Abstract
Spin Torque Oscillators (STOs) are promising solutions in a wide variety of next generation technologies from read-head sensors in high-density magnetic recording technology to neural oscillator units for neuromorphic computing. There are several metrics that can be used to quantify the performance of an STO such as power, quality factor, frequency tunability, etc., most of which are dependent on the design of the STO device itself. Furthermore, determining the most important metric will be contingent on its desired application, meaning that it is crucial to understand how the STOs design parameters influence all aspects of its performance so that its design can be optimized to perform the desired function. In this work, we analyzed spin torque oscillations generated from 20 magnetic tunnel junctions with in-plane anisotropy and patterned into elliptical nano-pillars with a wide range of sizes and aspect ratios. For each device, we acquired 20 to 50 data sets at various bias fields and currents and used power spectral density plots to measure output power, frequency, linewidth, quality factor, and power-to-linewidth ratio for each set. We also analyzed each STOs performance in terms of the bias fields and bias currents required to maximize output power and signal quality as well as the frequency tunability with both field and current. By comparing all of these performance metrics between the 20 STOs tested, we studied the influence of device size and shape on all aspects of STO performance and used correlation coefficients to quantify relative magnitude of these effects.
Highlights
INTRODUCTIONSpin-torque oscillators (STOs) are nanoscale, ferromagnetic devices capable of generating self-sustained, high frequency signals, which are caused by stable magnetization precessions induced by a spin polarized current via the spin transfer torque (STT) effect. Implementing STOs in modern technologies is challenging since the output power and quality factors of their signals are several orders of magnitude lower than needed for modern applications. STOs exhibit many unique and novel properties such as nonlinearity, frequency tunability and synchronization which give them exciting prospects for generation computation, communication, and sensor technologies
We study spin-torque oscillations generated from 20 MgO-based magnetic tunnel junctions (MTJs) and their dependence on both device size and shape
This result shows that increasing RP causes Δf to increase, has no influence on fp, and causes quality factor (Qf) to decrease at both maximum Pout and maximum Qf
Summary
Spin-torque oscillators (STOs) are nanoscale, ferromagnetic devices capable of generating self-sustained, high frequency signals, which are caused by stable magnetization precessions induced by a spin polarized current via the spin transfer torque (STT) effect. Implementing STOs in modern technologies is challenging since the output power and quality factors of their signals are several orders of magnitude lower than needed for modern applications. STOs exhibit many unique and novel properties such as nonlinearity, frequency tunability and synchronization which give them exciting prospects for generation computation, communication, and sensor technologies. Experimental work performed over the last decade has demonstrated that the frequency in STOs can be tuned over several GHz using external DC biases such as a magnetic field and an electrical current.. STO coupling can be done via spin wave propagation, dipole interactions, or electrical coupling, which is caused by self-modulation of the current through each STO.18 Is this feature is a promising solution for enhancing output power and quality of STO signals, but it has made STOs a promising solution in a novel generation computing paradigm where large scale oscillator arrays mimic neural activities for bio-inspired functions.. By studying all aspects of the STOs performance, our study provides a basis for application-specific optimization of future STO designs
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