Abstract
The method and technique of training demonstration of the giant magnetoresistance effect on the example of film samples (single layer Co film and three-layer film Co/Cu/Co) in CIP-geometry with the help of simple experimental equipment are presented.
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References
Meisell L, Gleng R (1977) Tehnologiya tonkih plenok: spravochnik, vol 1. Sow. Radio, Moskow
Meisell L, Gleng R (1977) Tehnologiya tonkih plenok: spravochnik, vol 2. Sow. Radio, Moskow
Pogrebnjak AD, Lebed AG, Ivanov YuF (2001) Modifcation of single crystal stainless steel structure (Fe–Cr–Ni–Mn) by high-power ion beam. Vacuum 63(4):483–486. https://doi.org/10.1016/S0042-207X(01)00225-1
Pogrebnjak AD, Bazyl EA (2001) Modification of wear and fatigue characteristics of Ti–V–Al alloy by Cu and Ni ion implantation and high-current electron beam treatment. Vacuum 64(1):1–7. https://doi.org/10.1016/S0042-207X(01)00160-9
Pogrebnjak AD, Isakov IF, Opekunov MS et al (1987) Increased wear resistance and positron annihilation in Cu exposed to high power ion beam. Phys Lett A 123(8):410–412. https://doi.org/10.1016/0375-9601(87)90043-0
Goncharov AA, Yunda AN, Komsta H et al (2017) Effect of structure on physicomechanical properties of transition metals diboride films. Acta Phys Pol A 132(2):270–273
Yakovin S, Zykov A, Dudin S et al (2017) Plasma assisted deposition of TaB2 coatings by magnetron sputtering system. Probl At Sci Technol 107(1):187–190
Bazhin AI, Goncharov AA, Pogrebnyak AD et al (2016) Superhardness effect in transition metal diborides films. Phys Met Metall 117(6):594–601
Goncharov AA, Yunda AN, Shelest IV et al (2017) Effect of the magnetron sputtering parameters on the structure and substructural characteristics of tantalum diboride films. J Nano- Electron Phys 9(4):04014
Pogrebnjak AD, Bondar OV, Abadias G et al (2016) Structural and mechanical properties of NbN and Nb–Si–N films: experiment and molecular dynamics simmulations. Ceram Int 42(10):11743–11756. https://doi.org/10.1016/j.ceramint.2016.04.095
Baibich MN, Broto JM, Fert A et al (1988) Giant magnetoresistance of (001)Fe/(001)Cr magnetic superlattices. Phys Rev Lett 61(21):2472–2475
Binasch G, Grünberg P, Saurenbach F et al (1989) Enhanced magnetoresistance in layered magnetic structures with antiferromagnetic interlayer exchange. Phys Rev B 39(7):4828–4830
Fert A (2008) Proischojdenie, razwitie i perspektiwi spintroniki. Usp Phys Nauk 178(12):1336–1348
Shkurdoda YuO, Chornous AM, Shabelnyk YuM et al (2017) The influence of the concentration of components in magnetic layers on the magnetoresistive properties of three-layer film systems based on FexNi1−x and Cu. J Magn Magn Mater 443:190–194. https://doi.org/10.1016/j.jmmm.2017.07.078
Loboda VB, Protsenko IE (1981) Structure and electrical resistance of thin scandium films (III). Study on electrical properties. Kristall Tech 16(4):489–494
Loboda VB, Shkurdoda YuO, Kravchenko VO et al (2011) Structure and magnetoresistive properties of polycrystalline Co/Cu/Co films. Metallofiz Noveishie Tekhnol 33(2):161–169
Loboda VB, Kolomiets VM, Shkurdoda YuO et al (2012) Structure and magnetoresistive properties of nanocrystalline film systems based on Co, Fe, Ag, and Cu. Metallofiz Noveishie Tekhnol 34(8):1043–1055
Loboda VB, Khursenko SN (2006) Structure and electrical conductivity of ultrathin Ni–Cu films. JETP 103(5):790–794
Shkurdoda YO, Chornous AM, Loboda VB et al (2016) Structure and magnetoresistive properties of three-layer film systems based on permalloy and copper. J Nano- Electron Phys 8(2):02056
Loboda VB, Kolomiets VM, Khursenko SM et al (2014) The electrical conductivity of the three-layer polycrystalline films Co/Ag(Cu)/Fe in the conditions of atoms interdiffusion. J Nano- Electron Phys 6(1):04032
Protsenko IY, Mehta PK, Odnodvorets LV et al (2014) Magnetoresistive properties of quasi granular film alloys FexPt1−x at the low concentrations of Pt atoms. J Nano- Electron Phys 6:01031
Synashenko OV, Tkach OP, Buryk IP et al (2009) Magnetoresistive properties of multilayer nanodimensional film systems. Probl At Sci Technol 18:169
Protsenko I, Odnodvoretz L, Chornous A (1998) Electroconductivity and tensosensibility of multilayer films. Metallofiz Noveishie Tekhnol 20:36
Lytvynenko IM, Pazukha IM, Pylypenko OV et al (2015) Structural, magnetic and magnetoresistive properties of ternary film Ni–Fe–Co alloy. Metallofiz Noveishie Tekhnol 37(10):1377
Pogorily AM, Ryabchenko SM, Tovstolytkin AI (2010) Spintronika. Osnovni javisza. Tendenzii rozvitku. Ukr Phys J 6(1):37–97 [In Ukrainian]
Lukashevich MG (2003) Vvedenie v magnitoelektroniku. BGU, Minsk [In Russian]
Sisoeva S (2005) Avtomobilnie datchiki polozenija. Komponenty technol 4(5):60–68
Romanova I (2014) Magnitoresistivnaya pamyat’ MRAM. Elektron-nauka-technol-biznes 8(00140):72–77
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Loboda, V.B., Dovzhyk, M.Y., Kravchenko, V.O., Khursenko, S.M., Shkurdoda, Y.O. (2019). On the Possibility of Training Demonstration of the Giant Magnetoresistance Effect in Higher School. In: Pogrebnjak, A.D., Novosad, V. (eds) Advances in Thin Films, Nanostructured Materials, and Coatings. Lecture Notes in Mechanical Engineering. Springer, Singapore. https://doi.org/10.1007/978-981-13-6133-3_8
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