Confirmation of Reaction Mechanism Using 13CO2 (GCMS)
A variety of analytical methods are utilized to measure reaction products in research into artificial photosynthesis, in which high-energy substances are manufactured using photo catalysts and solar energy. These methods include GC, HPLC, and absorption photometry. Experiments utilizing isotope-labeled samples are an effective way of confirming and clarifying reaction mechanisms. Mass spectrometers demonstrate their worth in such measurements. This Data Sheet presents an example of the use of GC-MS to measure carbon monoxide, methanol, formaldehyde, formic acid, and other substances generated in carbon dioxide photo catalytic reduction under a methanol environment.
(1) Confirmation of Photo Catalytic Reduction Reaction Products Using 13CO2*
Fig. 1 shows examples of the use of GC-MS to measure carbon monoxide (molecular weight: 28), generated in a carbon dioxide reduction using a photo catalyst. Fig. 1A is the extracted ion chromatogram for CO in experiments using unlabeled CO2 (methanol solvent). Fig. 1B is the extracted ion chromatogram for CO in experiments using 13CO2 (methanol solvent).
In Fig. 1B, a peak can be confirmed at m/z 29 (13CO). However, a peak is likewise confirmed at m/z 28 (CO). From this, it is evident that in this reaction, the carbon monoxide generated from the carbon dioxide is part of the total carbon monoxide. The reaction mechanism for the photo catalytic reaction can be inferred by measuring the formaldehyde, a reaction product of 13CH3OH, and the formic acid, a reaction product of 13CO2 in a similar manner.
Note:
This data was provided by Professor Osamu Ishitani of the Department of Chemistry, Graduate School of Science and Engineering, Tokyo Institute of Technology.
Sekizawa,K; Maeda,K; Domen,K; Koike,K; Ishitani,O. J.Am.Chem.Soc, 2013, 135, 4596.
Artificial Z-Scheme Constructed with a Supramolecular Metal Complex and Semiconductor for the Photocatalytic Reduction of CO2
GC-MS | GCMS-QP2010 Ultra |
Column | RT®-;Msieve 5A (Length: 30 m, 0.32 mm I.D., df=30 µm, RESTEK P/N 19722)+ Rtx ®(5 m, 0.25 m I.D., df=0.5 µm, particle trap) connecting the press tight connector |
[GC] | [MS] | ||
Injection unit temperature | 200 °C | Interface temperature | 200 °C |
Column oven temperature | 35 °C (2 min) → (10 °C/min) → 150 °C (5 min) | Ion source temperature | 200 °C |
Injection mode | Split (50:1) | Measurement mode | Scan |
Control mode | Pressure (100 kPa) | Measurement range | m/z 10 to 100 |
Carrier gas | Helium | Event time | 0.3 sec |
Injection volume | 100 µL gas phase (using a gas tight syringe) | Ionization method | EI |
Ionization voltage | 70 V | ||
Emission current | 150 µA |
(2) Analysis of Methanol, Formaldehyde, and Formic Acid in Solution
Fig. 2 shows a sample measurement in which a mixed aqueous solution of methanol, formaldehyde, and formic acid was introduced directly to the GC-MS. A polar column was used for the separation, enabling these three components to be measured in the same analytical run. With these conditions, the 13C labeled compound and the non-labeled compound have the same retention time. The mass spectra for each of the 13C labeled components is shown in Fig. 3. With the 13C labeled samples, since the mass spectra obtained is only shifted by an m/z of 1, the existence of isotopes can be confirmed from the presence of the molecular ion.
GC-MS | GCMS-QP2010 Ultra |
Column | Rtx-WAX ®(Length: 60 m, 0.32 mm I.D., df=0.5 µm, RESTEK) |
[GC] | [MS] | ||
Injection unit temperature | 250 °C | Interface temperature | 250 °C |
Column oven temperature | 70 °C → (10 °C/min) → 240 °C (5 min) | Ion source temperature | 200 °C |
Injection mode | Split (50:1) | Measurement mode | Scan |
Control mode | Linear velocity (40 cm/sec) | Measurement range | m/z 10 to 100 |
Carrier gas | Helium | Event time | 0.3 sec |
Injection volume | 0.5 µL | Ionization method | EI |
Ionization voltage | 70 V | ||
Emission current | 150 µA |
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