Ryan A. Peck scite author profile

Ryan A. Peck

4Publications

6Citation Statements Received

88Citation Statements Given

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University of California, Riverside

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Ultrahigh Resolution Titanium Deep Reactive Ion Etching

Woo

Gott

Peck

et al. 2017

ACS Appl. Mater. Interfaces

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Titanium (Ti) represents a promising new material for microelectromechanical systems (MEMS) because of its unique properties. Recently, this has been made possible with the advent of processes that enable deep reactive ion etching (DRIE) of high-aspect-ratio (HAR) structures in bulk Ti substrates. However, to date, these processes have been limited to minimum feature sizes (MFS) ≥750 nm. Although this is sufficient for many applications, MFS reduction to the deep submicrometer range opens potential for further device miniaturization and an opportunity for endowing devices with unique functionalities that are derived from precisely defined structures within this length scale regime. Herein, we report results from studies seeking to create means for realizing such opportunities through extension of Ti DRIE to the deep submicrometer scale. The effects of key process parameters on etch performance were investigated, and the understanding gained from these studies formed the development of a new ultrahigh resolution (UHR) Ti DRIE process. Using this process, we demonstrate, for the first time, fabrication of HAR structures in bulk Ti substrates with 150 nm MFS, smooth vertical sidewalls (88°), good etch rate (587 nm/min), and mask selectivity (11.1). This represents a fivefold or greater improvement in MFS relative to our previously reported processes and a 29-fold or greater improvement over more recent processes reported by others. As such, the UHR Ti DRIE process extends the state-of-the-art considerably, and it opens important new opportunities for Ti MEMS, particularly in the implantable medical device realm.

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Meso-Scale Particle Image Velocimetry Studies of Neurovascular Flows <em>In Vitro</em>

Peck¹,

Bahena²,

Jahan³

et al. 2018

JoVE

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Correction to Ultrahigh Resolution Titanium Deep Reactive Ion Etching

Woo¹,

Gott²,

Peck³

et al. 2017

ACS Appl. Mater. Interfaces

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Meso-Scale Particle Image Velocimetry Studies of Neurovascular Flows <em>In Vitro</em>

Peck¹,

Bahena²,

Jahan³

et al. 2018

JoVE

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Particle image velocimetry (PIV) is used in a wide variety of fields, due to the opportunity it provides for precisely visualizing and quantifying flows across a large spatiotemporal range. However, its implementation typically requires the use of expensive and specialized instrumentation, which limits its broader utility. Moreover, within the field of bioengineering, in vitro flow visualization studies are also often further limited by the high cost of commercially sourced tissue phantoms that recapitulate desired anatomical structures, particularly for those that span the mesoscale regime (i.e., submillimeter to millimeter length scales). Herein, we present a simplified experimental protocol developed to address these limitations, the key elements of which include 1) a relatively low-cost method for fabricating mesoscale tissue phantoms using 3-D printing and silicone casting, and 2) an open-source image analysis and processing framework that reduces the demand upon the instrumentation for measuring mesoscale flows (i.e., velocities up to tens of millimeters/second). Collectively, this lowers the barrier to entry for nonexperts, by leveraging resources already at the disposal of many bioengineering researchers. We demonstratethe applicability of this protocol within the context of neurovascular flow characterization; however, it is expected to be relevant to a broader range of mesoscale applications in bioengineering and beyond.

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Ryan A. Peck

Ultrahigh Resolution Titanium Deep Reactive Ion Etching

Meso-Scale Particle Image Velocimetry Studies of Neurovascular Flows <em>In Vitro</em>

Correction to Ultrahigh Resolution Titanium Deep Reactive Ion Etching

Meso-Scale Particle Image Velocimetry Studies of Neurovascular Flows <em>In Vitro</em>

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