1.2 Thermogravimetric analysis of single walled carbon nanotubes  (Page 3/3)

[link] shows a typical TGA for a functionalized SWNT. In this case it is polyethyleneimine (PEI) functionalized SWNTs prepared by the reaction of fluorinated SWNTs (F-SWNTs) with PEI in the presence of a base catalyst.

In the present case the molecular weight of the PEI is 600 g/mol. When the sample is heated, the PEI thermally decomposes leaving behind the unfunctionalized SWNTs. The initial mass loss below 100 °C is due to residual water and ethanol used to wash the sample.

In the following example the total mass of the sample is 25 mg.

1. The initial mass, M _i = 25 mg = mass of the SWNTs, residues and the PEI.
2. After the initial moisture has evaporated there is 68% of the sample left. 68% of 25 mg is 17 mg. This is the mass of the PEI and the SWNTs.
3. At 300 °C the PEI starts to decompose and all of the PEI has been removed from the SWNTs at 370 °C. The mass loss during this time is 53% of the total mass of the sample. 53% of 25 mg is 13.25 mg.
4. The molecular weight of this PEI is 600 g/mol. Therefore there is 0.013 g / 600 g/mol = 0.022 mmole of PEI in the sample.
5. 15% of the sample is the residual mass, this is the mass of the decomposed SWNTs. 15% of 25 mg is 3.75 mg. The molecular weight of carbon is 12 g/mol. So there is 0.3125 mmole of carbon in the sample.
6. There is 93.4 mol% of carbon and 6.5 mol% of PEI in the sample.

Determination of the mass of a chemical absorbed by functionalized swnts

Solid-state ¹³ C NMR of PEI-SWNTs shows the presence of carboxylate substituents that can be attributed to carbamate formation as a consequence of the reversable CO ₂ absorption to the primary amine substituents of the PEI. Desorption of CO ₂ is accomplished by heating under argon at 75 °C.

The quantity of CO ₂ absorbed per PEI-SWNT unit may be determined by initially exposing the PEI-SWNT to a CO ₂ atmosphere to maximize absorption. The gas flow is switched to either Ar or N ₂ and the sample heated to liberate the absorbed CO ₂ without decomposing the PEI or the SWNTs. An example of the appropriate TGA plot is shown in [link] .

The sample was heated to 75 °C under Ar, and an initial mass loss due to moisture and/or atmospherically absorbed CO ₂ is seen. In the temperature range of 25 °C to 75 °C the flow gas was switched from an inert gas to CO ₂ . In this region an increase in mass is seen, the increase is due to CO ₂ absorption by the PEI (10000Da)-SWNT. Switching the carrier gas back to Ar resulted in the desorption of the CO ₂ .

The total normalized mass of CO ₂ absorbed by the PEI(10000)-SWNT can be calculated as follows;

Solution outline

1. Minimum mass = mass of absorbant = M _absorbant
2. Maximum mass = mass of absorbant and absorbed species = M _total
3. Absorbed mass = M _absorbed = M _total - M _absorbant
4. % of absorbed species= (M _absorbed /M _absorbant )*100
5. 1 mole of absorbed species = MW of absorbed species
6. Number of moles of absorbed species = (M _absorbed /MW of absorbed species)
7. The number of moles of absorbed species absorbed per gram of absorbant= (1g/M _total )*(Number of moles of absorbed species)

Solution

1. M _absorbant = Mass of PEI-SWNT = 4.829 mg
2. M _total = Mass of PEI-SWNT and CO ₂ = 5.258 mg
3. M _absorbed = M _total - M _absorbant = 5.258 mg - 4.829 mg = 0.429 mg
4. % of absorbed species= % of CO ₂ absorbed = (M _absorbed /M _absorbant )*100 = (0.429/4.829)*100 = 8.8%
5. 1 mole of absorbed species = MW of absorbed species = MW of CO ₂ = 44 therefore 1 mole = 44g
6. Number of moles of absorbed species = (M _absorbed /MW of absorbed species)= (0.429 mg / 44 g) = 9.75 μM
7. The number of moles of absorbed species absorbed per gram of absorbant =(1 g/M _total )*(Number of moles of absorbed species) = (1 g/5.258 mg)*(9.75)= 1.85 mmol of CO ₂ absorbed per gram of absorbant

Bibliography

• I. W. Chiang, B. E. Brinson, A. Y. Huang, P. A. Willis, M. J. Bronikowski, J. L. Margrave, R. E. Smalley, and R. H. Hauge, J. Phys. Chem. B , 2001, 105 , 8297.
• E. P. Dillon, C. A. Crouse and A. R. Barron, ACS Nano , 2008, 2 , 156.