Selected publications:

Preliminary communications:

1. Gradov O. V., Gradova M. A. Multifactor response of the dispersed soft matter precursors under microwave-induced self-organization // Conf. PhysicA.SPb/2015. Section: “Devices and materials of the THz and microwave ranges” (At: Saint Petersburg, Ioffe Physical-Technical Institute of the Russian Academy of Sciences), ISBN 978-5-00071-389-1, DOI: 10.13140/RG.2.1.2321.8966. Short abstract
2. Gradov O. V. In situ tunable laser diode spectroscopy of the processes and products of the microwave-induced self-organization in the soft mater active media // 2nd International Conference and Exhibition on Mesoscopic and Condensed Matter Physics (Chicago, Illinois, USA [October 26-28, 2016]). Abstract
3. Gradov O. V. Application of the angular descriptors and radiation patterns in high frequency and microwave thermal analysis of anisotropic heterogeneous structures on a chip // Proc. RTAC-2016. — Vol. 2. — SPbPU Publisher, 2016. — P. 396. Proc. Content
4. Gradov O. V., Gradova M. A. [Microwave-induced self-organization of saturated ferric chloride solutions and colloidal suspensions] // In: Proc. [SupraZ-2015] (21 – 25 Sept. 2015). — 2015. — P. 78.
5. Gradov O. V., Gradova M. A. [Autowave measurements in cases of microwave self-organization] // In: Proc. [Microwave microelectronics – 2012; At: Saint Petersburg Electrotechnical University] (4-12 June 2012). — P. 371–376.

Datasets:

1. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. I. Prussian blue (2.45 GHz; 450 W; 3 min) // Pangaea. — 2019. DOI: 10.1594/PANGAEA.897646
2. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. II. Prussian blue (conentrated sol; 2.45 GHz | 450 W | 2 min). Erosion and reticulation //Pangaea. — 2019. DOI: 10.1594/PANGAEA.897647
3. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. III. FeCl3 colloid (200 W, 2.45 GHz,1 min) // Pangaea. — 2019. DOI: 10.1594/PANGAEA.897648
4. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. IV. FeCl3 colloid (450 W, 2.45 GHz) // Pangaea. — 2019. DOI: 10.1594/PANGAEA.897649
5. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. IX. Diluted FeOOH sol obtained from FeCl3 and Na2CO3 solutions (2.45 GHz; 450 W; 1 min; check experiment) // Pangaea. — 2019. DOI: 10.1594/PANGAEA.897650
6. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. V. FeCl3 colloid (800 W, 2.45 GHz, 30 sec.) // Pangaea. — 2019. DOI: 10.1594/PANGAEA.897651
7. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. VI. Saturated FeOOH sol obtained from FeCl3 and Na2CO3 solutions (2.45 GHz; 200 W; 1 min) // Pangaea. — 2019. DOI: 10.1594/PANGAEA.897652
8. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. VII. Diluted FeOOH sol obtained from FeCl3 and Na2CO3 solutions (2.45 GHz; 200 W; 1 min) //Pangaea. — 2019. DOI: 10.1594/PANGAEA.897653
9. Gradov O. V., Gradova M. A. Microwave-induced self-organization in mineral systems. VIII. Diluted FeOOH sol obtained from FeCl3 and Na2CO3 solutions (2.45 GHz; 300 W; 1 min) // Pangaea. — 2019. DOI: 10.1594/PANGAEA.897654
10. Gradov O. V., Gradova M. A. EHF-electrochemistry of the mineralized ferric chloride solutions // Koninklijke Nederlandse Akademie van Wetenschappen (KNAW), Data Archiving and Networked Services (DANS-KNAW). — 2019. DOI: 10.17632/pgj9wjwpmd.1 XML Code EHF-electrochemistry of the mineralized ferric chloride solutions (Abstract)