Roberto Pezone scite author profile

During the past decades micro-electromechanical microphones have largely taken over the market for portable devices, being produced in volumes of billions yearly. Because performance of current devices is near the physical limits, further miniaturization and improvement of microphones for mobile devices poses a major challenge that requires breakthrough device concepts, geometries, and materials. Graphene is an attractive material for enabling these breakthroughs due to its flexibility, strength, nanometer thinness, and high electrical conductivity. Here, we demonstrate that transfer-free 7 nm thick multilayer graphene (MLGr) membranes with diameters ranging from 85− 155 to 300 μm can be used to detect sound and show a mechanical compliance up to 92 nm Pa −1 , thus outperforming commercially available MEMS microphones of 950 μm with compliances around 3 nm Pa −1 . The feasibility of realizing larger membranes with diameters of 300 μm and even higher compliances is shown, although these have lower yields. We present a process for locally growing graphene on a silicon wafer and realizing suspended membranes of patterned graphene across through-silicon holes by bulk micromachining and sacrificial layer etching, such that no transfer is required. This transfer-free method results in a 100% yield for membranes with diameters up to 155 μm on 132 fabricated drums. The device-to-device variations in the mechanical compliance in the audible range (20−20000 Hz) are significantly smaller than those in transferred membranes. With this work, we demonstrate a transfer-free method for realizing wafer-scale multilayer graphene membranes that is compatible with high-volume manufacturing. Thus, limitations of transfer-based methods for graphene microphone fabrication such as polymer contamination, crack formation, wrinkling, folding, delamination, and low-tension reproducibility are largely circumvented, setting a significant step on the route toward high-volume production of graphene microphones.

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Ultra-sensitive graphene membranes for microphone applications

Baglioni

Pezone

Vollebregt

et al. 2023

Nanoscale

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Hybrid fabrication of multimodal intracranial implants for electrophysiology and local drug delivery

et al. 2022

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High-Performance Wafer-Scale Transfer-Free Graphene Microphones

Pezone

Baglioni

Sarro

et al. 2023

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A repeatable method to fabricate multi-layer graphene (ML-gr) membranes of 2r = 85 -155 μm (t < 10 nm) with a 100% yield on 100 mm wafers is demonstrated. These membranes show higher sensitivity than a commercial MEMS-Mic combined with an area reduction of 10x. The process overcomes one of the main limitations when integrating graphene diaphragms in microphones due to the absence of automatic transfer methods on non-planarized target substrates. This method aims to overcome this limitation by combining a full-dry release of Chemical Vapor Deposition (CVD) graphene by Deep Reactive Ion Etching (DRIE) and vapor HF (VHF).

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Ultra-sensitive graphene membranes for microphone applications

Baglioni¹,

Pezone²,

Vollebregt³

et al. 2022

Preprint

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Microphones exploit the motion of suspended membranes to detect sound waves.Since the microphone performance can be improved by reducing the thickness and mass of its sensing membrane, graphene-based microphones are expected to outperform state-of-the-art microelectromechanical (MEMS) microphones and allow further miniaturization of the device. Here, we present a laser vibrometry study of the acoustic response of suspended multilayer graphene membranes for microphone applications.

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Roberto Pezone

Sensitive Transfer-Free Wafer-Scale Graphene Microphones

Ultra-sensitive graphene membranes for microphone applications

Hybrid fabrication of multimodal intracranial implants for electrophysiology and local drug delivery

High-Performance Wafer-Scale Transfer-Free Graphene Microphones

Ultra-sensitive graphene membranes for microphone applications

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