&lt;title&gt;Microfabricated silicon gas chromatographic microchannels: fabrication and performance&lt;/title&gt;

Matzke, Carolyn M.; Kottenstette, Richard Joseph; Casalnuovo, S.A.; Frye-Mason, Gregory C.; Hudson, M. L.; Sasaki, Darryl Y.; Manginell, Ronald P.; Wong, C. S.

doi:10.1117/12.324309

Cited by 41 publications

(23 citation statements)

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“…R, and the indentation modulus E*. The elastic response relationship of the curve is given in equation (1).…”

Section: Sioxnyfilm Mechanical Propertiesmentioning

confidence: 99%

<title>Integratible process for fabrication of fluidic microduct networks on a single wafer</title>

Matzke¹,

Ashby²,

Bridges³

et al. 1999

Microfluidic Devices and Systems II

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We present a microelectronics fabrication compatible process that col],prises photolithography and a key room temperature SiON thin film plasma deposition to define and seal a fluidic microduct network. Our single wafer process is independent of therrno-mechanical material properties, particulate cleaning, global flatness, assembly alignment, and glue medium application, which are crucial for wafer fusion bonding or sealing techniques using a glue medium. From our preliminary experiments, we have identified a processing window to fabricate channels on silicon, glass and quartz substrates. Channels with a radius of curvature between 8 and 50 pm, are uniform along channel lengths of several inches and repeatable across the wafer surfaces. To further develop this technology, we have begun characterizing the SiON film properties such as elastic modulus using nanoindentation, and chemical bonding compatibility with other microelectronic materials.

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“…R, and the indentation modulus E*. The elastic response relationship of the curve is given in equation (1).…”

Section: Sioxnyfilm Mechanical Propertiesmentioning

confidence: 99%

<title>Integratible process for fabrication of fluidic microduct networks on a single wafer</title>

Matzke¹,

Ashby²,

Bridges³

et al. 1999

Microfluidic Devices and Systems II

Self Cite

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“…15 Micro-channel devices have several advantages over more conventional GC structures including reduced size and cost, lower dead volume, and design flexibility. The performance of such devices is highly dependent upon optimization of channel length, width, and depth.…”

Section: Chemical Sensing Devicesmentioning

confidence: 99%

“…The 1 µm wide trenches were etched to an approximate depth of 7.5 µm while the 3.5 µm trenches were etched to a depth of approximately 9.5 µm. 15 for the reactive species to diffuse to the bottom of the trench and more difficult for etch products to be extracted. Improved ARDE effects have been obtained for the DRIE process under high SF 6 flow conditions due to a reduction in redeposition of etch products.…”

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confidence: 99%

Post-Processed Integrated Microsystems

Shul¹,

Kravitz²,

Christenson³

et al. 2001

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This report represents the completion of a three-year Laboratory-Directed Research and Development (LDRD) program to develop a low cost platform for integrated microsystems that is easily configured to meet a wide variety of specific applications-driven needs. Once developed, this platform, which incorporates many of the elements that are common to numerous microsystems, will enable integrated microsystem users access to this technology without paying the high up-front development costs that are now required. The process starts with the fabrication, or acquisition, of wafers which have sparsely placed device or circuit components fabricated in any foundried technology (Si CMOS or bipolar technologies, high-frequency GaAs technologies, MEMS, etc.). We call these "smart substrates." Using the diverse processing capabilities of SNL, we then intend to "post-process" high-value components in open areas on the front or back of the wafers and microelectronically integrate the added components with the pre-placed circuitry. Examples of post-processed components include sensors, antennas, SAW devices, passive elements, micro-optics, and surface-mounted hybrids. The combination of preplaced electronics and post-processed components will enable the development of many new types of integrated microsystems. Targeted applications include integrated sensor systems, tags, and electromechanical systems. INTRODUCTIONAdvanced optoelectromechanical system design is constantly pushing for higher levels of functionality and reliability with lower system size, weight, power, and cost. To achieve these goals, many system designs are envisioned as fully integrated "microsystems-on-a-chip". This level of integration is often hard to realize because of the necessity of combining different devices made with diverse materials and processes, all in a single microelectronic technology (i.e., silicon CMOS).Here we propose a simpler, faster, and more cost-effective approach to integrated microsystem design that addresses many of these problems. The process starts with the fabrication, or acquisition, of wafers with sparsely placed device or circuit components fabricated in any foundried technology (Si CMOS or bipolar technologies, high-frequency GaAs technologies, MEMS, etc.). We call these "smart substrates". Using the diverse processing capabilities of SNL, we then intend to "post-process" (i.e., to interrupt a microelectronic production sequence in mid stream and do something unique) high-value components in open areas on the front or back of the wafers and microelectronically integrate the added components with the pre-placed circuitry. Examples of post-processed components include sensors, antennas, SAW devices, LIGA-formed components, passive elements, micro-optics, and surface-mounted hybrids. The combination of pre-placed electronics and post-processed components will enable the development of many new types of integrated microsystems. Targeted applications include integrated sensors and control electronics, electromechanical s...

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“…A Si DRIE process, similar to that used to fabricate the preconcentrator, is employed to produce the GC column [4]. Because of the exceptionally high aspect ratio and anisotropy of the DRIE process, closely spaced, narrow gas flow channels can be etched into the Si substrate to a depth many times the channel width.…”

Section: Gc Columnmentioning

confidence: 99%

“…After the channels are etched, the Si substrate is thermally oxidized to produce a thin, glasslike layer on the surface of the channels in order to facilitate stationary phase deposition (see below). Closed channels are produced by anodically bonding a Pyrex lid to the top surface of the Si substrate [4]. Since the bonding process is carried out at elevated temperatures, Pyrex is used because it closely matches Si's thermal expansion coefficient.…”

Section: Gc Columnmentioning

confidence: 99%

Gas phase chemical detection with an integrated chemical analysis system

Casalnuovo

Frye-Mason²,

Kottenstette³

et al.

Proceedings of the 1999 Joint Meeting of the European Frequency and Time Forum and the IEEE International Frequency Control Sym

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Microfabrication technology has been applied to the development of a miniature, multi-channel gas phase chemical laboratory that provides fast response, small size, and enhanced versatility and chemical discrimination. Each analysis channel includes a sample preconcentrator followed by a gas chromatographic separator and a chemically selective surface acoustic wave detector array to achieve high sensitivity and selectivity. The performance of the components, individually and collectively, is described.

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<title>Microfabricated silicon gas chromatographic microchannels: fabrication and performance</title>

Cited by 41 publications

References 0 publications

<title>Integratible process for fabrication of fluidic microduct networks on a single wafer</title>

<title>Integratible process for fabrication of fluidic microduct networks on a single wafer</title>

Post-Processed Integrated Microsystems

Gas phase chemical detection with an integrated chemical analysis system

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