Department of Semiconductor Physics of the Physics Department at Novosibirsk State University

The Department of Semiconductor Physics at the Faculty of Physics, Novosibirsk State University, trains specialists for research work in the field of condensed matter physics, semiconductor physics and the physics of low-dimensional systems and nanostructures. It also provides knowledge enabling its graduates to participate in developing semiconductor technologies, improving existing and creating new opto-, micro- and nanoelectronic devices. The article describes the history of the creation of the department, the main stages of the formation of training courses and work on the organization of students’ research practice in the laboratories of Rzhanov Institute of Semiconductor Physics (ISP), which is the basic Institute for the department. An overview of the training courses taught at the department for the preparation of bachelors and masters is given. It is told about the scientific and technological achievements of ISP, and about unique measuring, analytical and technological equipment available in the laboratories of the Institute, which is the basis for organizing research work of students at a high scientific and methodological level.

1. Anniversary collection of selected pappers of the Rzhanov Institute of Semiconductor Physics (1964–2014). Eds. A. V. Latyshev, A. V. Dvurechenskii, A. L. Aseev. Novosibirsk, Parallel, 2014, 844 p. (in Russ.)

2. Latyshev A. V., Dvurechenskii A. V., Aseev A. L. Advances in Semiconductor Nanostructures: Growth, Characterization, Properties and Applications. Elsevier Inc, 2017. 527 p.

3. Latyshev A. V., Fedina L. I., Rogilo D. I., Sitnikov S. V., Kosolobov S. S. Atomically Controlled Silicon Surface. Novosibirsk, Parallel, 2016, 220 p.

4. Pchelyakov O. P., Dvurechenskii A. V., Latyshev A. V., Aseev A. L. Ge/Si heterostructures with coherent Ge quantum dots in silicon for applications in nanoelectronics. Semicond. Sci. Technol., 2011, vol. 26, no. 1, pp. 14–27.

5. Gusev G. M., Olshanetsky E. B., Kvon Z. D., Mikhailov N. N., Dvoretsky S. A., Portal J. C. Quantum Hall Effect near the Charge Neutrality Point in a Two-Dimensional Electron-Hole System. Phys. Rev. Lett., 2010, vol. 104, pp. 166401–166404.

6. Maier H., Ziegler J., Fischer R., Kozlov D., Kvon Z. D., Mikhailov N., Dvoretsky S. A., Weiss D. Ballistic Geometric Resistance Resonances in a Single Surface of a Topological Insulator. Nat. Commun., 2017, vol. 8, 2023.

7. Reimann J., Schlauderer S., Schmid C. P., Langer F., Baierl S., Kokh K. A., Tereshchenko O. E., Kimura A., Lange C., Güdde J., Höfer U., Huber R. Subcycle observation of lightwave-driven Dirac currents in a topological surface band. Nature, 2018. vol. 562, pp. 396–400.

8. Córdoba R., Baturina T. I., Sesé J., Mironov A. Yu., Teresa J. M. de, Ibarra M. R., Nasimov D. A., Gutakovskii A. K., Latyshev A. V., Guillamón I., Suderow H., Viera S., Baklanov M. R, Palacios J. J., Vinokur V. M. Magnetic field-induced dissipation-free state in superconducting nanostructures. Nat. Commun., 2013, vol. 4, 1437.

9. Photodetectors based on the cadmium-mercury-tellurium epitaxial system. Ed. Aseev A. L. Novosibirsk, SB RAS Publ., 2012, 258 p. (in Russ.)

10. Novotný O., Wilhelm P., Paul D., Kálosi Á., Saurabh S., Becker A., Blaum K., George S., Göck J., Grieser M., Grussie F., R. von Hahn, Krantz C., Kreckel H., Meyer C., Mishra P. M., Muell D., Nuesslein F., Orlov D. A., Rimmler M., Schmidt V. C., Shornikov A., Terekhov A. S., Vogel S., Zajfman D., Wolf A. Quantum-state-selective electron recombination studies suggest enhanced abundance of primordial HeH+. Science, 2019, vol. 365, no. 6454, pp. 676–679.