Presence of Dispersant when dispersing multilayer carbon nanotubes CNTs

Researcher  and author: Dr.   (   Afshin Rashid)



Note: CNTs multilayer carbon nanotubes have large impurities in some samples,  such as graphene polymer particles, amorphous carbon, and  catalyst particles. The light absorption of these impurities is related to the spectrum  and it is necessary to quantitatively evaluate the elimination of the  field  absorption field, which in this case  is not possible and a little analysis will be associated with error  The third problem is due to the presence of  dispersant, which is dispersed when the  multilayer CNTs are dispersed, the presence of  which leads to misdiagnosis in quantitative detection of  SWCNT in the state.

When functional  groups are covalently placed on  multilayer CNTs, the absorption peaks are  significantly attenuated or even  disappear because the structure of the nanotube in some  hexagonal SP2s changes to the structure of the  parts of the SP3 structure  NIR-VIS-UV absorption spectroscopy has  two important uses: the rate of covalent reactions  and the selectivity of different nanotubes  Non-covalent doping or molecular adsorption  produces valence-like electrons (dopingP ) or saturation of the conduction band  (doping-n).




These non-covalent interactions  can affect the intensity of absorption peaks  When doping, electron  donors such as (Cs, K) or electron acceptors make  very similar changes in the spectrum  (-Br2 ) such as  NIR-vis-UV, both of which  attenuate electron transfer. Use absorption spectroscopy to estimate the abundance  of metallic and semiconductor species by comparing the  peaks intensity; Because the position of these resonant peaks depends on  chirality and diameter. For qualitative analysis  , absorption spectroscopy is excellent because  it shows the overall appearance of the sample composition; However, quantitative evaluation depends on (m, n) the absorption of nanotubes  for several possible reasons has it. It is reported that the ratio of extinction coefficients  for metal to semiconductor  SWCNTs is 0.352, which should be independent of the separation method  - 0.009 or starting material. However, the values ​​of the  extinction coefficients of SWCNTs reported in  scientific sources are not consistent and still better measurement methods are needed  to determine the extinction coefficient of different  nanotubes (m, n). Second, the  strong absorption of π in the short wavelength region makes the  resonant transitions not distinct. In addition, the complexity of courier overlap  is problematic. As a result, the presence of a large number of SWCNTs with different  (m, n) with unknown frequency along with  various errors along with data analysis, makes it possible  to quantitatively assess the concentration of specific species. (m, n) is difficult in the sample and only approximate data  is obtained.



Conclusion :
 CNTs multilayer carbon nanotubes have large impurities in some samples,  such as graphene polymer particles, amorphous carbon, and  catalyst particles. The light absorption of these impurities is related to the spectrum  and it is necessary to quantitatively evaluate the elimination of the  field  absorption field, which in this case  is not possible and a little analysis will be associated with error  The third problem is due to the presence of  dispersant, which is dispersed when the  multilayer CNTs are dispersed, the presence of  which leads to misdiagnosis in quantitative detection of  SWCNT in the state.
Researcher  and author: Dr.   (   Afshin Rashid)

PhD in Nano-Microelectronics