Microwave magnetoelectric effect in ferrite-piezoelectric structures YIG-GGG-PZT and YIG-GGG-PMN-PT

In this work, the microwave magnetoelectric effect in the layered ferrite-piezoelectric structures YIG-GGG-PZT and YIG-GGG-PMN-PT in the microwave range is studied. The active development of modern microwave technology leads to the study of new materials with different physical properties, as well as to the creation of new layered structures from these materials, which can be combined: magnetic and ferroelectric, magnetic and semiconductor, etc. As a result of the experimental study, the dependences of the microwave magnetoelectric effect, which manifests itself in the ferromagnetic resonance line shift, in the YIG-GGG-PZT and YIG-GGG-PMN-PT ferrite-piezoelectric structures were obtained. Based on the data obtained from the experimental study, it can be concluded that the effect of ferromagnetic resonance line shift can be used to develop a new generation of controllable microwave solid-state electronics devices, such as isolators, attenuators, circulators, phase shifters, filters, etc.

1. Sokolov O. V., Bichurin M. I., Lobekin V. N., Tatarenko A. S. Mikrovolnovyy magnitoelektricheskiy effekt v dvukhsloynykh strukturakh na osnove zhelezo-ittriyevogo granata, kvartsa i magnoniobata svintsa [Microwave magnetoelectric effect in two-layer structures based on yttrium iron garnet, quartz and lead magnoniobate] // Vestnik NovSU. 2019. 4(116). 92-95. 1. DOI: 10.34680/2076-8052.2019.4(116).92-95

2. Bichurin M. I., Sokolov O. V., Tatarenko A. S., Lobekin V. N., Leontiev V. S., Turutin A. V. Microwave Magnetoelectric Effect in a Two-Layer FeGaB/PZN-PT Structure // Microwave Conference (RMC): Proceedings of the 7th All-Russian Microwave Conference, Moscow, November 25–27, 2020. Moscow, 2020. P. 282-285. DOI: 10.1109/RMC50626.2020.9312260

3. Manicheva I. N., Filippov D. A., Laletin V. M. Magnitoelektricheskiy effekt vtrekhsloynoy strukture nikel'-kvarts-nikel' [Magnetoelectric effect in a nickel-quartz-nickel three-layer structure] // International Research Journal. 2019. 4(82), part 1. 27-32. DOI: 10.23670/IRJ.2019.82.4.005

4. Vyunik D. A., Kapustin V. G., Saveliev D. V., Fetisov L. Yu., Chashin D. V., Shabin P. A. Magnitoelektricheskiy effekt v sloistoy strukture p'yezoelektrikmagnitostriktsionnyy volokonnyy kompozit [Magnetoelectric effect in a layered structure of a piezoelectric-magnetostrictive fiber composite] // Lomonosov-2019: Materials of the XXVI International Youth Scientific Forum, Moscow, April 08–12, 2019. Moscow, 2019. P. 759-761. Available at: https://conf.msu.ru/archive/Lomonosov_2019/data/section_33_16302.htm (Accessed: 14.01.2023).

5. Lobekin V. N., Snisarenko D. V., Tatarenko A. S., Bichurin M. I. Issledovaniye magnitoelektricheskogo SVCH ventilya na osnove ferrit-p'yezoelektricheskikh struktur [Study of a magnetoelectric microwave valve based on ferrite-piezoelectric structures]. Vestnik NovSU. 2018. 1(107). 74-76.

6. Bichurin M. I., Sokolov O. V., Leontiev V. S., Petrov R. V., Tatarenko A. S., Semenov G. A., Ivanov S. N., Turutin A. V., Kubasov I. V., Kislyuk A. M., Malinkovich M. D., Parkhomenko Y. N., Kholkin A. L., Sobolev N. A. Magnetoelectric Effect in the Bidomain Lithium Niobate/Nicke / Metglas Gradient Structure // Physica Status Solidi (B) Basic Research. 2020. 257(3). 1900398. DOI: 10.1002/pssb.201900398

7. Leontiev V. S., Petrov R. V., Bozhkov S. T. Issledovaniye datchika polozheniya kolenchatogo vala na osnove kompozitnoy struktury LiNbO3 [Study of the crankshaft position sensor based on the LiNbO3 composite structure] // Vestnik NovSU. 2020. 2(118). 36-39. DOI: 10.34680/2076-8052.2020.2(118).36-39

8. Petrov V. M., Sergeev I. S. Girator v istochnikakh vtorichnogo elektropitaniya [Gyrator in secondary power sources] // Vestnik NovSU. 2018. 4(110). 19-24.

9. Bichurin M. I., Petrov V. M., Petrov R. V., Kapralov G. N., Kiliba Yu. V., Bukashev F. I., Smirnov A. Yu., Tatarenko A. S. Magnetoelectric microwave devices // Ferroelectrics. 2011. 280(1). 211-218. DOI: 10.1080/00150190214807

10. Petrov R. V., Leontiev V. S. Magnitoelektricheskiy magnitometr [Magnetoelectric magnetometer] // Vestnik NovSU. 2013. 75, vol. 1. 29-32.