Min-Wu Kim scite author profile

Nanoelectromechanical (NEM) switches have received widespread attention as promising candidates in the drive to surmount the physical limitations currently faced by complementary metal oxide semiconductor technology. The NEM switch has demonstrated superior characteristics including quasi-zero leakage behaviour, excellent density capability and operation in harsh environments. However, an unacceptably high operating voltage (4-20 V) has posed a major obstacle in the practical use of the NEM switch in low-power integrated circuits. To utilize the NEM switch widely as a core device component in ultralow power applications, the operation voltage needs to be reduced to 1 V or below. However, sub-1 V actuation has not yet been demonstrated because of fabrication difficulties and irreversible switching failure caused by surface adhesion. Here, we report the sub-1 V operation of a NEM switch through the introduction of a novel pipe clip device structure and an effective air gap fabrication technique. This achievement is primarily attributed to the incorporation of a 4-nm-thick air gap, which is the smallest reported so far for a NEM switch generated using a 'top-down' approach. Our structure and process can potentially be utilized in various nanogap-related applications, including NEM switch-based ultralow-power integrated circuits, NEM resonators, nanogap electrodes for scientific research and sensors.

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An ultra-low voltage MEMS switch using stiction-recovery actuation

Kim¹,

Song²,

Yang³

et al. 2013

J. Micromech. Microeng.

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In this paper, an ultra-low voltage microelectromechanical system (MEMS) switch is proposed, modeled and demonstrated. Through the introduction of torsional hinges, stiction-recovery actuation was possible, and thus irreversible stiction could be overcome. Owing to this see-saw-like actuation, the switch could be freely designed to have low stiffness resulting in an ultra-low actuation voltage. The proposed switch shows an actuation voltage of around 3 V, which is especially low compared with typical values of several tens of volts in conventional microelectromechanical switches. Variation of the actuation voltage stayed under 12% during 106 cycles. Switching performance was degraded by an increase of contact resistance rather than in-use stiction. Using the proposed switches, low-voltage mechanical logic gates were also proposed and successfully demonstrated, operating at VDD of 3 V.

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3-terminal nanoelectromechanical switching device in insulating liquid media for low voltage operation and reliability improvement

Lee

Kim

et al. 2009

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Nanowire Mechanical Switch with a Built‐In Diode

Han

Ahn

Kim

et al. 2010

Small

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A Complementary Dual-Contact MEMS Switch Using a “Zipping” Technique

Song

Kim

Seo

et al. 2014

J. Microelectromech. Syst.

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Min-Wu Kim

A sub-1-volt nanoelectromechanical switching device

An ultra-low voltage MEMS switch using stiction-recovery actuation

3-terminal nanoelectromechanical switching device in insulating liquid media for low voltage operation and reliability improvement

Nanowire Mechanical Switch with a Built‐In Diode

A Complementary Dual-Contact MEMS Switch Using a “Zipping” Technique

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