol used in green energy research, especially artificial photosynthesis. Accurate quantification at trace levels is critical for developing hydrogen and organic compound synthesis from CO2.
This study demonstrates a straightforward gas chromatography method to detect formic acid in methanol at low ppm concentrations by using a Jetanizer as the FID nozzle. It aims to simplify installation and improve sensitivity.
The method involves phosphoric acid treatment of the GC inlet and column to prevent adsorption of formic acid. A conventional GC-FID (Shimadzu Nexis GC-2030) is modified by replacing the FID nozzle with a Jetanizer, which contains a built-in catalyst for methanization.
The method achieved linear calibration for formic acid from 1 to 1000 ppm with R2 of 0.9998. At the low end (1 ppm), the peak was distinct after treatment steps. Reproducibility tests showed relative standard deviations below 2.3% across concentrations. Continuous analysis at 10 ppm yielded stable peak areas over five runs.
By simply swapping the standard FID nozzle for a Jetanizer, laboratories can attain ppm-level detection without extensive hardware modifications. This cost-effective upgrade is ideal for quality control in chemical synthesis, environmental monitoring, and green transformation research.
The integration of catalyst-based detectors like the Jetanizer in routine GC platforms may expand to analyze other volatile acids and trace gases. Ongoing development could focus on miniaturized reactors, automated conditioning protocols, and coupling with mass spectrometry for broader compound coverage.
This work presents an accessible GC-FID approach for high-sensitivity formic acid analysis in methanol. Phosphoric acid pre-treatment and the Jetanizer nozzle enable reliable quantification at trace levels, supporting impurity screening in energy and industrial applications.
GC
IndustriesEnergy & Chemicals
ManufacturerShimadzu
Summary
Significance of the Topic
Formic acid is a key impurity in methanol used in green energy research, especially artificial photosynthesis. Accurate quantification at trace levels is critical for developing hydrogen and organic compound synthesis from CO2.
Objectives and Study Overview
This study demonstrates a straightforward gas chromatography method to detect formic acid in methanol at low ppm concentrations by using a Jetanizer as the FID nozzle. It aims to simplify installation and improve sensitivity.
Methodology and Instrumentation
The method involves phosphoric acid treatment of the GC inlet and column to prevent adsorption of formic acid. A conventional GC-FID (Shimadzu Nexis GC-2030) is modified by replacing the FID nozzle with a Jetanizer, which contains a built-in catalyst for methanization.
- Instrument: Nexis GC-2030 with Flame Ionization Detector (Jetanizer nozzle)
- Column: SH-PolarWax (30 m × 0.32 mm I.D., 1.0 µm film)
- Carrier gas: Helium at constant linear velocity (35 cm/s)
- Injection: Split 1:2, 1 µL sample volume
- Temperature program: 80 °C ramp to 130 °C at 5 °C/min, then to 230 °C at 15 °C/min
- Detector temperatures: 400 °C with specific hydrogen, air, and make-up gas flows
Main Results and Discussion
The method achieved linear calibration for formic acid from 1 to 1000 ppm with R2 of 0.9998. At the low end (1 ppm), the peak was distinct after treatment steps. Reproducibility tests showed relative standard deviations below 2.3% across concentrations. Continuous analysis at 10 ppm yielded stable peak areas over five runs.
Benefits and Practical Applications
By simply swapping the standard FID nozzle for a Jetanizer, laboratories can attain ppm-level detection without extensive hardware modifications. This cost-effective upgrade is ideal for quality control in chemical synthesis, environmental monitoring, and green transformation research.
Future Trends and Applications
The integration of catalyst-based detectors like the Jetanizer in routine GC platforms may expand to analyze other volatile acids and trace gases. Ongoing development could focus on miniaturized reactors, automated conditioning protocols, and coupling with mass spectrometry for broader compound coverage.
Conclusion
This work presents an accessible GC-FID approach for high-sensitivity formic acid analysis in methanol. Phosphoric acid pre-treatment and the Jetanizer nozzle enable reliable quantification at trace levels, supporting impurity screening in energy and industrial applications.
Reference
- Assessment of Jetanizer and Quantitative Analysis of CO2 and CH4 in the Atmosphere, Application News No. 01-00599-en
- Analysis of Trace Carbon Monoxide in Hydrogen Fuel Using Jetanizer, Application News No. 01-00638-en
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