Диссертация (1104133), страница 20
Текст из файла (страница 20)
Malyshev, Y. P. Melnikov, Tishin A.M., Spichkin Y.I.,Gimaev R.R. Analysis and optimization of high-energy permanent magnetelectromagnetic drive by finite element method // Moscow International Symposium onMagnetism (MISM), 29 June – 3 July 2014, Moscow. Book of Abstracts. — Faculty ofPhysics M.V. Lomonosov MSU Moscow, 2014. — P. 596–596.114Список литературы1.Fallot M. // Ann. Phys.
(Paris). 1938. Vol. 10. P. 291.2.Mariager S.O. et al. Structural and Magnetic Dynamics of a Laser Induced Phase Transition inFeRh // Phys. Rev. Lett. 2012. Vol. 108, № 8. P. 087201.3.Gray A.X. et al. Electronic Structure Changes across the Metamagnetic Transition in FeRhvia Hard X-Ray Photoemission // Phys. Rev.
Lett. 2012. Vol. 108, № 25. P. 257208.4.Cooke D.W. et al. Thermodynamic Measurements of Fe-Rh Alloys // Phys. Rev. Lett. 2012.Vol. 109, № 25. P. 255901.5.Derlet P.M. Landau-Heisenberg Hamiltonian model for FeRh // Phys. Rev. B. 2012. Vol. 85,№ 17. P. 174431.6.Vries M.A. de et al. Hall-effect characterization of the metamagnetic transition in FeRh //New J.
Phys. 2013. Vol. 15, № 1. P. 013008.7.Staunton J.B. et al. Fluctuating local moments, itinerant electrons, and the magnetocaloriceffect: Compositional hypersensitivity of FeRh // Phys. Rev. B. 2014. Vol. 89, № 5. P.054427.8.Тишин А.М., Рочев Ю.А., Горелов А.В. Носитель для лекарственных средств ибиологически активных веществ для лечения и диагностики и применения его длясоздания лекарственных средств и способа регулируемой управляемой доставкилекарственного средства: pat.
RU 2373957 C2 USA.9.Tishin A.M., Rochev J.A., Gorelov A.V. Magnetic carrier and medical preparation forcontrollable delivery and release of active substances, a method of production and method oftreatment using thereof: pat. WO 2008/044963 USA. 2008.10. Tishin A.M., Rochev J.A., Gorelov A.V. Magnetic carrier and medical preparation forcontrollable delivery and release of active substances, a method of production and method oftreatment using thereof: pat. DE 112006004066 USA.
2009.11. Thiele J.-U., Maat S., Fullerton E.E. FeRh/FePt exchange spring films for thermally assistedmagnetic recording media // Appl. Phys. Lett. 2003. Vol. 82, № 17. P. 2859–2861.12. Pecharsky V.K., Gschneidner J. K.A. Giant Magnetocaloric Effect in Gd5Si2Ge2 // Phys. Rev.Lett. 1997. Vol. 78, № 23.
P. 4494–4497.13. Fujieda S., Fujita A., Fukamichi K. Large magnetocaloric effect in La(FexSi1−x)13 itinerantelectron metamagnetic compounds // Appl. Phys. Lett. 2002. Vol. 81, № 7. P. 1276–1278.14. Tegus O. et al. Transition-metal-based magnetic refrigerants for room-temperatureapplications // Nature. 2002. Vol. 415, № 6868. P. 150–152.11515. Nikitin S.A. et al.
The magnetocaloric effect in Fe49Rh51 compound // Phys. Lett. Sect. Gen.At. Solid State Phys. 1990. Vol. 148, № 6–7. P. 363–366.16. Annaorazov M.P. et al. Alloys of the Fe-Rh system as a new class of working material formagnetic refrigerators // Cryogenics. 1992. Vol. 32, № 10. P. 867–872.17. Nikitin S.A. et al.
Giant anomalies of the Young’s modulus and internal friction of FeRh alloyabove the AFM-FM transition point // Phys. Lett. A. 1993. Vol. 176, № 3–4. P. 275.18. Nikitin S.A. et al. Giant elastocaloric effect in FeRh alloy // Phys. Lett. A. 1992. Vol. 171, №3–4. P. 234–236.19. Franco V. et al. The Magnetocaloric Effect and Magnetic Refrigeration Near RoomTemperature: Materials and Models // Annu.
Rev. Mater. Res. 2012. Vol. 42, № 1. P. 305.20. Nishimura K. et al. Magnetocaloric Effect of Fe(Rh1−xPdx) Alloys // Mater. Trans. 2008. Vol.49, № 8. P. 1753–1756.21. Manekar M., Roy S.B. Very large refrigerant capacity at room temperature with reproduciblemagnetocaloric effect in Fe0.975Ni0.025Rh // J.
Phys. Appl. Phys. 2011. Vol. 44, № 24. P.242001.22. Barua R., Jiménez-Villacorta F., Lewis L.H. Towards tailoring the magnetocaloric response inFeRh-based ternary compounds // J. Appl. Phys. 2014. Vol. 115, № 17. P. 17A903.23. Gyorffy B.L. et al. A first-principles theory of ferromagnetic phase transitions in metals // J.Phys. F Met. Phys. 1985. Vol. 15, № 6.
P. 1337.24. Garcia-Sanchez F. et al. Multiscale models of hard-soft composite media // J. Magn. Magn.Mater. 2006. Vol. 303, № 2. P. 282–286.25. Fallot M., Horcart R. // Rev. Sci. 1939. Vol. 77. P. 498.26. Kouvel J.S. Unusual Nature of the Abrupt Magnetic Transition in FeRh and Its PseudobinaryVariants // J. Appl. Phys. 1966. Vol. 37, № 3. P. 1257–1258.27. Zakharov A.I. et al.
// Sov. Phys. JETP. 1964. Vol. 19. P. 1348.28. Muldawer L., deBergevin F. Antiferromagnetic‐Ferromagnetic Transformation in FeRh // J.Chem. Phys. 1961. Vol. 35, № 5. P. 1904–1905.29. Kren E., Pal L., Szabo P. Neutron diffraction investigation of the antiferromagneticferromagnetic transformation in the FeRh alloy // Phys. Lett. 1964.
Vol. 9, № 4. P. 297–298.30. de Bergevin F., Muldawer L. // C. R. Hebd. Seances Acad. Sci. 1961. Vol. 253. P. 1347.31. Feng Y., Fukuda T., Kakeshita T. Temperature memory effect associated with a first ordermagnetic transition in FeRh // Intermetallics. 2013. Vol. 36. P. 57–60.32.
Shirane G. et al. // J. Appl. Phys. 1963. Vol. 34. P. 1044.33. Bertaut E.F. et al. Magnetic Structure Work at the Nuclear Center of Grenoble // J. Appl.Phys. 1962. Vol. 33, № 3. P. 1123–1124.11634. Shirane G., Chen C.W., Nathans R. // Phys. Rev. 1964. Vol. 134. P. A1547.35. Kunitomi N., Kohgi M., Nakai Y. Diffuse scattering of neutrons in the antiferromagneticphase of FeRh // Phys. Lett. A. 1971. Vol. 37, № 4. P. 333–334.36.
Hargitai C. On the aligned magnetic moment of the Rh atoms in the FeRh alloy // Phys. Lett.1965. Vol. 17. P. 178–179.37. Moruzzi V.L., Marcus P.M., Qiu S.L. Oscillatory magnetism in compounds of iron with 4 dmetals // Phys. Rev. B. 1995. Vol. 52, № 5. P. 3448–3452.38. Gruner M.E., Hoffmann E., Entel P. Instability of the rhodium magnetic moment as the originof the metamagnetic phase transition in $\ensuremath{\alpha}-\mathrm{FeRh}$ // Phys.
Rev.B. 2003. Vol. 67, № 6. P. 064415.39. Kouvel J.S., Hartelius C.C. Anomalous Magnetic Moments and Transformations in theOrdered Alloy FeRh // J. Appl. Phys. 1962. Vol. 33. P. 1343–1344.40. Zarkevich N.A., Johnson D.D. Predicted martensitic and quantified metamagnetictransformations in FeRh // ArXiv170203042 Cond-Mat Physicsphysics. 2017.41. Ibarra M.R., Algarabel P.A.
Giant volume magnetostriction in the FeRh alloy // Phys. Rev. B.1994. Vol. 50, № 6. P. 4196–4199.42. Algarabel P.A. et al. Giant room‐temperature magnetoresistance in the FeRh alloy // Appl.Phys. Lett. 1995. Vol. 66, № 22. P. 3061–3063.43. Stoffel A.M. Magnetic and Magneto‐Optic Properties of FeRh and CrO2 // J. Appl.
Phys.1969. Vol. 40, № 3. P. 1238–1239.44. Yuasa S. et al. Change in the Resistivity of bcc and bct FeRh Alloys at First-Order MagneticPhase Transitions // J. Phys. Soc. Jpn. 1995. Vol. 64, № 10. P. 3978–3985.45. Lu W. et al. Kinetics of first order magnetostructural transition in single crystalline FeRh thinfilm // 2015 IEEE Magnetics Conference (INTERMAG). 2015. P. 1–1.46. Lommel J.M.
Thermodynamics of the First‐Order Transition in FeRh // J. Appl. Phys. 1969.Vol. 40, № 9. P. 3880–3881.47. McKinnon J.B., Melville D., Lee E.W. Solid State Phys. Conf. University of Manchester,1968.48. Zavadskii E.A., Fakidov I.G. // Sov. Phys.‐Solid State. 1967. Vol. 9, № 103.49.
Pál L. et al. The magnetic field dependence of the antiferromagnetic-ferromagnetic transitiontemperature in FeRh // Acta Phys. Acad. Sci. Hung. 1972. Vol. 32, № 1–4. P. 135.50. Kittel C. Model of Exchange-Inversion Magnetization // Phys. Rev. 1960. Vol. 120, № 2. P.335–342.51. Ricodeau J.A., Melville D. Model of the antiferromagnetic-ferromagnetic transition in FeRhalloys // J. Phys. F Met.
Phys. 1972. Vol. 2, № 2. P. 337.11752. Гражданкина Н.П. Магнитные фазовые переходы I рода // Успехи Физических Наук.1968. Vol. 96, № 10. P. 291–325.53. Perrot P. A to Z of Thermodynamics. Oxford University Press, 1998. 340 p.54. Stern-Taulats E. et al. Barocaloric and magnetocaloric effects in Fe49Rh51 // Phys. Rev. B.2014.
Vol. 89, № 21. P. 214105.55. Kamantsev A.P. et al. Properties of metamagnetic alloy Fe48Rh52 in high magnetic fields //Bull. Russ. Acad. Sci. Phys. 2015. Vol. 79, № 9. P. 1086–1088.56. Annaorazov M.P. et al. Limit field of the AF–F transition in FeRh // J. Alloys Compd.
2003.Vol. 348, № 1–2. P. 18–22.57. Thiele J.-U., Hauet T., Hellwig O. Design of Co∕Pd multilayer system with antiferromagneticto-ferromagnetic phase transition // Appl. Phys. Lett. 2008. Vol. 92, № 24. P. 242502.58. Dubenko I. et al. The comparison of direct and indirect methods for determining themagnetocaloric parameters in the Heusler alloy Ni50Mn34.8In14.2B // Appl. Phys. Lett. 2012.Vol. 100, № 19.
P. 192402.59. Dubenko I. et al. The Adiabatic Temperature Changes in the Vicinity of the First-OrderParamagnetic-Ferromagnetic Transition in the Ni-Mn-In-B Heusler Alloy // IEEE Trans.Magn. 2012. Vol. 48, № 11. P. 3738–3741.60. Sharma M. et al. Magnetotransport properties of epitaxial MgO(001)/FeRh films across theantiferromagnet to ferromagnet transition // J.
Appl. Phys. 2011. Vol. 109, № 8. P. 083913.61. Driel J. van et al. Compositional dependence of the giant magnetoresistance in FexRh1−x thinfilms // J. Appl. Phys. 1999. Vol. 85, № 2. P. 1026–1036.62. Suzuki I. et al. Clear correspondence between magnetoresistance and magnetization ofepitaxially grown ordered FeRh thin films // J. Appl. Phys. 2011.
![](https://s.studizba.com/z.php?f=/templates/si/i/noavatar.png&w=100&h=100&t=1"){kind=avatar}
