Tuning Superconductivity in ABO3 Type Multiferroic Nanocrystals
Abstract
We present a suitable ways for tuning superconductivity in type multiferroics nanocrystals. It is seen that as a smart materials, multiferroics nanocrystals present distinguishing properties including ferroelectricity, piezoelectricity, ferrotoroids, magneto electrics and ferromagnetism. The reasons for the existence of multiferroicity are interactions of photons with these analytic molecules, electron doping and crispr, which adds or alters the electronic, optical and magnetic properties dramatically. It is clarified that the existence of ferromagnetic, ferroelectric and piezoelectric in Multiferroic materials are consequence of magnetic anisotropy, dipole segregation and strain. The formations of copper pairs in Multiferroic nanocrystals are due to electron doping, photon activated tunneling, Zero field cooling and crispr methods are responsible for the resulting superconductivity. In addition, quantum phenomenon as photon assisted tunneling in multiferroics nanocrystals will reinforce the coupling of electron pair. Hence, the nature of superconductivity in giving Multiferroic nanocrystals is dealt in accordance to oxygen content and vacancies
Keywords
Full Text:
PDFReferences
Paweł Peczkowski et al., Characterization of the superconductor-Multiferroic type materials based on YBa2Cu3O7-δYMnO3 composites, 2019,V. 13, 01-938
Yen-Lin Huang et al., Anisotropic superconductivity induced by periodic Multiferroic domain patterns, Materials (2019) 11:73
Armin Kargol, Leszek Malkinski, and Gabriel Caruntu, Biomedical Applications of Multiferroic Nanoparticles, 2012, 65. PP. 90 - 113.
Shevchun A.F et al., Superconductivity in Hierarchical 3D Nanostructure Pb - In Alloys, Symmetry 2022, 14, 2142.
R.S. Dahiya, M. Valle, Robotic Tactile Sensing, 2013, 978-94-007-0579-1
P. Ravindran, dielectric and ferroelectric properties of materials, April 2014
Bai Sun et al., ABO3 Multiferroic perovskite materials for memristive memory and neuromorphic computing, Nanoscale Horiz., 2021, 6, 939 – 970
G. Ciofani and A. Menciassi, Piezoelectric nanomaterials for biomedical applications, 2012;9. 3. 13-16.
Lone et al. Multiferroic ABO3 Transition Metal Oxides Nanoscale Research Letters, (2019) 14:142
Simonov. V. l. Crystal, structure of high temperature superconductors, 1992. Vo1. 8.1
Adam Alfieri et al., nanomaterials for quantum information Science & Engineering, Electrical and Systems Engineering, University of Pennsylvania, Philadelphia, PA 19104, USA
M. A. Jalaja, Soma Dutta, Ferroelectrics and multiferroics for next generation photovoltaic, Adv. Mater. Lett. 2015, 6(7), 568-584
J Peng et al, New iron-based multiferroics with improper ferroelectricity J. Phys. D: Appl. Phys. 51 (2018) 243002
Bhavnagar H A. et al. Electronic and Photo electronic processes in Multiferroic Materials; 2014
Camille Blouzon, photoelectric and magnetic properties of Multiferroic domain walls in BiFeO3, Physics, 2016, No. 6
Shifeng Zhao, Advances in Multiferroic nanomaterials Assembled with Clusters, Volume 2015, 101-528, pp. 1-12
Changeling Lu, Single-phase multiferroics: new materials phenomena, and physics, National Science Review 2019, 6: 653- 668
D. Rubi et al. Ferromagnetism and increased ionicity in epitaxial grown TbMnO3 films, physical review, 2019, B. 79, 014416
Y. H Huang et al. Crystal & magnetic structure of the orthorhombic perovskite, Chem. Mater, 2006, 18, 8, 2130–2134
Sao Carlos, Growth of superconducting and ferroelectric heterostructures, 2018. 94p. 24-74.
T. H. Arima, Spin driven Ferroelectricity and Magneto-Electric Effects in Frustrated Magnetic Systems, J. Phy. Soc. Japan 80 (2011) 05200
Shuai Dong et al., Multiferroic materials and magneto electric physics: symmetry, entanglement, excitation, and topology, Advances in Physics, (2015) 64:5-6, 519-626
Chengliang Lu and Jun Ming Liu, a model system of type II- Multiferroics, 2016, 2, 213-224.
Emerson Coy, Growth and characterization of new Multiferroic materials, 2015
Jun - Jie Zhang, et al, type - II Multiferroic Hf2VC2F2 MXene Monolayer with High Transition Temperature, J. Am. Chem. Soc. 2018, 140, 30, 9768–9773
C. Lu et al., Single-phase multiferroics: new materials, phenomena & physics, NSR 2019, 6, 653-668
H. Ibach, et al., Introduction to solid states Physics, 2009, 7thedt. 299-369
A.K. Kundu, P. Nordblad, and C. N. R. Rao, J. Phys. Condens. Matter, 2006, 18, 4809
A. Moyses Luiz, Superconductivity; theory and applications; 2011, ISBN 978-953-307-151-0
S. Neeleshwar et al., Superconductivity in aluminum nanoparticles, Physica C, 2004, 408–410 209–210
Jacob Linder et al., Interplay between Superconductivity and Ferromagnetism on a Topological Insulator, 2021, 103, 47- 54
B.J. Kirby, D. Kan, A. Luykx et al. Anomalous ferromagnetism in thin films, J. Appl. Phys. 2009, V. 105, 07
Pankaj Sharma et al., Functional Ferroics Domain Walls for Nanoelectronics, Materials 2019, 12, 2927; doi: 10. 3390/ma12182927
Wang et al, Evidence for Majorana bound states in an iron-based superconductor, science 2018, 362, 333–335
Vitaley L. Ginzuberg, superconductivity & Super fluidity, 2006, ISBN 978-3-540-68004-8.
DOI: https://doi.org/10.37628/ijibb.v9i1.859
Refbacks
- There are currently no refbacks.