Publications

Reichardt, Thomas A.; Hernandez, Oscar R.; Kulp, Thomas J.; Jaramillo, Monica J.; Hoffman, Mary M.; Johnson, Mark S.; Kolda, Tamara G.; Ray, Will R.; Hale, Richard H.; Hunley, Riley H.; Wetherington, Randall W.; Freer, Eva F.; Krebs, John K.

Abstract not provided.

Applied Optics

Shokair, Isaac R.; Johnson, Mark S.; Schmitt, Randal L.; Sickafoose, Shane S.

We discuss a maritime surveillance and detection concept based on Raman scattering of water molecules. Using a range-gated scanning lidar that detects Raman scattered photons from water, the absence or change of signal indicates the presence of a non-water object. With sufficient spatial resolution, a two-dimensional outline of the object can be generated by the scanning lidar. Because Raman scattering is an inelastic process with a relatively large wavelength shift for water, this concept avoids the often problematic elastic scattering for objects at or very close to the water surface or from the bottom surface for shallow waters. The maximum detection depth for this concept is limited by the attenuation of the excitation and return Raman light in water. If excitation in the UV is used, fluorescence can be used for discrimination between organic and non-organic objects. In this paper, we present a lidar model for this concept and discuss results of proof-of-concept measurements. Using published cross section values, the model and measurements are in reasonable agreement and show that a sufficient number of Raman photons can be generated for modest lidar parameters to make this concept useful for near-surface detection.

Shokair, Isaac R.; Johnson, Mark S.; Schmitt, Randal L.; Sickafoose, Shane S.

In this report we discuss a new maritime surveillance and detection concept based on Raman scattering of water molecules. Using a scanning lidar that detects Raman scattered photons from water, the absence or change of signal indicates the p resence of a non - water object. With sufficient spatial resolution a negative two dimensional imag e of the object can be generate d by the scanning lidar . Because Raman scatt er ing is an inelastic process with a relatively large wavelength shift for water , this concept completely avoids the problematic elastic sc attering for objects at or very close to the water surface . Elastic scattering makes it difficult to disc riminate between water and dark objects at or near the water surface especially when automated detection is required . It is also difficult to deal wit h elastic scattering from the bottom surface for shallow waters. The maximum detection depth for this concept is limited by the attenuation of the excitation and return Raman light in water. If excitation in the UV is used, fluorescence can be used for dis crimination between organic and non - organic objects. Range gating can be used for this concept for detection of objects below a specified depth. In this report we develop a lidar model for this concept to estimate the number of detected Raman photons fo r variable lidar parameters and depths in the presence of the solar background . We also report on the results of proof - of - concept measurements using the Sandia Ares lidar with excitation at 355 nm. The measurements show good agreement with the lidar mode l predictions. The detected number of photons for typical lidar parameter shows the concept is viable and applicable to a variety of day and nighttime detection scenarios. This concept has many potential applications including ne ar - surface mine detection, swimmer detection for security purposes, wide area search, as well as other civilian applications.

Herges, Thomas H.; Schmitt, Randal L.; Bossert, David B.; Johnson, Mark S.; Sanchez, A.L.; Glen, Crystal C.; Maniaci, David C.; Naughton, Brian T.

Abstract not provided.

Herges, Thomas H.; Schmitt, Randal L.; Bossert, David B.; Johnson, Mark S.; Sanchez, A.L.; Glen, Crystal C.; Maniaci, David C.; Naughton, Brian T.

Abstract not provided.

Schmitt, Randal L.; Sickafoose, Shane S.; Johnson, Mark S.; Sobczak, Alice M.; Glen, Crystal C.

Abstract not provided.

Schmitt, Randal L.; Sobczak, Alice M.; Sanchez, A.L.; Johnson, Mark S.; Servantes, B.L.

A unique aerosol flow chamber coupled with a bistatic LIDAR system was implemented to measure the optical scattering cross sections and depolarization ratio of common atmospheric particulates. Each of seven particle types (ammonium sulfate, ammonium nitrate, sodium chloride, potassium chloride, black carbon and Arizona road dust) was aged by three anthropogenically relevant mechanisms: 1. Sulfuric acid deposition, 2. Toluene ozonolysis reactions, and 3. m-Xylene ozonolysis reactions. The results of pure particle scattering properties were compared with their aged equivalents. Results show that as most particles age under industrial plume conditions, their scattering cross sections are similar to pure black carbon, which has significant impacts to our understanding of aerosol impacts on climate. In addition, evidence emerges that suggest chloride-containing aerosols are chemically altered during the organic aging process. Here we present the direct measured scattering cross section and depolarization ratios for pure and aged atmospheric particulates.

Schmitt, Randal L.; Johnson, Mark S.; Servantes, B.L.; Sanchez, A.L.; Hebner, Gregory A.

Abstract not provided.

Glen, Crystal C.; Sanchez, A.L.; Rivera, Danielle R.; Schmitt, Randal L.; Sickafoose, Shane S.; Santarpia, Joshua S.; Servantes, B.L.; Johnson, Mark S.; Pack, Michael P.; Brockmann, John E.; Lucero, Daniel A.

Abstract not provided.

Schroder, Kevin L.; Boney, Craig M.; Claassen, Paul J.; Pedroncelli, Michael L.; Spooner, Jeffrey T.; Lang, Alvin R.; Magee, Glen I.; Krumel, Leslie J.; Hargis, Philip J.; Shokair, Isaac R.; Ashlock, Tad A.; Daniels, James W.; Klarkowski, James R.; Johnson, Mark S.

Abstract not provided.

Schroder, Kevin L.; Boney, Craig M.; Claassen, Paul J.; Pedroncelli, Michael L.; Spooner, Jeffrey T.; Lang, Alvin R.; Magee, Glen I.; Krumel, Leslie J.; Hargis, Philip J.; Shokair, Isaac R.; Ashlock, Tad A.; Daniels, James W.; Klarkowski, James R.; Johnson, Mark S.

Abstract not provided.

Bender, Susan F.; Bender, Susan F.; Rodacy, Philip J.; Schmitt, Randal L.; Hargis, Philip J.; Johnson, Mark S.; Klarkowski, James R.; Magee, Glen I.; Bender, Gary L.

The Defense Advanced Research Projects Agency (DARPA) has recognized that biological and chemical toxins are a real and growing threat to troops, civilians, and the ecosystem. The Explosives Components Facility at Sandia National Laboratories (SNL) has been working with the University of Montana, the Southwest Research Institute, and other agencies to evaluate the feasibility of directing honeybees to specific targets, and for environmental sampling of biological and chemical ''agents of harm''. Recent work has focused on finding and locating buried landmines and unexploded ordnance (UXO). Tests have demonstrated that honeybees can be trained to efficiently and accurately locate explosive signatures in the environment. However, it is difficult to visually track the bees and determine precisely where the targets are located. Video equipment is not practical due to its limited resolution and range. In addition, it is often unsafe to install such equipment in a field. A technology is needed to provide investigators with the standoff capability to track bees and accurately map the location of the suspected targets. This report documents Light Detection and Ranging (LIDAR) tests that were performed by SNL. These tests have shown that a LIDAR system can be used to track honeybees. The LIDAR system can provide both the range and coordinates of the target so that the location of buried munitions can be accurately mapped for subsequent removal.

Singh, Anup K.; Schmitt, Randal L.; Johnson, Mark S.; Hargis, Philip J.; Simonson, Robert J.; Simonson, Robert J.; Schoeniger, Joseph S.; Ashley, Carol S.; Brinker, C.J.; Hance, Bradley G.

This report summarizes the development of sensor particles for remote detection of trace chemical analytes over broad areas, e.g residual trinitrotoluene from buried landmines or other unexploded ordnance (UXO). We also describe the potential of the sensor particle approach for the detection of chemical warfare (CW) agents. The primary goal of this work has been the development of sensor particles that incorporate sample preconcentration, analyte molecular recognition, chemical signal amplification, and fluorescence signal transduction within a ''grain of sand''. Two approaches for particle-based chemical-to-fluorescence signal transduction are described: (1) enzyme-amplified immunoassays using biocompatible inorganic encapsulants, and (2) oxidative quenching of a unique fluorescent polymer by TNT.