X-ray photoelectron spectroscopy and near-edge X-ray-absorption fine structure of C 60 polymer films

Abstract: We report core-level and valence-band X-ray photoelectron spectroscopy (XPS) and carbon K near-edge X-ray-absorption fine structure spectroscopy (NEXAFS) results of plasma-polymerized C 60 . In comparison with evaporated C 60 the C 1s peak is broader and asymmetric for the C 60 polymer and its shake-up satellites diminished. Furthermore, the features of the valence-band as well as the features of the π * antibonding orbitals of the C 60 polymer are broader and reduced in intensity. Changes in the electronic st… Show more

“…1d. 46 The results indicate that the hydrogen treatment can effectively reduce the oxides in the composite powders. 29,36,44,45 The prominent D peak is from the structural imperfections created by the attachment of epoxy, hydroxyl and epoxy groups on the carbon basal plane; 38 the G peak is corresponding to the rstorder scattering of the E 2g mode.…”

High apparent strengthening efficiency for reduced graphene oxide in copper matrix composites produced by molecule-lever mixing and high-shear mixing

“…1d. 46 The results indicate that the hydrogen treatment can effectively reduce the oxides in the composite powders. 29,36,44,45 The prominent D peak is from the structural imperfections created by the attachment of epoxy, hydroxyl and epoxy groups on the carbon basal plane; 38 the G peak is corresponding to the rstorder scattering of the E 2g mode.…”

High apparent strengthening efficiency for reduced graphene oxide in copper matrix composites produced by molecule-lever mixing and high-shear mixing

“…As shown in figure 4(b), the hexatriacontane C 1s lineshape is asymmetric and can be fit with four This gas versus solid approach to study vibrational asymmetry, also followed by Ramm et al with fullerene (C 60 ) [69], brought direct proof that each polymer has its own vibrational behavior upon photoionization, which leads to a different degree of asymmetry and a different number of components with different FWHM values in the corresponding C 1s spectra. It is also strongly suggested that the physical intrinsic aspects of a material, such as degrees of branching, unsaturation, crosslinking, crystallinity, and finally chemical environment may strongly impact the lineshapes and linewidths of the considered components [62].…”

“…Observable effects on the spectra References Vibrational excitation subsequent to core-level electron ejection Asymmetry in core-level lineshape inducing increase in FWHM, particularly marked if symmetric components are used for fitting [65][66][67][68][69] Average chemical bond angle disorder Core-level lineshape broadening, increase in FWHM of the fitting components [70,71] Variation in possible electron delocalization in alternant (sp2-sp3) carbons such as HOPG, subsequent to structural changes Core-level lineshape broadening, increase in FWHM of the fitting components [72] Crystallinity and polymer chain conformation…”

Challenges in the characterization of plasma polymers using XPS

“…As a result, the changes occurring here may represent photopolymerization. There are several reports of UPS in photopolymerized C 60 [5][6][7]], but the relationship with photopolymerization is unclear, and consistent results have not been obtained. As a result, the author measured UPS after photopolymerization by creating an epitaxial film on a MoS 2 (0001) substrate in an ultrahigh vacuum.…”

Electron spectroscopy of organic thin-film FETs