Philip P. Schonewill
METHOD OF IMAGING THE ELECTRICAL CONDUCTIVITY DISTRIBUTION OF A SUBSURFACE
A method of imaging electrical conductivity distribution of a subsurface containing metallic structures with known locations and dimensions is disclosed. Current is injected into the subsurface to measure electrical potentials using multiple sets of electrodes, thus generating electrical resistivity tomography measurements. A numeric code is applied to simulate the measured potentials in the presence of the metallic structures. An inversion code is applied that utilizes the electrical resistivity tomography measurements and the simulated measured potentials to image the subsurface electrical conductivity distribution and remove effects of the subsurface metallic structures with known locations and dimensions.
Shuttha Shutthanandan
Shuttha Shutthanandan is a materials scientist at Pacific Northwest National Laboratory.
Pete McGrail
Rapid Start Fuel Reforming Systems and Techniques
An on-board fuel processor includes a microchannel steam reforming reactor (30) and a water vaporizer (40) heated in series with a combustion gas. The reformer (30) and the vaporizer (40) are both of a cross-flow panel configuration that allows for low combustion side pressure drop. Fuel is directly injected into the steam, and during a rapid cold start, both the combustion gas flow rate and the steam to carbon ratio are substantially increased relative to their steady state operating values. A rapid cold start can be achieved in under 30 seconds with a manageable amount of electric power consumption, removing impediments to use in automotive fuel cell applications.
3D Printed Face Covering and Reusable Respirator Designs
Tirthankar Chakraborty (TC)
Chandru Dhandapani, PhD
Dhandapani is currently working on radiation convection equilibrium simulations using the LES model DP-SCREAM and bridging the gap between cloud chamber observations and global models using cloud-resolved PINACLES simulations.
Lai-yung Ruby Leung
Dr. L. Ruby Leung is a Battelle Fellow at Pacific Northwest National Laboratory. Her research broadly cuts across multiple areas in modeling and analysis of climate and the hydrological cycle.
Aquatic Organism Tracking Devices, Systems and Associated Methods
Compared with MHK energy, widely-used hydropower have also been facing similar environmental concerns. To help investigate the potential of fish injury and mortality from passage through hydropower turbines, PNNL developed the JSATS. Recent JSATS development included several state-of-the-art acoustic transmitters, such as the injectable transmitter and the juvenile eel/lamprey transmitter. The latter is the world's smallest acoustic tag. Both these small transmitters have been successfully demonstrated in field studies and helped gather information on species of early life stages that had previously been unobtainable. The highly efficient transducer and circuit designs as well as the high-density micro-battery technology specifically developed for these transmitters were the innovations that made these technological advancements possible. The JSATS operates at 416.7 kHz, a relatively high acoustic frequency that works well filtering out acoustic noises in freshwater environments. With hardware and software modifications, these technologies can be readily adopted for a lower-frequency transmitter for use in marine environments. Our feasibility assessment and laboratory benchtop testing of the transmitter concept at three different frequencies around 200 kHz have shown significant improvements (detailed results listed in the attached document).