Broad frequency and amplitude control of vibration in freestanding graphene via scanning tunneling microscopy with calculated dynamic pseudo-magnetic fields

TL;DR

This paper demonstrates a method to control the frequency and amplitude of vibrations in freestanding graphene using scanning tunneling microscopy, enabling precise local mechanical manipulation and pseudo-magnetic field generation.

Contribution

It introduces a novel technique for tuning graphene vibrations over wide ranges of frequency and amplitude via STM, linking mechanical motion to pseudo-magnetic fields.

Findings

Vibrations tuned over nearly four decades around 10 Hz.

Amplitude controlled over nearly three decades around 1 nm.

Mechanical vibrations directly related to pseudo-magnetic field strength.

Abstract

A technique to locally generate mechanical vibrations in freestanding graphene using scanning tunneling microscopy (STM) is presented. The frequency of the mechanical vibrations is tuned over nearly four decades and is centered around 10 Hz. The amplitude of the vibrations also changes over nearly three decades centered on 1 nm. The oscillating motion is generated in two ways: first, by scanning the STM tip on the surface and second, by scanning the bias voltage on the STM tip. The frequency and amplitude of the displaced freestanding graphene is quantitatively transformed to the frequency and strength of the locally generated pseudo-magnetic field for our specific geometry.