FMR Studies of High-Moment Materials at High Frequencies James Rantschler and Chet Alexander Center for Materials for Information Technology and Department of Physics Jesse Lawrence Department of Chemistry MINT Spring Review, 23
Advantages of High-Frequency, High-field FMR in Studies of High-Moment Films The use of a high field and a high frequency allows one to achieve resonance when the magnetic field is perpendicular to the film plane. Spin waves are most easily observed in this orientation and fitting of spin wave data allows one to determine the exchange coupling constant Detection of magnetic species with slightly different g or Ms values is easier because the separation of the absorption lines is proportional to the applied field. The variable temperature capabilities of the superconducting magnets makes it possible to study the temperature variation of magnetic properties, including FMR line widths. The sample size for the 94 GHz FMR is small, and the sensitivity is very high,making it a particularly good system for studying patterned samples of high-moment materials
Cu/CoFe, FMR at 94 GHz Intensity [] 1.5 1 4 Intensity [] 2-2 -4-6 -8-1 1 4-1.2 1 4 2 1 4 1 1 4 5-5 -1 1 4-1.5 1 4 CuCoFe LW = 114 G H p e rp e n d icu la r to film 48875 G CuCoFe 4/3/3 Spin waves 54625 G 5.4 1 4 5.45 1 4 5.5 1 4 5.55 1 4 Field [G] 55312 G 53528 G 54622 G 4.8 1 4 5 1 4 5.2 1 4 5.4 1 4 55425 G Field (G) 6 1 4 5.5 1 4 5 1 4 4.5 1 4 4 1 4 3.5 1 4 3 1 4 2.5 1 4 2 1 4 H (pependicular to film) -2 2 4 6 8 1 12 Angle beta (deg) CuCoFe FMR f = 94 GHz H, Measured x H, Fit Easy Axis Perpendicular Anisotropy = 2339 Oe γ = 2.93 MHz/Oe A = 1.75 x 1 6 erg/cm Field [G]
FMR of FeTiN5 at 93.9 GHz in 6T Superconducting Magnet 5 1 4 4.5 1 4 H perpendicular to film 1 8 Angle of H and M (angle of M) Θ 6 Hcal (Oe) 4 1 4 3.5 1 4 3 1 4 FMR at 93.9 GHz FeTiN (1% N) γ=2.88 MHz/Oe 4πMs = 1462 Oe Angle (deg) 4 2 β (angle of H) 2.5 1 4-2 2 4 6 8 1 beta Deg) -2-2 2 4 6 8 1 beta
Measurement of Switching Characteristics of Patterned Soft Films: MOKE-Microwave Stripline system Yunfei Ding and Chet Alexander Center for Materials for Information Technology and Department of Physics MINT Spring Review, 23
MOKE- Microwave Stripline System Patterned Samples are placed on a microwave coplanar waveguide, and pulses of variable length (1-1 nsec), amplitude (- 12 Oe) and repetition frequency (.1 1 khz) can be applied. The magnetization state is detected by a MOKE system. Switching of 5 nm thick NiFe samples 2 x 1 µ has been detected.
CPW-MOKE system for the study of fast switching of patterned films Electromagnet He-Ne laser Polarizer Objective Lens CPW Pulse Generator Spatial filter Modulator Microscope Analyser Laser Glass Sub. Photodiode Film Copper Lock in Ampl. Computer Dielectric Cross section of CPW
Patterned NiFe Measured by MOKE EA HA Hc = 8.3 Oe Hk = 139 Oe Pattern size: 2 x 1 um Thickness: 5nm -4-3 -2-1 1 2 3 4 H (Oe)
The Effects of Ti on the Diffusion of Nitrogen in FeXN Films Yunfei Ding and Chet Alexander Center for Materials for Information Technology and Department of Physics MINT Spring Review, 23
Ti and Nitrogen Diffusion The diffusion of N atoms in FeXN films can cause phase changes and unstable anisotropy. Multilayer films of Fe, Ti, FeTi, and FeTiN have been studied before and after annealing. We have done structural studies by XRF and depth profile studies by XPS techniques. Our preliminary findings show that Ti has a large effect on N diffusion and Ti tends to stabilize the α-phase of FeN and prevent formation of Fe 4 N.
Diffusion of N in FeXN materials causes nitrogen loss, phase change and unstable anisotropy ENTHALPY KJ/MOL DIFFUSION LENGTH (DT) 1/2 (A) 373K, 1 MIN Fe 4 N -1 α(bcc) Fe 2 TiN -338 α(hcp) Ti.2 AlN -318 Cu 3 N Subject to randomization Rotation of Hk caused by nitrogen diffusion in FeTaN X-N affinity and N diffusion in pure nitrides
Effect of Ti in the stability of α phase FeTiN 5 4 3 2 As deposit and annealed FeN film As Deposit 2C Ann Fe 4 N(2) α FeN(11) Arb. Intensity 5 4 3 2 As deposit and annealed FeTiN film As deposit 2c Ann α FeTiN (11) 1 1 35 4 45 5 2θ 35 4 45 5 2θ Arb. Intensity 5 4 3 2 As deposit and annealed Ti/FeTiN film As Deposit 2C Ann Ti(2) α FeTiN (11) Addition of Ti in FeN film stablizes the α phase, prohibits the formation of Fe 4 N phase But N can still diffuse over a long distance, even to the adjacent layer 1 35 4 45 5 2 θ
Study of N diffusion by XPS depth profile 1 Ti/FeTiN As deposit 1 Ti/FeTiN after 2 o C 1hr annealing at.% 8 6 4 2 Fe O Ti N at.% 8 6 4 2 Fe O Ti N N (and O) in FeTiN layer is absorbed by Ti layer 5 1 15 2 25 Etching time (s) 5 1 15 2 25 Etching time (S) at.% 5 4 3 2 1 FeTi/FeTiN after 2 o C 1hr annealing 1 2 3 4 Etching Time (s) Fe O Ti N N diffuse from FeTiN layer to FeTi layer resulting a uniform distribution at.% 5 4 3 2 1 Fe/FeTiN after 2 o C 1hr annealing 1 2 3 4 5 Etching time (s) Fe O Ti N N dosen t diffuse from FeTiN layer to Fe layer