Citations (29)
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Read on this site (9)
S. A. Shcherbinin, M. A. Lugovaya, A. N. Reznichenko, D. I. Makarev & A. N. Rybyanets. (2021) Study of microstructure and electromechanical properties of ceramic-matrix piezocomposites PZT/α-Al2O3. Ferroelectrics 576:1, pages 70-74.
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M. A. Lugovaya, E. I. Petrova, I. A. Shvetsov, A. V. Nasedkin & A. N. Rybyanets. (2021) Microstructural features and electromechanical characteristics of ceramic-matrix piezocomposites. Ferroelectrics 575:1, pages 24-28.
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M. A. Lugovaya, E. I. Petrova, I. A. Shvetsov, S. A. Shcherbinin & A. N. Rybyanets. (2019) Finite difference simulation and experimental study of ultrasonic waves propagation in inhomogeneous piezoelectrically active composites. Ferroelectrics 539:1, pages 63-70.
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A. Nasedkin, A. Nasedkina & A. Rybyanets. (2017) Finite element simulation of effective properties of microporous piezoceramic material with metallized pore surfaces. Ferroelectrics 508:1, pages 100-107.
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A. A. Naumenko, M. A. Lugovaya, S. A. Shcherbinin & A. N. Rybyanets. (2015) Elastic Losses and Dispersion in Ceramic Matrix Composites. Ferroelectrics 484:1, pages 69-77.
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M. A. Bunin, A. N. Rybyanets, A. A. Naumenko, D. I. Sukhomlinov & A. E. Fedorovskiy. (2015) Piezoelectric Response from Porous Ferroelectric Ceramics at Low Drive Voltage. Ferroelectrics 475:1, pages 96-103.
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AndreyN. Rybyanets. (2011) Porous Piezoelectric Ceramics—A Historical Overview. Ferroelectrics 419:1, pages 90-96.
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A.N. Rybianets. (2007) New “Damped by Scattering” Ceramic Piezocomposites with Extremally Low QMValues. Ferroelectrics 360:1, pages 84-89.
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A.N. Rybianets & A.V. Nasedkin. (2007) Complete Characterization of Porous Piezoelectric Ceramics Properties Including Losses and Dispersion. Ferroelectrics 360:1, pages 57-62.
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Articles from other publishers (20)
M. A. Lugovaya, I. A. Shvetsov, N. A. Shvetsova, E. I. Petrova & A. N. Rybyanets. (2018) Microstructural Features and Electrophysical Characteristics of Ceramic–Crystal Matrix Composites. Bulletin of the Russian Academy of Sciences: Physics 82:3, pages 310-313.
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I. A. Shvetsov, E. I. Petrova, M. A. Lugovaya, N. A. Shvetsova, S. A. Shcherbinin & A. N. Rybyanets. 2018. Advanced Materials. Advanced Materials
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Andrey V. NasedkinAnna A. NasedkinaAndrey N. Rybyanets. (2017) Modeling and Computer Design of Piezoceramic Materials with Stochastic Microporous Structure and Local Alloying Pore Surfaces. Modeling and Computer Design of Piezoceramic Materials with Stochastic Microporous Structure and Local Alloying Pore Surfaces.
Anna Kudimova, Ivan Mikhayluts, Dmitryi Nadolin, Andrey Nasedkin, Anna Nasedkina, Pavel Oganesyan & Arcady Soloviev. (2017) Computer design of porous and ceramic piezocomposites in the finite element package ACELAN. Procedia Structural Integrity 6, pages 301-308.
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A. N. Rybyanets. 2016. Advanced Materials. Advanced Materials
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A. N. Rybyanets, A. A. Naumenko, G. M. Konstantinov, N. A. Shvetsova & M. A. Lugovaya. (2015) Elastic loss and dispersion in ceramic-matrix piezocomposites. Physics of the Solid State 57:3, pages 558-562.
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Andrey N. Rybyanets & Anastasia A. Naumenko. (2013) Nanoparticles Transport in Ceramic Matriсes: A Novel Approach for Ceramic Matrix Composites Fabrication. Journal of Modern Physics 04:08, pages 1041-1049.
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A. N. Rybyanets & A. A. Rybyanets. (2011) Ceramic piezocomposites: Modeling, technology, and characterization. IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control 58:9, pages 1757-1773.
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Andrey N. Rybyanets. (2011) Porous piezoceramics: theory, technology, and properties. IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control 58:7, pages 1492-1507.
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A. N. Rybjanets. (2010) Properties of PZT/PZT ceramic piezocomposites. Bulletin of the Russian Academy of Sciences: Physics 74:8, pages 1100-1103.
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Andrey N. Rybyanets, Tamara V. Domashenkina & Anastasia A. Rybyanets. (2010) Complex material constants for PZT/PZT ceramic composites. Complex material constants for PZT/PZT ceramic composites.
Andrey N. Rybyanets. (2010) Porous Piezoelectric Ceramics - A historical overview. Porous Piezoelectric Ceramics - A historical overview.
Andrey N. Rybyanets & Anastasia A. Rybyanets. (2010) Losses and dispersion in ceramic piezocompozites. Losses and dispersion in ceramic piezocompozites.
Andrey N. Rybyanets. (2010) Novel approach for fabrication of ceramic matrix piezocomposites. Novel approach for fabrication of ceramic matrix piezocomposites.
G. Iovane & A.V. Nasedkin. (2010) Modal analysis of piezoelectric bodies with voids. II. Finite element simulation. Applied Mathematical Modelling 34:1, pages 47-59.
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Andrey Ryby, Andrey Nasedkin, Tamara Domashenkina, Anastasia Rybyanets & Maria Lugovaya. (2009) Ceramic piezocomposites modeling and fabrication. Ceramic piezocomposites modeling and fabrication.
. 2009. Electromechanical Properties in Composite Based on Ferroelectrics. Electromechanical Properties in Composite Based on Ferroelectrics
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A. Rybianets, L. Kushkuley & Y. Eshel. (2006) P2O-4 New Low-Q Ceramic Piezocomposites for Ultrasonic Transducer Applications. P2O-4 New Low-Q Ceramic Piezocomposites for Ultrasonic Transducer Applications.
A. Rybianets, L. Kushkuley, Y. Eshel & A. Nasedkin. (2006) P1M-5 Accurate Evaluation of Complex Material Constants of Porous Piezoelectric Ceramics. P1M-5 Accurate Evaluation of Complex Material Constants of Porous Piezoelectric Ceramics.
A. Nasedkin, A. Rybjanets, L. Kushkuley, Y. Eshel & R. Tasker. (2005) Different approaches to finite element modeling of effective moduli of porous piezoceramics with 3-3 (3-0) connectivity. Different approaches to finite element modeling of effective moduli of porous piezoceramics with 3-3 (3-0) connectivity.