18 The Temperature Behavior of Resonant and Non-resonant Microwave Absorption in Ni-Zn Ferrites
Yüklə 0,49 Mb. Pdf görüntüsü
|
- Bu səhifədəki naviqasiya:
- 4.1 High temperatures (T >T C )
|
4. Microwave absorption in ferrites
In this Section, we discuss the microwave absorption of polycrystalline Ni-Zn ferrites as a function of measuring temperature. The resonant mode is first considered. The description and analysis of these properties is quite useful, as NiZn ferrites offer a wide variety of magnetic structures and phenomena. The study of non resonant absorption also sheds light on magnetic structure phenomena of ferrites. 4.1 High temperatures (T >T C ) By “high temperature” we mean a temperature higher than the transition from the ordered (ferrimagnetic) phase to the disordered (paramagnetic) phase. This transition is the Curie temperature, T C , and it is an intrinsic property, depending entirely on the ferrite composition (except for ferrite nanoparticles, where the Curie temperature might depend on the nanoparticle size). The effects of temperature are shown in Fig. 4.1 for a polycrystalline NiZn ferrite with x = 0.65. Most of spectra exhibit an additional absorption in the low field range (H < 0.75 kOe). This non-resonant absorption is the low field microwave absorption (LFMA, Section 3) and will be discussed in Section 5. We focus now on the resonance phenomena. The reported Curie temperature for this composition is ~ 435 K (Globus et al 1977); the spectrum at 460 K corresponds therefore to the paramagnetic state. In these conditions, the thermal energy is high enough to overwhelm the internal field that results in the long range order of spins, and they are free to interact with the DC field, H DC , and the microwave field, h AC . In the Larmor relation (Eq. 3.6), ω = γH (4.1) www.intechopen.com The Temperature Behavior of Resonant and Non-resonant Microwave Absorption in Ni-Zn Ferrites 395 (where ω is the resonance frequency, γ is the gyromagnetic factor), H is the total field on the spins. In the absence of any internal field, H is simply the external applied field H res . The microwave absorption at 460 K, Fig. 4.1, appears as a narrow, symmetric line. This is an EPR (electron spin resonance) spectrum. 0 1 2 3 4 5 -2 -1 0 1 2 d P / d H (a .u.) H (kOe) 184 K 220 K 260 K 300 K 342 K 396 K 430 K 460 K Ni 0.35 Zn 0.65 Fe 2 O 4 Fig. 4.1. Ferromagnetic resonance as a function of measuring temperature (184 ≤ T ≤ 460 K), on a polycrystalline ferrite with composition Ni 0.35 Zn 0.65 Fe 2 O 4 (adapted from Montiel et al., 2004). Yüklə 0,49 Mb. Dostları ilə paylaş:
|