Photon pressure and its effect on the magnetic properties of multilayer films

The effect of nanosecond laser pulses on the optical and magnetic properties of Bi-SiC-TbFe-SiC, SiC-TbFe-SiC, SiC-Tb-Au-Fe-SiC, and phthalocyanine dye-bismuth-phthalocyanine dye multilayer nanofilms is experimentally studied. The photon pressure of a laser beam is shown to cause electrons to drift in the direction of beam propagation. As a result of the injection of spin-polarized electrons from the magnetic layer, a nonequilibrium magnetization arises in the nonmagnetic Bi or Au layer, which changes the magnetooptic properties of the films. In three-layer dye-bismuth-dye films, the photon pressure of the laser radiation induces a space electron charge in the exit dye layer, which causes a drift of ionized bismuth atoms.     

Structure and magnetic properties of Fe/Cu multilayered films

Mutually insoluble Fe/Cu multilayered films prepared by a dc-magnetron sputtering system with a rotating substrate-holder have been studied. The periodicity of the multilayers was confirmed by X-ray diffraction. The results of magnetization measurements and Mössbauer spectroscopy at 300 and 77 K show that the samples with the Fe layer thinner than 9 Å exhibit superparamagnetism. The temperature dependence of the spontaneous magnetization follows Bloch's law for all samples, with the spin-wave temperature coefficient B inversely proportional to the thickness of the Fe layer. The results of torque measurements show that the magnetization is normal to the film plane for the samples with the Fe layer thinner than 6 Å.     

Rotation of the magnetic moment of thin films

The remagnetization time of thin magnetic fields for remagnetization along the axis of hard magnetization has been calculated on a computer. It is found that the magnetic moment may flip from a position along the axis of easy magnetization to the opposite direction under the influence of a pulsed magnetic field along the axis of hard magnetization.Translated from Izvestiya Vysshikh Uchebnykh Zavedenii, Fizika, Vo. 12, No. 3, pp. 104–107, March, 1969.The author thanks G. M. Rogichev for discussion of and assistance in this study.     

Structural and magnetic properties of high magnetic moment electroplated CoNiFe thin films

CoNiFe alloy thin films deposited at various cobalt concentrations were galvanostatically electrodeposited on the pre-cleaned copper substrates. The effects of cobalt concentration on the structural, compositional, morphological, and magnetic properties of the films were investigated. X-ray diffraction patterns revealed that the deposited films possess polycrystalline in nature with mixed (fcc–bcc) cubic structure at optimized cobalt concentration. Microstructural properties of the films were calculated from predominant diffraction lines. The surface morphology and surface roughness were characterized using scanning electron microscopy and atomic force microscopy, respectively. EDAX results were revealed that the cobalt content increases as nickel content decreases whereas ferrous content initially increases and then eventually decreases in the CoNiFe alloy. VSM results show a higher value of saturation magnetization (4πM _s) above 2 T with coercivity 154 A/m for films deposited in the optimized deposition condition.     

MnBi磁性多层膜磁光科尔效应的数值模拟

基于各向异性的平面电磁波传输理论和4×4矩阵法，计算了MnBi，Mn_0.53Bi_0.47，Mn_0.52Bi_0.44Sb_0.04磁性多层膜系列的磁光科尔旋转角、椭圆率随波长、入射角、磁性层厚度变化曲线.计算结果表明，模拟的科尔旋转角、椭圆率随波长变化规律与实验结果吻合很好；在一定波长的垂直入射下，模拟的科尔旋转角、椭圆率随磁性层厚度变化曲线出现科尔谱极大；在磁性层厚度一定的情况下，当入射光以某一角度 关键词： 4×4矩阵法 磁性多层膜 磁光科尔谱 介电张量     

铁单质薄膜磁致伸缩行为与磁矩演化研究

磁致伸缩材料在传感器、位移器件等领域应用前景广阔,对此类材料的制备与实验已成为研究热点,但使用分子动力学方法模拟其磁致伸缩过程中内部磁矩的演化仍缺乏相关研究.本研究以磁致伸缩材料铁单质为研究对象,采用分子动力学方法建立单畴铁单质磁致伸缩模型.分析了铁单质薄膜磁致伸缩行为随初始磁矩的变化,以及在磁场作用下微观原子磁矩的变化与宏观磁致伸缩之间的关系.结果表明:模型磁化构型的演化与磁致伸缩行为有着密切联系,随着外加磁场强度增大,原子磁矩与外加磁场方向相同的区域面积逐渐增大,宏观表现为模型的磁致伸缩随磁场强度增大而伸长,并最终达到饱和,而边界处的原子磁矩是模型是否达到饱和磁致伸缩的关键.     

Effects of layering and working pressure on magnetic and magnetotransport properties of as sputtered multilayered granular Co/Cu films

Heterogeneous films of CoCu having high giant magnetoresistance (MR) were prepared in the form of multilayered granular specimens by a two-target RF sputtering. MR performances of 11% at 293 K were obtained in as deposited granular films. The magnetic and magnetotransport properties could be changed to a large extent, by varying the thickness of the deposited Co (Cu) layer as well as the Ar pressure. The effect of Co concentration, in the range 5–30%, and the influence of thermal treatments were also analysed.     

Ferromagnetic resonance features in anisotropic magnetic films with a metastable state of magnetic moment

In experiments on single-domain magnetic films with uniaxial in-plane anisotropy, a new homogeneous ferromagnetic resonance peak was observed in a planar magnetic field oriented at an angle to the easy magnetization axis and directed opposite to the magnetization projection onto the field direction. The peak was observed in fields smaller than the magnetization reversal field of the film, and the origin of the peak was found to be related to the metastable state of the magnetic moment. A good agreement was obtained between phenomenological calculations and experimental data.     

Photon equation of motion with application to the electron’s anomalous magnetic moment

The photon equation of motion previously applied to the Lamb shift is here applied to the anomalous magnetic moment of the electron. Exact agreement is obtained with the QED result of Schwinger. The photon theory treats the radiative correction to the photon in the presence of the electron rather than its inverse as in standard QED. The result is found to be first order in the photon-electron interaction rather than second order as in standard QED, introducing an ease of calculation hitherto unavailable.     

Numerical calculation of Kerr spectra for Co/Pt magnetic multilayered films

The Kerr spectra as function of wavelength, incident angle and layer number are calculated with 4×4 matrix method. It is found that the calculated results are in good agreement with experimental ones for [Co (0.3 nm)/Pt (0.4 nm)]×43/glass (1.21 mm) and [Co (0.4 nm)/Pt (1.1 nm)]×53/glass (1 mm). In addition, for [Co (0.3 nm)/Pt (0.4 nm)]×43/glass (1.21 mm), it shows a maximum Kerr rotation at N = 10. For [Co (0.4 nm)/Pt (1.1 nm)]×53/glass (1 mm), the calculated Kerr rotation as a function of incident angle reveals maximum when the incident angle is 89°.     

Experimental evidence of the magnetic moment of Bloch walls in garnet films

Differential susceptibility measurements in low in-plane fields showed up a new peak assumed to be caused by magnetization reversal inside the Bloch walls (BW). Highly sensitive measurements carried out subsequently on different domain structures yielded various new parameters such as the BW hysteresis curve, the integral saturated and remanent BW moments and the internal BW coercivity. The mechanism proposed for the observed phenomena is based on the reversible and irreversible motion of Bloch lines inside the Bloch walls.     

Characteristics of thin film inductors using magnetic multilayered films with ceramic intermediate layers

Circular spiral thin film inductors were fabricated using as-deposited magnetic multilayered films with ceramic intermediate layers, and a thin film inductor with a single magnetic layer was also fabricated for comparison. The magnetic multilayered films have good soft magnetic properties and high resistivity thus can decrease the eddy current loss. Employing the magnetic multilayered films, we got a higher quality factor (>30) and better inductor characteristics as compared with the inductor with a single magnetic layer, such as a high operating frequency (>80 MHz) without decreasing the inductance.     

On magnetic moment and magnetic induction

An attempt is made to introduce the concept of magnetic moment and magnetic induction directly from observed mechanical interactions between magnets, without bringing in the idealized notion of isolated magnetic poles.     

缺陷对铁单质薄膜磁致伸缩与磁矩演化的影响

磁致伸缩材料在传感、控制及能量与信息转换等领域应用前景广阔,此类材料的性能提升及工程应用已成为研究热点,但材料在制备与使用中不可避免会出现缺陷.本文以常用的铁磁性材料铁单质为研究对象,采用分子动力学方法分别建立无缺陷、孔洞缺陷与裂纹缺陷的铁单质磁致伸缩结构模型,分析了缺陷形式对铁单质薄膜磁致伸缩行为的影响,并从微观原子磁矩角度解释缺陷对磁致伸缩行为的影响机理.结果表明:缺陷会对其周围的原子磁矩产生影响,从而影响铁单质薄膜磁致伸缩,其中孔洞形缺陷对磁致伸缩的影响较小,裂纹形缺陷对磁致伸缩的影响较大.裂纹的方向会影响铁单质薄膜的磁致伸缩,与磁化方向平行的裂纹会降低材料在磁化方向上由初始状态至磁化达到饱和的最大磁致伸缩量;与磁化方向垂直的裂纹会提高材料在磁化方向上由初始状态至磁化达到饱和的最大磁致伸缩量.     

Diffusion and spin waves in multilayered thin films

The influence of diffusion on the energy spectrum, spin wave amplitudes and one-magnon excitation of spin waves is investigated on the basis of a one-dimensional model of biatomic thin films.On leave of absence from theInstitute of Atomic Physics, Bucharest, Romania.     

Spin-dependent scattering in multilayered magnetic rings

Narrow mesoscopic NiFe/Cu/Co elliptical rings exhibit room-temperature giant magnetoresistance with distinct resistance levels corresponding to three different micromagnetic states. The highest and lowest resistance states of the multilayer rings correspond to the Co layer being in a bidomain state, antiparallel or parallel, respectively, to the NiFe, while the intermediate resistance corresponds to the Co layer being in a vortex state. Micromagnetic simulations suggest that the behavior of these rings is dominated by magnetostatic interactions between the domain walls in the Co and NiFe layers. Additional magnetization states in the NiFe at low applied fields can account for the minor loop behavior.     

Evanescent wave holographic recording in nanosize thick chalcogenide glass films

The results of holographic gratings recording in 29, 15 and 8 nm thick As₂S₃ films are presented in the paper. The method is based on the interference of surface-propagating evanescent waves, created by total internal reflection. The condition for successful recording is the penetration depth of these inhomogeneous waves to be greater than the films thickness. In this case, the film’s refractive index does not affect the total internal reflection (TIR) condition and could be greater than the input glass prism. The experimentally obtained low diffraction efficiencies by this holographic recording technique is due to the very low refractive index modulation, but the good signal-to-noise ratio - better than 50:1 and Bragg-type diffraction are a base for future applications of this grating formation method in nanotechnology.