The effect of interactions on the soft and hard phases and interference region that commonly appears in the First Order Reversal Curve (FORC) of interacting two-phase magnetic systems was investigated. To obtain an interacting two-phase system, a new method was introduced for the first time to electrodeposit a two-phase magnetic nanowire (NW) composed of hard and soft phases with high magnetization into nanopores of the anodized aluminum oxide template using the single-bath ac-pulse electrodeposition technique. Two-phase behavior was obtained by multilayer and grainy configurations of the CoFe and Cu layers as two type layers with controllable thickness through the related pulse numbers. It was found that interphase interaction can be observed in FORC diagrams with three factors; (i) the shift in center of the soft phase feature along the interaction field axis without the change in coercivity, (ii) shift in center of the hard phase feature along the coercivity axis and (iii) appearance of an additional interference region. However, order of the shifts directly correlates with the order of demagnetizing intraphase interaction through the hard phase and magnetic moment contribution of the soft phase. The interference region contribution was found strongly correlates with irreversible magnetic moment contribution of the soft and hard phases.

1 H. P. Liang, 44 : 3013-3016, 2005

2 F. Ebrahimi, 5 : 134-138, 2003

3 G. Binaseh, 39 : 4828-4832, 1989

4 C. -I. Dobrot, "What does a first-order reversal curve diagram really mean? A study case : array of ferromagnetic nanowires" 113 : 043928-043938, 2013

5 L. Clime, "The interaction field in arrays of ferromagnetic barcode nanowires" 18 : 435709-435715, 2007

6 M. Almasi-Kashi, "The effect of magnetic layer thickness on magnetic properties of Fe/Cu multilayer nanowires" 144 (144): 230-234, 2014

7 A. Ramazani, "The effect of deposition parameters on the magnetic behavior of CoFe/Cu multilayer nanowires" 130 : 2-9, 2015

8 R. Ramesh, "Synthesis and properties of a-Fe2O3nanorods" 45 : 965-968, 2010

9 Fanny Beron, "Reversible and quasireversible information in first-order reversal curve diagrams" 101 : 09J107-09J109, 2007

10 I. Bodale, "Reversible and irreversible components evaluation in hysteretic processes using first and second-order magnetization curves" 47 : 192-197, 2011

11 S. Samanifar, "Reversal modes in FeCoNi nanowire arrays: correlation between magnetostatic interactions and nanowires length" 378 : 73-83, 2015

12 D.A. Gilbert, "Quantitative decoding of interactions in tunable nanomagnet arrays using first order reversal curves"

13 Dustin A. Gilbert, "Quantitative Decoding of Interactions in Tunable Nanomagnet Arrays Using First Order Reversal Curves" Springer Nature 4 : 2014

14 A. Stancu, "Preisach Model for Soft-hard Bilayers, Hysteresis modeling and micromagnetics" NIST 2009

15 N. Siadou, "Magnetization reversal in [Ni/Pt]6/Pt(x)/[Co/Pt]6multilayers" 323 : 1671-1677, 2011

16 V. Alexandrakis, "Magnetization reversal in CoPt(111)hard/soft bilayers" 105 : 063908-063915, 2009

17 L. Alonso, "Magnetic interaction in exchangebiased bilayers: a first-order reversal curve analysis" 43 : 465001-, 2010

18 Sima Alikhanzadeh-Arani, "Magnetic characterization of FeCo nanowire arrays by first-order reversal curves" 한국물리학회 13 (13): 664-669, 2013

19 M. Winklhofer, "Identifying reversible and irreversible magnetization changes in prototype patterned media using first- and secondorder reversal curves" 103 : 07C518-07C520, 2008

20 D. R. Cornejo, "First-order-reversal-curve analysis of PreFeeB-based exchange spring magnets" 45 : 5077-5083, 2010

21 F. Beron, "First-order reversal curve diagrams of magnetic entities with mean interaction field: a physical analysis perspective" 103 : 07D908-07D910, 2008

22 V. Bonanni, "First-order reversal curve analysis of graded anisotropy FePtCu films" 97 : 202501-202503, 2010

23 D. R. Cornejo, "First order reversal curve analysis of nanocrystalline Pd80Co20alloy films" 479 : 43-48, 2009

24 H. Chiriac, "Experimental and micromagnetic first-order reversal curves analysis in NdFeB-based bulk “exchange spring”-type permanent magnets" 316 : 177-180, 2007

25 F. Beron, "Electrodeposited Nanowires and Their Applications" INTECH 228-, 2010

26 M. Kumari, "Distinguishing magnetic particle size of iron oxide nanoparticles with first-order reversal curves" 116 : 124304-124309, 2014

27 C. R. Pike, "Characterizing interactions in finemagnetic particle systems using first order reversal curves" 85 : 6660-6667, 1999

28 L. Clime, "Characterization of individual ferromagnetic nanowires by in-plane magnetic measurements of arrays" 299 : 487-491, 2006

29 L. Clime, "Characterization of individual ferromagnetic nanowires by in-plane magnetic measurements of arrays" 299 : 487-491, 2006

30 A. Siritaratiwat, "Annealing effects on GMR multilayer films" 81 : 40-43, 2000

31 J. E. Davies, "Anisotropy dependence of irreversible switching in Fe/SmCo and FeNi/FePt exchange spring magnet films" 86 : 262503-262505, 2005

32 E. Jafari-Khamse, "Angular dependence of interactions in polycrystalline Co nanowire arrays" 159 : 128-138, 2015

33 A. Pereira, "A soft/hard magnetic nanostructure based on multisegmented CoNi nanowires" 1-3, 2013

34 I. Panagiotopoulos, "A simple approach to the First Order Reversal Curves(FORC)of two-phase magnetic systems" 323 : 2148-2153, 2011

35 A. Ramazani, "A new approach to fabricate magnetic multilayer nanowires by modifying the acpulse electrodeposition in a single bath"