Abstract
A theoretical analysis of the effect of the magnetostatic interaction on the temperature dependence of the hysteresis characteristics and various types of remanent magnetization of the decay products of the titanomagnetite nanoparticle system is carried out. It is established that the magnetic interactions between nanoparticles with an effective field of less than the coercive field leads to an insignificant decrease in the temperature dependence of the hysteresis characteristics. An increase in the degree of decay of titanomagnetite (the size of the magnetite core of the nanoparticle) lowers the dependence of the hysteresis characteristics on temperature. In addition, it is shown that an increase in the intensity of the magnetic interactions leads to a drop in the thermo-remanent and chemical remanent magnetizations, regardless of the degree of decay of titanomagnetite. The thermal and chemical remanent magnetizations to the ideal ratios (\(R_{t}\) and \(R_{c}\)) increases with increasing magnetostatic interaction, while the increase in the degree of decay leads to a decrease in the values of \(R_{t}\) lying in the range \(0.8 \,\le\, R_{t} \, \le\, 1.4\) and an increase in \(R_{c}\), which is limited by the relation \(0 \,<\, R_{c} \,\le\, 0.9.\)
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References
Afremov L., Anisimov S., Iliushin I., Size effect on the hysteresis characteristics of a system of interacting core/shell nanoparticles. JMMM, 2018, 447, pp 88–95.
Afremov L.L., Belokon V.I. Kirienko Yu.V., Nefedev K.V., Magnetic properties of nanodispersed magnets. Vladivostok: Publisher FEFU, 2010, 120 p.
Afremov L.L., Iliushin I.G., Anisimov S.V., Modeling the implications of chemical transformations for the magnetic properties of a system of titanomagnetite nanoparticles. Izv., Phys. Solid Earth, 2015, 51, pp. 613–621.
Afremov L.L., Kharitonsky P.V., On the magnetostatic interaction in an ensemble of growing single-domain grains. Izvestiya AN USSR, Fizika Zemli, 1988, 2, pp. 101–105.
Afremov L.L., Kharitonsky P.V., Some diagnostic features of the thermo-sufficient and chemical magnetizations of an ensemble of single-domain particles. In the book “Magnetism of rocks”, Moscow, 1989, pp. 37–45.
Afremov L.L., Panov A.V., Remanent magnetization of ultradispersed magnets. Vladivostok: Publisher FEFU, 2004, 192 p.
Anisimov S.V., Afremov L.L., Thermoremanent and chemical magnetization of exsolution products of nanosized titanomagnetites. Izvestiya, Physics of the Solid Earth, 2018, 54, pp. 1–6.
Avilova T.E., Bagin V.I. Gendler T.S., Chemical remanent magnetization and structural-sensitive characteristics of hematite. Izvestiya AN USSR, Fizika Zemli, 1985, 4, pp. 67–77.
Belokon V.I., Kochegura V.V., Sholpo L.E., Methods of paleomagnetic studies of rocks. Leningrad Nedra, 1973, 248 p.
Belokon V.I., On the ratio of some types of remanent magnetization of an ensemble of single-domain interacting particles. Izvestiya AN USSR, Fizika Zemli, 1985, 2, pp. 55–64.
Borisova G.P., Sholpo L.E., On the possibility of statistical estimates of paleo magnetic field strength. Izvestiya AN USSR, Fizika Zemli, 1985, N7, p. 71.
Goroshko O.A., Ivanov V.A., Soppa I.V., Observation of interaction assembly of single domain particles. JMMM, 2010, 322, pp. 3385–3390.
Gribov C.K., Dolotov A.V. Scherbakov V.P., experimental modeling of chemical magnetization and Telie method for the titanomagnetite-containing basalts. Fizika Zemli, 2017, 2, pp. 109–128.
Gubin S.P., Koksharov Yu.A., Khomutov G.B., Yurkov G.Yu., Magnetic nanoparticles: preparation, structure and properties. Russian Chem. Rev., 2005, 74, pp. 489–520.
Haig G., The occurrence of remanent magnetization in chemical changes. In the book ”Paleomagnetism” under the redaction of Petrova G.N., Moscow, 1962, pp. 67–86.
Hramov A.N., Paleomagnetics. Leningrad Nedra, 1982, 312 p.
Ivanov V.A., Haburzaniya I.A., Sholpo L.E., The use of Preisoch diagram for the diagnosis of single- and multi-domain grains in rock samples. Izvestiya AN USSR, Fizika Zemli, 1981, 1, pp. 55–65.
Ivanov V.A., Sholpo L.E., Quantitative criteria for single- and multi-domain states of ferromagnetic minerals of rocks. Izvestiya AN USSR, Fizika Zemli, 1982, 8, pp. 84–90.
Jun Wang, Wei Wu, Fan Zhao, and Guo-meng Zhao, Curie temperature reduction in SiO2-coated ultrafine Fe3O4 nanoparticles: Quantitative agreement with a finite-size scaling law. Applied physics letters, 2011, 98, 083107.
Krupichka S., Physics of ferrites and related magnetic oxides. Moscow, 1976, 2, 504 p.
Kudryavceva G.P., Ferrimagnetism of natural oxides. Moscow Nedra, 1988, 232 p.
Nguen T.K.T., Chemical remanent magnetization of magnetite, formed during the decay of titanomaghemite. VINITY RAS № 4886–85, 1985a, 17 p.
Nguen T.K.T., On the stability and the ratio between the values of crystallographic, ideal and thermo-remanent magnetization of magnetite formed during the decay of pyrite. Izvestiya AN USSR, Fizika Zemli, 1985b, 7, pp. 100–104.
Nguen T.K.T., Pechersky D.M., An experimental study of the crystallization magnetization formed in the oxidation of pyrite. Izvestiya AN USSR, Fizika Zemli, 1984, N5, pp. 48–62.
Nguen T.K.T., Pechersky D.M., Experimentally obtained features of the crystallization remanent magnetization of magnetite-bearing rocks. Izvestiya AN USSR, Fizika Zemli, 1985, N8, pp. 48–62.
Nguen T.K.T., Pechersky D.M., Signs of the chemical magnetization of magnetite formed during the decay of titanomagnetite. Izvestiya AN USSR, Fizika Zemli, 1987, N5, pp. 69–76.
Nikiforov V.N., Ignatenko A.N., Irkhin V. Yu., Size and surface effects on the magnetism of magnetite and maghemite nanoparticles. J. Exp. Theor. Phys., 2017, 124, pp. 304–310.
O’Reilly W., Rock and mineral magnetism. New York. 1984. 230 p.
Özdemir Ö., and Dunlop D. J., Hysteresis and coercivity of hematite. J. Geophys. Res. Solid Earth, 2014, 119, 2582–2594.
Perez N., Guardia P., Roca A.G., Morales M.P., Serna C.J., Iglesias O., Bartolome F., Garcia L.M., Batlle X., Labarta A., Surface anisotropy broadening of the energy barrier distribution in magnetic nanoparticles. Nanotechnology, 2008, 19, 475704.
Petrova G.N., Laboratory methods in paleomagnetic studies. Geomagnetic studies, 1977, 19, pp. 40–49.
Scherbakov V.P., On the distribution function of molecular fields in systems with randomly distributed interaction centers. FMM, 1979, 48(6), p. 1134.
Scherbakov V.P., Scherbakova V.V., To the calculation of the thermo-sufficient and ideal magnetization of an ensemble of interacting single-domain grains. Izvestiya AN USSR, Fizika Zemli, 1977, 6, pp. 69–83.
Sholpo L.E., The use of the rock magnetism to solve the geological tasks. Leningrad Nedra, 1977, 182 p.
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Anisimov, S.V., Afremov, L.L., Iliushin, I.G. (2019). Influence of Magnetostatic Interaction on Magnetic Characteristics of Decay Products of Nanodisperse Titanomagnetites. In: Nurgaliev, D., Shcherbakov, V., Kosterov, A., Spassov, S. (eds) Recent Advances in Rock Magnetism, Environmental Magnetism and Paleomagnetism. Springer Geophysics. Springer, Cham. https://doi.org/10.1007/978-3-319-90437-5_9
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