Publications

Dye, Joshua A.; Robinson, Alex L.

Abstract not provided.

Kayser, Ste-ven C.; Robinson, Alex L.

Abstract not provided.

Hooper, Russell H.; Smith, Thomas M.; Robinson, Alex L.; Shadid, J.N.S.; Crockatt, M.M.C.; Shields, Sidney S.; Swan, Matthew S.

Abstract not provided.

Kayser, Ste-ven C.; Robinson, Alex L.; Lavin, Judith M.

Abstract not provided.

Kayser, Ste-ven C.; Selander, James S.; Robinson, Alex L.; Lavin, Judith M.; Secor, Ethan B.; Parson, Ted B.; Gallegos, Michael A.; Maines, Erin M.

Abstract not provided.

Robinson, Alex L.; Bliss, Clayton B.

Abstract not provided.

Kayser, Ste-ven C.; Lavin, Judith M.; Secor, Ethan B.; Gallegos, Michael A.; Keicher, David K.; Robinson, Alex L.; Maines, Erin M.

Abstract not provided.

Robinson, Alex L.; Bliss, Clayton B.

Abstract not provided.

Robinson, Alex L.; Pfeifer, Kent B.; Casias, Adrian L.; Howell, Stephen W.; Sorensen, Neil R.; Missert, Nancy A.

We have developed and characterized novel in-situ corrosion sensors to monitor and quantify the corrosive potential and history of localized environments. Embedded corrosion sensors can provide information to aid health assessments of internal electrical components including connectors, microelectronics, wires, and other susceptible parts. When combined with other data (e.g. temperature and humidity), theory, and computational simulation, the reliability of monitored systems can be predicted with higher fidelity.

Herman, Jeremy A.; Robinson, Alex L.; Binasiewicz, Edward J.

Abstract not provided.

Eichenfield, Matthew S.; Givler, R.C.; Pfeifer, Kent B.; Reinke, Charles M.; Robinson, Alex L.; Resnick, Paul J.; Griffin, Benjamin G.; Langlois, Eric L.; Nielson, Gregory N.; Okandan, Murat O.

After years in the field, many materials suffer degradation, off-gassing, and chemical changes causing build-up of measurable chemical atmospheres. Stand-alone embedded chemical sensors are typically limited in specificity, require electrical lines, and/or calibration drift makes data reliability questionable. Along with size, these "Achilles' heels" have prevented incorporation of gas sensing into sealed, hazardous locations which would highly benefit from in-situ analysis. We report on development of an all-optical, mid-IR, fiber-optic based MEMS Photoacoustic Spectroscopy solution to address these limitations. Concurrent modeling and computational simulation are used to guide hardware design and implementation.

Advanced Functional Materials

Robinson, Alex L.; Zeitler, Todd Z.; Greathouse, Jeffery A.; Denning, Julie M.; Volponi, Joanne V.; White, Michael I.

Abstract not provided.

Robinson, Alex L.; Vianco, Paul T.

Abstract not provided.

Robinson, Alex L.; Casias, Adrian L.

Abstract not provided.

Denning, Julie M.; Greathouse, Jeffery A.; Robinson, Alex L.; Stavila, Vitalie S.; Zeitler, Todd Z.

Abstract not provided.

Stavila, Vitalie S.; Greathouse, Jeffery A.; Pohl, Andrew P.; Robinson, Alex L.; White, Michael I.; Zeitler, Todd Z.

Abstract not provided.

Sensors and Actuators, B: Chemical

Venkatasubramanian, Anandram; Lee, Jin H.; Stavila, Vitalie; Robinson, Alex L.; Allendorf, Mark D.; Hesketh, Peter J.

Metal Organic Frameworks (MOFs) are a rapidly developing class of nanoporous materials with numerous applications in diverse fields such as chemical detection, hazardous gas detection, and carbon capture. Even though numerous articles have been written emphasizing the adsorption properties of these MOFs, their compatibility with respect to the sensing device has not been explored. While there are numerous types of sensing devices that could benefit from the use of MOF-based coatings to enhance sensitivity and selectivity, we are particularly interested in microcantilevers because of the high sensitivity they can provide within a compact, lower-power architecture. In this paper, we address this need by analyzing the effect of the mechanical properties of MOFs on the sensor response. In particular, we are interested in the structural flexibility of MOFs, because this unique guest-induced property can be used for strain-induced sensing attribute of the microcantilever. In this regard we examined the effects of important MOF mechanical properties such as the Young's Modulus, Poisson's ratio, and density on the sensor response for a range of values representative of the MOFs available in the literature. From our analysis we determined that increasing the Young's Modulus and Poisson's ratio improve the response, while the density of the MOF has a negligible effect on the cantilever response. In addition, we also examined the influence on cantilever response of the intermediate layer used to bind the MOF, from which we observe that SiO 2 provides the best sensor response for a given MOF layer. © 2012 Elsevier B.V.

Robinson, Alex L.; Carson, Lowell C.

Abstract not provided.

Robinson, Alex L.; Schauer, Anna L.; Okandan, Murat O.; Nielson, Gregory N.; Langlois, Eric L.; Givler, R.C.; Hochrein, James M.

Abstract not provided.

Robinson, Alex L.; Tran, Hy D.

Significant deformation of thin films occurs when measuring thickness by mechanical means. This source of measurement error can lead to underestimating film thickness if proper corrections are not made. Analytical solutions exist for Hertzian contact deformation, but these solutions assume relatively large geometries. If the film being measured is thin, the analytical Hertzian assumptions are not appropriate. ANSYS is used to model the contact deformation of a 48 gauge Mylar film under bearing load, supported by a stiffer material. Simulation results are presented and compared to other correction estimates. Ideal, semi-infinite, and constrained properties of the film and the measurement tools are considered.

Robinson, Alex L.; Allendorf, Mark D.; Stavila, Vitalie S.; Thornberg, Steven M.

Abstract not provided.

Robinson, Alex L.; Allendorf, Mark D.; Stavila, Vitalie S.; Thornberg, Steven M.

Abstract not provided.

Greathouse, Jeffery A.; Zeitler, Todd Z.; Robinson, Alex L.; Stavila, Vitalie S.; Allendorf, Mark D.

Abstract not provided.

Proceedings of SPIE - The International Society for Optical Engineering

Lee, J.H.; Houk, R.T.J.; Robinson, Alex L.; Greathouse, Jeffery A.; Thornberg, Steven M.; Allendorf, M.D.; Hesketh, P.J.

In this paper we demonstrate the potential for novel nanoporous framework materials (NFM) such as metal-organic frameworks (MOFs) to provide selectivity and sensitivity to a broad range of analytes including explosives, nerve agents, and volatile organic compounds (VOCs). NFM are highly ordered, crystalline materials with considerable synthetic flexibility resulting from the presence of both organic and inorganic components within their structure. Detection of chemical weapons of mass destruction (CWMD), explosives, toxic industrial chemicals (TICs), and volatile organic compounds (VOCs) using micro-electro-mechanical-systems (MEMS) devices, such as microcantilevers and surface acoustic wave sensors, requires the use of recognition layers to impart selectivity. Traditional organic polymers are dense, impeding analyte uptake and slowing sensor response. The nanoporosity and ultrahigh surface areas of NFM enhance transport into and out of the NFM layer, improving response times, and their ordered structure enables structural tuning to impart selectivity. Here we describe experiments and modeling aimed at creating NFM layers tailored to the detection of water vapor, explosives, CWMD, and VOCs, and their integration with the surfaces of MEMS devices. Force field models show that a high degree of chemical selectivity is feasible. For example, using a suite of MOFs it should be possible to select for explosives vs. CWMD, VM vs. GA (nerve agents), and anthracene vs. naphthalene (VOCs). We will also demonstrate the integration of various NFM with the surfaces of MEMS devices and describe new synthetic methods developed to improve the quality of VFM coatings. Finally, MOF-coated MEMS devices show how temperature changes can be tuned to improve response times, selectivity, and sensitivity. © 2010 Copyright SPIE - The International Society for Optical Engineering.

Robinson, Alex L.; Allendorf, Mark D.; Thornberg, Steven M.

Abstract not provided.