Lecture course "Integrated Nanophotonics" by Dmitry Fedyanin

Transcript

1. Integrated Nanophotonics Dmitry Yu. Fedyanin Laboratory of Nanooptics and Plasmonics,

   MIPT

2. 2 GENERAL INFORMATION Lecturer Dr. Dmitry Yu. Fedyanin Senior Research

   Fellow Editor at Scientific Reports (Nature Publishing Group) Editor at Journal of Physics Communications (IOP Publishing) + Dr. Adndrey Vyshnevyy and guests Contact information Email: [email protected] Web: www.mipt.ru/en/science/labs/nano/staff/fedyanin.php Course webpage mipt.ru/en/science/labs/nano/lecture-courses/integrated-nanophotonics.php

3. 3 My Research Ultrafast low-power nanoscale optoelectronics for high-performance computing,

   sensing technologies and energy-efficient lighting

4. 4 My Research - I.A. Khramtsov, M. Agio, D.Yu. Fedyanin,

   Dynamics of single-photon emission from electrically pumped color centers, Physical Review Applied 8, 024031 (2017). - D.Yu. Fedyanin, M. Agio, Ultrabright single-photon source on diamond with electrical pumping at room and high temperatures, New Journal of Physics 18, 073012 (2016). - S. Lagomarsino et al., Robust luminescence of the silicon-vacancy center in diamond at high temperatures, AIP Advances 5, 127117 (2015)

5. 5 My Research -D.Yu. Fedyanin et al., Ultralow-loss CMOS copper

   plasmonic waveguides, Nano Letters 16, 362 (2016). - A.A. Vyshnevyy, D.Yu. Fedyanin, Spontaneous emission and fundamental limitations on the signal-to-noise ratio in deep-subwavelength plasmonic waveguide structures with gain, Physical Review Applied 6, 064024 (2016). - A.A. Vyshnevyy, D.Yu. Fedyanin, Self- heating and cooling of active plasmonic waveguides, ACS Photonics 3, 51 (2016). - D.Yu.Fedyanin et al., Surface Plasmon Polariton Amplification upon Electrical Injection in Highly Integrated Plasmonic Circuits, Nano Lett. 12, 2459 (2012).

6. 6 My Research ACS Photonics 4, 790 (2017)

7. 7 GENERAL INFORMATION Course objectives • To introduce students to

   the fundamentals of photonics and light control at the nanoscale. • To give students the foundation so that they can freely use light in their research without fear. This includes both theory and experiment.

8. 8 COURSE OUTLINE • Historical aspects of integrated photonics: from

   the technology to components. • Propagation of photons in bulk media and in micro- and nanoscale waveguide and resonator structures. • Theoretical and numerical methods for the study of photonic structures. • Experimental techniques. • Generation, propagation and detection of photons in nanophotonics systems and nanophotonic circuits. • State of the art applications of integrated nanophotonics: optoelectronic microprocessors, AI chips and quantum computations.

9. 9 TEXTBOOKS 1. Л. А. Вайнштейн, Электромагнитные волны. — М.:

   Радио и связь, 1988. 2. L. N. Binh, Photonic Signal Processing: Techniques and Applications. — CRC, 2008. 3. G. Lifante, Integrated Photonics: Fundamentals. — Wiley, 2003. 4. R. G. Hunsperger, Integrated Optics. — Springer, 2010. 5. Т. Тамир, Интегральная оптика. — М.: Мир, 1978. T. Tamir, Integrated Optics, Springer, 1975. More books 1. С.А. Майер, Плазмоника. Теория и приложения. — М.: R&C Dynamics, 2011. 2. D. Marcuse, Theory of Dielectric Optical Waveguides. — Academic Press, 1974. 3. Т. Тамир, Волноводная оптоэлектроника. — М.: Мир, 1991. 4. A. Yariv, P. Yeh, Photonics: Optical Electronics in Modern Communications. — Oxford University Press, 2007. 5. P. Kok, B. W. Lovett, Introduction to Optical Quantum Information Processing. — Cambridge, 2010.

10. 10 GENERAL INFORMATION Grade 40% – semester work 60% –

    final examination at the end of the semester 40 – 49% – удвл.(3–4) 50 – 59% – хор. (5–7) 60 – 100% – отл. (8–10) Semester work 7 – 8 mini-examinations (~ every second week) homework (not graded but should help you to learn how to solve problems)

11. 12 NEXT CLASS We will see how the integrated photonics

    emerged and discuss its evolution from 1970s to the present time.