Encapsulation of iron atoms between framgments of graphene planes

In this paper, we apply results of analysis of the Raman spectrum from an amorphous carbon film modified with iron (a − C : F e) which leads to construction of clusters containing fragments of graphene and a layer of iron atoms. Such clusters may be candidates for the role of microwave radiation absorbers. For the Raman experiments we performed deposition of a thin film of a − C : F e. Details of the film deposition process, together with the corresponding Raman experiments are presented in this paper. Comparison with a literature model was performed for the intensity ratio of the maxima for specific Raman bands, using the letter D to represent “disorder” and the letter G to represent “graphite”. Comparison gives evidence for the existence of nanosize fragments of graphene embedded in an amorphous matrix of the a − C : F e film. The diameter of the fragments is predicted to attain a value of about 1.2 nm. Moreover, in a comparison with experimental data for defective graphite, the position of the maximum of the D band for a−C : F e appeared to be red shifted. This could support the proposition that damping of Raman-active oscillations occurs by an electron gas in fragments of graphene after introduction of iron, e.g. after intercalation. On the basis of these estimates, we modeled a symmetrical polycyclic aromatic hydrocarbon having a similar size and converted it into fragment of a graphene plane by removal of hydrogen atoms occupying the edge states. To preserve symmetry, we placed atoms of iron on top of the fragment, situating them exactly above the centers of hexagons at a certain distance and placed another fragment of graphene on the top of the iron atoms, symmetrically. For a distance of 2.52 ˚Abetween the centers of the hexagon and the iron atom, distortions of carbon-carbon valence bonds and angles were found to be minimal, as shown through optimization of the system’s geometry using the Avogadro molecular editor. This result supports an hypothesis of graphene fragments during the growth of an amorphous carbon film modified by simultaneous addition of a dopant metal such as iron. This example may illustrate the stability of a two-dimensional electron gas confined between the fragments. 

1. Kosugi K., Bushiri M. J., Nishi N. Formation of air stable carbon-skinned iron nanocrystals from F eC2. Appl. Phys. Lett, 2004, 84, P. 1753–55.

2. Zhao J., Deng Q., Bachmatiuk A., et al. Free-Standing Single-Atom-Thick Iron Membranes Suspended in Graphene Pores. Science, 2014, 343, P. 1228–32.

3. Ivanov-Omskii V. I., Smorgonskaya E. A. Charge displacement induced by intercalation of graphite-like nanoclusters in amorphous carbon with copper. Physics of the Solid State, 1999, 41(3), P. 786–88.

4. Ivanov-Omskii V. I., Smorgonskaya E. A. Modification of the electron spectrum and vibrational properties of amorphous carbon by copper doping. Semiconductors, 1998, 32(8), P. 831–37.

5. Ivanov-Omskii V. I., Zvonareva T. K., Frolova G. S. Vibration modes of carbon in hydrogenated amorphous carbon modified with copper. Semiconductors, 2000, 34(12), P. 1391–96.

6. Zvonareva T. K., Ivanova E. I., Frolova G. S. et al. Vibratonal spectroscopy of aC : H(Co). Semiconductors, 2002, 36(6), P. 695–00.

7. Ivanov-Omskii V. I., Frolova G. S. IR spectroscopy of copper-intercalated graphite nanoclusters in amorphous carbon. Tech. Phys. Lett., 2000, 26(7), P. 623–24.

8. Lutsev L. V., Yakovlev S. V., Zvonareva T. K. et al. Microwave properties of granular amorphous carbon films with cobalt nanoparticles. J. Appl. Phys., 2005, 97, P. 104327/1-6.

9. Alexeev A. G., Shtager E. A., Kozyrev S. V. Physical Principles of Stealth Technology. St.Petersburg.: VVM, 2007. 283 p.

10. Draine B. T., Lazarian A. Magnetic dipole microwave emission from dust grains. Astrophys. J., 1999, 512, P. 740–54.

11. Yastrebov S. G, Ivanov-Omskii V. I., Pop V, et al. Magnetic properties of iron-modified amorphous carbon. Semiconductors, 2005, 39(7), P. 840–44.

12. Bohren C. F., Huffman D. R. Absorption and Scattering of Light by Small Particles. Weinheim.: WileyVCH Verlag GmbH, 1998, 545 p.

13. Belenkov E. A. Formation of Graphite Structure in Carbon Crystallites. Inorganic Materials, 2001, 37(9), P. 928–34.

14. Lucchese M. M., Stavale F, Ferreira Martins E. H., Vilani C. et al Quantifying ion-induced defects and Raman relaxation length in graphene. Carbon, 2010, 4(8), P. 1592–97.

15. Cancado L. G., Jorio A., Ferreira Martins E. H. et. al. Quantifying Defects in Graphene via Raman Spectroscopy at Different Excitation Energies. Nanoletters, 2011, 11(8), P. 3190–3196.

16. Hanwell M. D., Curtis D. E., Lonie D. C., et al. Avogadro: An advanced semantic chemical editor, visualization, and analysis platform. J Cheminform, 2012, 4(1), P. 1–17.

17. Swanepoel R. Determination of the thickness and optical constants of amorphous silicon. J. Phps. E: Sci. Instrum., 1983, 16, P. 1214–33.

18. Ferrari A. C. Raman spectroscopy of graphene and graphite: Disorder, electron-phonon coupling, doping and nonadiabatic effects. Solid State Communications, 2007, 143, P. 47–57

19. Alberty R., A., Chung M., B., Reif A. K. Standard Chemical Thermodynamic properties of Polycyclic Aromatic Hydrocarbons and their Isomer Groups. III. Naphthocoronene Series, Ovalene Series, and First Members of Some Higher Series. Phys Chem Ref Data, 1990, 19(2), P. 350–70.

20. Yamamoto R., Shibuta H., Doyama M. Computer simulation of radiation damage in amorphous metals. J.Nucl.Mater., 1979, 85-86, P. 603–06.

21. Wang L., Hudson G. A. Advanced Molecular Dynamics Simulations on the Formation of Transition Metal Nanoparticles. In: Molecular Dynamics - Theoretical Developments and Applications in Nanotechnology and Energy; Ed. Lichang Wang L.- INTECH Open Access Publisher, 2012, 424 p.

22. Cervantes-Salguero K., Seminario J. M. Structure and energetics of small iron clusters. J. Mol. Model., 2012, 18, P. 4043–52.

23. H¨olzl J., Schulte F. K. Work function of metals In Solid Surface Physics. Springer Tracts in Modern Physics, 2006, 85, P. 1–150

24. Kuroda H. Ionisation potential of polyciclic aromatic hydrocarbons. Nature, 1964, P. 1214–15.

25. Robertson J., O’Reilly E. P. Electronic and atomic structure of amorphous carbon. Phys.Rev.B, 1987, 35(6), P. 2946–57.