The NanOsc Instruments line of broadband ferromagnetic resonance (FMR) spectrometers offer a simple turn-key solution to the burgeoning field of magnetodynamics research. Broadband FMR spectroscopy allows for measurements continuously spanning several 10’s of GHz. Measurements over a wide frequency range allow for significant improvements in accurately extracting a variety of material parameters not accessible by static measurement techniques. Broadband FMR is particularly well-suited for studying magnetic thin films, which not only form the backbone of fundamental spintronics and magnonics research but are also constituents of current and future technologies focused on magnetic memories, sensors, logic, and microwave signal processing.
- Turn-key FMR spectrometer with easy to use software interface
- Broadband FMR using a coplanar waveguide
- Measures effective magnetization (Meff), anisotropy (K), gyromagnetic ratio (γ), damping (α), inhomogeneous broadening (ΔHO), exchange stiffness (A), inverse spin Hall effect (ISHE) voltage
|Instrument||Bandwidth*||Temperature Range||Magnetic Field|
|PhaseFMR-8||2-8 GHz||Room Temperature||User Supplied
Electromagnet / Power Supply
|CryoFMR-8||2-8 GHz||4-400 K: PPMS / DynaCool
55-400 K: VersaLab
10-350 K: MI Cryostation
|±9, 14, 16 T: PPMS / DynaCool
±3 T: VersaLab
±0.7 T: MI Cryostation
Quantum Design introduces its first portable, cryogen-free cryocooler-based material characterization platform – VersaLab. With a temperature range of 50 – 400K, this 3 tesla platform is perfect for accomplishing many types of materials characterization in a limited space.
The MPMS 3 incorporates major advances in data acquisition, temperature control and magnetic field control with ≤10-8 emu sensitivity. The award- winning design of Quantum Design’s MPMS 3 also provides expanded software functionality within its user-friendly MultiVu interface.
The high-performance, compact IR Image Furnace from Quantum Design offers unsurpassed performance in a convenient, stand-alone design. Rivaling much larger and more costly IR furnaces, it uses the Floating Zone (FZ) method to promote single crystal growth from a polycrystalline rod.
Quantum Design's patented high-symmetry SQUID design and electronics provide the most rugged and sensitive all-thin-film sensors commercially available, and give you everything you need to configure flexible, powerful detection systems for your research.