Abstract
The nanofriction properties of hexagonal boron nitride (h-BN) are vital for its application as a substrate for graphene devices and solid lubricants in micro- and nano-electromechanical devices. In this work, the nanofriction characteristics of h-BN on Si/SiO2 substrates with a bias voltage are explored using a conductive atomic force microscopy (AFM) tip sliding on the h-BN surface under different substrate bias voltages. The results show that the nanofriction on h-BN increases with an increase in the applied bias difference (Vt−s) between the conductive tip and the substrate. The nanofriction under negative Vt−s is larger than that under positive Vt−s. The variation in nanofriction is relevant to the electrostatic interaction caused by the charging effect. The electrostatic force between opposite charges localized on the conductive tip and at the SiO2/Si interface increases with an increase in Vt−s. Owing to the characteristics of p-type silicon, a positive Vt−s will first cause depletion of majority carriers, which results in a difference of nanofriction under positive and negative Vt−s. Our findings provide an approach for manipulating the nanofriction of 2D insulating material surfaces through an applied electric field, and are helpful for designing a substrate for graphene devices.
Highlights
Electric fields play a critical role in substrate materials and interface lubricating materials
All electrostatic nanofriction and adhesion measurements were conducted on hexagonal boron nitride (h-BN) under various electric fields
When Vt s exists, similar to charging a capacitor, the opposite charge is distributed on the conductive tip surface and at the Si/SiO2 interface
Summary
Electric fields play a critical role in substrate materials and interface lubricating materials. Meyer’s work in non-contact atomic force microscopy (AFM) proved that photonic friction is the main dissipative channel below the critical temperature [25], and Park et al [26, 27] studied the contribution of photonic and electronic dissipation to friction. The friction and adhesion of the electrical contact sliding interface on h-BN are critical to the performance, life, and reliability of graphene nanoelectronics devices. The nanoscale friction and adhesion characteristics of h-BN were studied by applying an independent bias on a conductive AFM tip and substrate in an ambient environment. With many recorded force–distance curves of h-BN, the bias-dependent nanofriction of h-BN through electrostatic interactions under different electric fields was studied. The friction and adhesion bias-dependent mechanism of h-BN at the electrified sliding interface are presented
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