# Pure voltage controlled magnetic nano-oscillator

**Authors:** Qianchang Wang, Yiheng Li, Andres Chaves, Joseph Schneider, Jin-Zhao, Hu, Greg Carman

arXiv: 1812.02264 · 2018-12-07

## TL;DR

This paper introduces a voltage-controlled nanomagnetic oscillator using a multiferroic structure, enabling energy-efficient RF signal generation with tunable frequency via voltage bias, avoiding current-based actuation.

## Contribution

It presents a novel pure voltage actuation mechanism for nanomagnetic oscillators using multiferroics, expanding design possibilities for energy-efficient RF devices.

## Key findings

- Achieves magnetic oscillation with AC voltage and DC bias on a piezoelectric substrate.
- Tuning of ferromagnetic resonance (FMR) via voltage bias allows wide frequency range.
- Simulation results show impact of voltage parameters and magnet thickness on oscillation.

## Abstract

Nanomagnetic oscillator is a key component for radio-frequency (RF) signal generation in many nano-scale spintronic devices. However, the actuation mechanisms of nanomagnetic oscillators are mostly current-based, which is energy inefficient at nanoscale due to Joule heating. In this study, we present a new actuation mechanism for nanomagnetic oscillator with pure voltage input using a multiferroic structure. An AC voltage with a DC bias is applied to the piezoelectric substrate, and steady perpendicular magnetic oscillation is achieved in the attached Ni disk when the frequency of the voltage matches the ferromagnetic resonance (FMR) of the Ni disk. The FMR can be tuned by simply changing the voltage bias, therefore, the oscillation frequency has a wide range. A systematic simulation study is conducted to investigate the impact of the voltage amplitude, frequency, waveform, as well as the thickness of the magnet on the magnetic oscillation. This opens new possibilities of designing energy efficient nanomagnetic oscillators using multiferroics that have large amplitude and wide frequency range.

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Source: https://tomesphere.com/paper/1812.02264