The problem of the synthesis of new type nanomaterials in the form of nano-coatings with sub-nanometric heterogeneity has been formulated. It has been presented an analysis of influences of physical vapor deposition in ultrahigh vacuum on the process of intermixing a film with a substrate, including the results, which has been obtained under the formation of transition metal – silicon interface. The generalization of the obtained experimental results develops an approach to the development of new nano-coatings with low-dimensional heterogeneity. The principles of constructing such low-dimensional nano-coatings, their properties and possible applications are considered. 

1. Hannink RHJ, Hill AJ (editors). Nanostructure control of materials. Cambridge: Woodhead Publishing Limited; 2006. p. 368.

2. Voorhoeve RJH. Molecular beam deposition of solids on surfaces: Ultrathin films. In: Treatise on Solid State Chemistry. Boston, MA: Springer; 1976. p. 241–342.

3. O’Connor DJ, Sexton BA, Smart RSC (editors). Surface analysis methods in material science. New York/Berlin: Springer Verlag; 1992. p. 480.

4. Katayama M, Lifshits VG, Saranin AA, et al. Surface science. An introduction. Berlin: Spriner-Verlag; 2003. p. 440.

5. Henini M (editor). Molecular beam epitaxy: from research to mass production. London: Elsevier; 2012. p. 744.

6. Plyusnin NI, Il’yashchenko VM, Krylov SV, et al. Effect of incident atomic beam power on the formation of a Fe/Si(111)7×7 interface. Technical Physics Letters 2007; 33: 486–489.

7. Plusnin NI. Atomic-scale control of molecular-beam growth of nanolayers. In: Comprehensive Guide for Nanocoatings Technology, Characterization and Reliability. New York: Nova Science Publishers Inc.; 2015. p. 87–101.

8. Plyusnin NI, Tarima NA, Il’yashchenko VM, et al. The effect of underlayer-modified atomic monolayer on the mechanism of subsequent film growth. Technical Physics Letters 2012; 38: 324–327.

9. Plusnin NI. Application of AES and EELS for surface/interface characterization. Journal of Electron Spectroscopy and Related Phenom 2004; 137-140: 161–164.

10. Plusnin NI. The use of AES and EELS for complex analysis of two-dimensional coatings and their gro- wth process. Modern Electronic Materials 2017; 3(4): 131–141.

11. Plyusnin NI. From physics of the interface formation to low–dimensional nanocoatings and nanomaterials based on them. VESTNIK of Far East Branch of Russian Academy of Science 2016; 4(188): 27–35. Available from: https://cyberleninka.ru/article/n/ot-fizki-formirovaniya-granitsy-razdela-k-nizkorazmernym-nanopokrytiyam-i-materialam-na-ih-osnove.

12. Plusnin NI, Galkin NG, Lifshits VG, et al. Formation of interfaces and templates in the Si(111)-Cr system. Surface Review and Letters 1995; 2(4): 439–449.

13. Plusnin NI, Il’iashchenko VM, Kitan’ SA, et al. Metal thin-film nanophases and their interface with silicon. Journal of Physics: Conference Series 2008; 100(5).

14. Plyusnin NI, Il’yashchenko VM, Kitan’ SA, et al. Formation, electronic structure, and stability of film nanophases of transition metals on silicon. Journal of Surface Investigation. X-Ray, Synchrotron and Neutron Techniques 2009; 3(5): 734–746.

15. Plyusnin NI. Atomic-scale AES-EELS analysis of structure-phase state and growth mechanism of layered nanostructures. Advances in Materials Physics and Chemistry 2016; 6(7): 195–210.

16. Plyusnin NI. Metallic nanofilms on single crystal silicon: Growth, properties and applications. Modern Electronic Materials 2017; 3(2): 57–65.