Owen Y. Loh scite author profile

Nanoelectromechanical (NEM) switches are similar to conventional semiconductor switches in that they can be used as relays, transistors, logic devices and sensors. However, the operating principles of NEM switches and semiconductor switches are fundamentally different. These differences give NEM switches an advantage over semiconductor switches in some applications--for example, NEM switches perform much better in extreme environments--but semiconductor switches benefit from a much superior manufacturing infrastructure. Here we review the potential of NEM-switch technologies to complement or selectively replace conventional complementary metal-oxide semiconductor technology, and identify the challenges involved in the large-scale manufacture of a representative set of NEM-based devices.

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Tablet-level origin of toughening in abalone shells and translation to synthetic composite materials

Espinosa

et al. 2011

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Nacre, the iridescent material in seashells, is one of many natural materials employing hierarchical structures to achieve high strength and toughness from relatively weak constituents. Incorporating these structures into composites is appealing as conventional engineering materials often sacrifice strength to improve toughness. Researchers hypothesize that nacre's toughness originates within its brick-and-mortar-like microstructure. Under loading, bricks slide relative to each other, propagating inelastic deformation over millimeter length scales. This leads to orders-of-magnitude increase in toughness. Here, we use in situ atomic force microscopy fracture experiments and digital image correlation to quantitatively prove that brick morphology (waviness) leads to transverse dilation and subsequent interfacial hardening during sliding, a previously hypothesized dominant toughening mechanism in nacre. By replicating this mechanism in a scaled-up model synthetic material, we find that it indeed leads to major improvements in energy dissipation. Ultimately, lessons from this investigation may be key to realizing the immense potential of widely pursued nanocomposites.

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Nanofountain‐Probe‐Based High‐Resolution Patterning and Single‐Cell Injection of Functionalized Nanodiamonds

Loh¹,

Lam²,

Chen³

et al. 2009

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Nanodiamonds are rapidly emerging as promising carriers for next-generation therapeutics and drug delivery. However, developing future nanoscale devices and arrays that harness these nanoparticles will require unrealized spatial control. Furthermore, single-cell in vitro transfection methods lack an instrument that simultaneously offers the advantages of having nanoscale dimensions and control and continuous delivery via microfluidic components. To address this, two modes of controlled delivery of functionalized diamond nanoparticles are demonstrated using a broadly applicable nanofountain probe, a tool for direct-write nanopatterning with sub-100-nm resolution and direct in vitro single-cell injection. This study demonstrates the versatility of the nanofountain probe as a tool for high-fidelity delivery of functionalized nanodiamonds and other agents in nanomanufacturing and single-cell biological studies. These initial demonstrations of controlled delivery open the door to future studies examining the nanofountain probe's potential in delivering specific doses of DNA, viruses, and other therapeutically relevant biomolecules.

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Robust Carbon‐Nanotube‐Based Nano‐electromechanical Devices: Understanding and Eliminating Prevalent Failure Modes Using Alternative Electrode Materials

Loh

Wei

et al. 2010

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The failure modes common to widely pursued carbon‐nanotube‐based nano‐electromechanical systems are investigated. A fundamental understanding of the underlying mechanisms for failure and their relation to the device design space is developed through complementary in situ electromechanical characterization and dynamic multiphysics models. It is then found that the facile replacement of commonly used metal thin‐film electrodes with diamondlike carbon structures leads to a dramatic improvement in reliability. This enables experimental demonstration of numerous actuation cycles without failure, and reliable application to volatile memory operations.

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Electric field-induced direct delivery of proteins by a nanofountain probe

Loh¹,

Ho²,

Rim³

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

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We report nanofabrication of protein dot and line patterns using a nanofountain atomic force microscopy probe (NFP). Biomolecules are continuously fed in solution through an integrated microfluidic system, and deposited directly onto a substrate. Deposition is controlled by application of an electric potential of appropriate sign and magnitude between the probe reservoir and substrate. Submicron dot and line molecular patterns were generated with resolution that depended on the magnitude of the applied voltage, dwell time, and writing speed. By using an energetic argument and a Kelvin condensation model, the quasi-equilibrium liquid-air interface at the probe tip was determined. The analysis revealed the origin of the need for electric fields in achieving protein transport to the substrate and confirmed experimental observations suggesting that pattern resolution is controlled by tip sharpness and not overall probe aperture. As such, the NFP combines the highresolution of dip-pen nanolithography with the efficient continuous liquid feeding of micropipettes while allowing scalability to 1-and 2D probe arrays for high throughput.arrays ͉ atomic force microscopy ͉ nanolithography ͉ patterning ͉ nanofabrication

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Owen Y. Loh

Nanoelectromechanical contact switches

Tablet-level origin of toughening in abalone shells and translation to synthetic composite materials

Nanofountain‐Probe‐Based High‐Resolution Patterning and Single‐Cell Injection of Functionalized Nanodiamonds

Robust Carbon‐Nanotube‐Based Nano‐electromechanical Devices: Understanding and Eliminating Prevalent Failure Modes Using Alternative Electrode Materials

Electric field-induced direct delivery of proteins by a nanofountain probe

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