by G. Abrasonis, R. Gago, M. Vinnichenko, U. Kreissig, A. Kolitsch and W. Möller
Abstract:
The atomic arrangement in sp2-dominated carbon (C) and carbon nitride (CNx) thin films has been studied by Raman spectroscopy as a function of substrate temperature and, in the case of CNx, different N incorporation routes (growth methods). In this way, materials composing graphitelike, fullerenelike (FL), and paracyanogenlike structures have been compared. The results show that each type of arrangement results in a characteristic set of the Raman spectra parameters, which describe the degree of aromatic clustering, bond length, and angle distortion and order in sixfold structures. In the case of C films, the atomic structure evolves with substrate temperature from a disordered network to nanocrystalline planar graphitic configurations, with a progressive promotion in size and ordering of sixfold ring clusters. Nitrogen incorporation favors the promotion of sixfold rings in highly disordered networks produced at low temperatures, but precludes the formation of extended graphiticlike clusters at elevated substrate temperatures (textgreater700K). In the latter case, N introduces a high degree of disorder in sixfold ring clusters and enhances the formation of a FL microstructure. The formation and growth of aromatic clusters are discussed in terms of substrate temperature, N incorporation, growth rate, film-forming sources, and concurrent bombardment by hyperthermal particles during growth.
Reference:
G. Abrasonis, R. Gago, M. Vinnichenko, U. Kreissig, A. Kolitsch and W. Möller, “Sixfold ring clustering in $s{p}{textasciicircum}{2}$-dominated carbon and carbon nitride thin films: A Raman spectroscopy study”, Physical Review B, vol. 73, no. 12, pp. 125427.
Bibtex Entry:
@article{abrasonis_sixfold_2006, title = {Sixfold ring clustering in $s{p}{textasciicircum}{2}$-dominated carbon and carbon nitride thin films: {A} {Raman} spectroscopy study}, volume = {73}, shorttitle = {Sixfold ring clustering in $s{p}{textasciicircum}{2}$-dominated carbon and carbon nitride thin films}, url = {https://link.aps.org/doi/10.1103/PhysRevB.73.125427}, doi = {10.1103/PhysRevB.73.125427}, abstract = {The atomic arrangement in sp2-dominated carbon (C) and carbon nitride (CNx) thin films has been studied by Raman spectroscopy as a function of substrate temperature and, in the case of CNx, different N incorporation routes (growth methods). In this way, materials composing graphitelike, fullerenelike (FL), and paracyanogenlike structures have been compared. The results show that each type of arrangement results in a characteristic set of the Raman spectra parameters, which describe the degree of aromatic clustering, bond length, and angle distortion and order in sixfold structures. In the case of C films, the atomic structure evolves with substrate temperature from a disordered network to nanocrystalline planar graphitic configurations, with a progressive promotion in size and ordering of sixfold ring clusters. Nitrogen incorporation favors the promotion of sixfold rings in highly disordered networks produced at low temperatures, but precludes the formation of extended graphiticlike clusters at elevated substrate temperatures ({textgreater}700K). In the latter case, N introduces a high degree of disorder in sixfold ring clusters and enhances the formation of a FL microstructure. The formation and growth of aromatic clusters are discussed in terms of substrate temperature, N incorporation, growth rate, film-forming sources, and concurrent bombardment by hyperthermal particles during growth.}, number = {12}, urldate = {2017-07-21}, journal = {Physical Review B}, author = {Abrasonis, G. and Gago, R. and Vinnichenko, M. and Kreissig, U. and Kolitsch, A. and Möller, W.}, month = mar, year = {2006}, pages = {125427}, file = {APS Snapshot:E:\cmam_papers\files\487\PhysRevB.73.html:text/html;APS Snapshot:E:\cmam_papers\files\489\PhysRevB.73.html:text/html;APS Snapshot:E:\Usuarios\Administrator\Zotero\storage\33Z3A7U2\PhysRevB.73.html:text/html;APS Snapshot:E:\Usuarios\Administrator\Zotero\storage\W8S3UP62\PhysRevB.73.html:text/html}, }