Infopaket

Nanomaterials and structures based on them

ДВС.1.02.01

Вибіркова дисципліна для ОП

Second

2018/2019

2 Semester

4

The ability to build adequate models of chemical phenomena, to study them for obtaining new conclusions and deepening of understanding of nature, including using methods molecular, mathematical and computer modeling. Ability to organize, plan and implement a chemical experiment. The ability to interpret, objectively evaluate and present the results of one's work research. The ability to formulate new hypotheses and scientific problems in the field of chemistry, to choose directions and appropriate methods for their solution based on an understanding of modern issues research in the field of chemistry and taking into account the available resources. The ability to choose optimal research methods and techniques. Possession of the general methodology of carrying out scientific research.

Full-time form

The discipline is based on a cycle of disciplines of professional and practical training, in particular, such as "Electricity and Magnetism", "Optics", "Fundamentals of Solid State Physics", "Physical interactions in nanosystems", "Electrophysical, chemical and biological methods research".

The course examines in detail the properties of nanomaterials, the physical processes occurring under the action of an electric field in nanoscale structures, and the physics of the operation of semiconductor nanoelectronic devices. The main attention is directed to (a) physical properties of nanomaterials, basic information about nanoparticles, nanoclusters, nanostructures, (b) physical phenomena occurring in nanostructures under the influence of lighting and electric field (electric field shielding, electronic transport in thin and ultrathin semiconductors) and their use; (c) physical processes in semiconductor nanoelectronic devices, which determine their use in nanoelectronic systems.

1. Sze S.M., Ng Kwong K. Physics of semiconductor devices.- Wiley-Interscience, 2007 2. Sze S.M. Modern semiconductor device physics.- 1998 3. Benellmekki M., Elbe A. Nanostructured thin films. Fundamentals and applications.- Elsevier, 2019. 5. Zhuiykov S. Nanostructured semiconductors.- Elsevier, 2018. 6. Sze S.M. Modern semiconductor device physics.- Wiley-Interscience, 1998, 547 P. 7. Tiwari A., Uzum L. Advanced in functional materials.- Wiley,2015. 8. McGuire G.E. Characterization of Semiconductor materials.- Noyes Publications, 1989. 9. Evtukh, H. Hartnagel, O. Yilmazoglu, H. Mimura, D. Pavlidis. Vacuum Nanoelectronic Devices – Novel Electron Sources and Applications. John Wiley & Sons, Inc, 2015, 495 P. ISBN: 9781119037958 10. Готра З.Ю. та ін. Наноелектроніка. Львів-Ліга-Прес-2009, 342 С.

lectures, laboratory

- semester assessment: 1. Modular control work 1-20 points; 2. Modular control work 2- 20 points; 3. Modular control work 3- 20 points; - final evaluation in the form of an exam. - the maximum number of points that can be obtained by a student during the exam is 40 points on a 100-point scale;

Ukrainian