Yemin Tang scite author profile

This paper reports high-density arrays of 3-dimensional (3-D) high-aspect ratio MEMS structures that can imitate biological hairs. Hair has many properties, including high aspect ratio (long and small footprint), large surface area, mechanical flexibility and robustness, and customized material properties. Hair sensors can be made in large arrays, provide high sensitivity through local neural processing, and offer a multiplicity of functions. In nature, hairs typically exist in large-scale arrays, offering distributed sensing functions, redundancy, and improved stability, sensitivity, and dynamic range. In this paper, we present a fabrication technology for forming highly dense 3-D arrays of microstructures useful for a variety of sensing applications, which realize some of these biological advantages. We have fabricated 4x4, 5x5, and 10x10 accelerometer arrays, achieving a sensor density of ~100 sensors/mm 2 . Initial testing shows accelerometer resonant frequencies and static capacitance values that vary with proof mass and hair/spring dimensions as expected.

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Ultra high aspect-ratio and thick deep silicon etching (UDRIE)

Tang

Sandoughsaz

Najafi

2017

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High aspect-ratio low-noise multi-axis accelerometers made from thick silicon

Tang

Najafi

2016

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Yemin Tang

Ultra Deep Reactive Ion Etching of High Aspect-Ratio and Thick Silicon Using a Ramped-Parameter Process

Technology for fabricating dense 3-D microstructure arrays for biomimetic hair-like sensors

Ultra high aspect-ratio and thick deep silicon etching (UDRIE)

High aspect-ratio low-noise multi-axis accelerometers made from thick silicon

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