Critical Conditions for High Efficiency Flocculation of Freshwater Algae with Ferric Chloride
Abstract not provided.
Publications
Critical Conditions for High Efficiency Flocculation of Freshwater Algae with Ferric Chloride
Abstract not provided.
Flocculation efficiencies under various mixing mechanisms
Abstract not provided.
Flocculation of algae under shear :
Abstract not provided.
A Coordination Chemistry Modelfor Algae Autocoagulation
Abstract not provided.
Toward an understanding of algae flocculation and its dependence on water chemistry
Abstract not provided.
Critical Conditions for Ferric Chloride Induced Flocculation of Freshwater Algae
Biotechnology and Bioengineering
Abstract not provided.
First Principles for Algae Flocculation
Abstract not provided.
Sandia Biofuels Overview
Abstract not provided.
Understanding the Consequences of Liquid Sodium Metal Fires
Abstract not provided.
Modeling thermal abuse of Li ion transportation batteries
Abstract not provided.
Algal cell surface characterization and simulation for harvesting applications
Abstract not provided.
Fundamental models of algae flocculation dynamics to identify sensitivities and controls
Abstract not provided.
Predicting electrochemical phenomena in lithium molten salt thermal batteries
Abstract not provided.
First-principles flocculation : key to low energy algal biofuels processing
Abstract not provided.
First-principles flocculation as the key to low energy algal biofuels processing
Abstract not provided.
Predicting electrochemical phenomena in lithium molten salt batteries
Abstract not provided.
Sodium metal fires and advanced reactor safety
Abstract not provided.
Metal fires and their implications for advanced reactors
Transactions of the American Nuclear Society
With the scoping experimental results, initial computational model development is underway. Coupling the experimental program with the computational modern analysis will develop the expertise and capability needed to identify, investigate, and assess key metal fires issues.
Diagnostic development for determining the joint temperature/soot statistics in hydrocarbon-fueled pool fires : LDRD final report
A joint temperature/soot laser-based optical diagnostic was developed for the determination of the joint temperature/soot probability density function (PDF) for hydrocarbon-fueled meter-scale turbulent pool fires. This Laboratory Directed Research and Development (LDRD) effort was in support of the Advanced Simulation and Computing (ASC) program which seeks to produce computational models for the simulation of fire environments for risk assessment and analysis. The development of this laser-based optical diagnostic is motivated by the need for highly-resolved spatio-temporal information for which traditional diagnostic probes, such as thermocouples, are ill-suited. The in-flame gas temperature is determined from the shape of the nitrogen Coherent Anti-Stokes Raman Scattering (CARS) signature and the soot volume fraction is extracted from the intensity of the Laser-Induced Incandescence (LII) image of the CARS probed region. The current state of the diagnostic will be discussed including the uncertainty and physical limits of the measurements as well as the future applications of this probe.
On the dissolution of iridium by aluminum
The potential for liquid aluminum to dissolve an iridium solid is examined. Substantial uncertainties exist in material properties, and the available data for the iridium solubility and iridium diffusivity are discussed. The dissolution rate is expressed in terms of the regression velocity of the solid iridium when exposed to the solvent (aluminum). The temperature has the strongest influence in the dissolution rate. This dependence comes primarily from the solubility of iridium in aluminum and secondarily from the temperature dependence of the diffusion coefficient. This dissolution mass flux is geometry dependent and results are provided for simplified geometries at constant temperatures. For situations where there is negligible convective flow, simple time-dependent diffusion solutions are provided. Correlations for mass transfer are also given for natural convection and forced convection. These estimates suggest that dissolution of iridium can be significant for temperatures well below the melting temperature of iridium, but the uncertainties in actual rates are large because of uncertainties in the physical parameters and in the details of the relevant geometries.
Metal fire implications for advanced reactors. Part 2, PIRT results
This report documents the results of a Phenomena Identification and Ranking Table (PIRT) exercise performed at Sandia National Laboratories (SNL) as well as the experimental and modeling program that have been designed based on the PIRT results. A PIRT exercise is a structured and facilitated expert elicitation process. In this case, the expert panel was comprised of nine recognized fire science and aerosol experts. The objective of a PIRT exercise is to identify phenomena associated with the intended application and to then rank the current state of knowledge relative to each identified phenomenon. In this particular PIRT exercise the intended application was sodium fire modeling related to sodium-cooled advanced reactors. The panel was presented with two specific fire scenarios, each based on a hypothetical sodium leak in an Advanced Breeder Test Reactor (ABTR) design. For both scenarios the figure of merit was the ability to predict the thermal and aerosol insult to nearby equipment (i.e. heat exchangers and other electrical equipment). When identifying phenomena of interest, and in particular when ranking phenomena importance and the adequacy of existing modeling tools and data, the panel was asked to subjectively weigh these factors in the context of the specified figure of merit. Given each scenario, the panel identified all those related phenomena that are of potential interest to an assessment of the scenario using fire modeling tools to evaluate the figure of merit. Each phenomenon is then ranked relative to its importance in predicting the figure of merit. Each phenomenon is then further ranked for the existing state of knowledge with respect to the ability of existing modeling tools to predict that phenomena, the underlying base of data associated with the phenomena, and the potential for developing new data to support improvements to the existing modeling tools. For this PIRT two hypothetical sodium leak scenarios were evaluated for the ABTR design. The first scenario was a leak in the hot side of the intermediate heat transport system (IHTS) resulting in a sodium pool fire. The second scenario was a leak in the cold side of the IHTS resulting in a sodium spray fire.
Metal Fires and Their Implication for Advanced Reactors
Abstract not provided.
Heat Flux from Ambient Air Solid Propellant Fire Plumes
Abstract not provided.
Metal fire implications for advanced reactors. Part 1, literature review
Public safety and acceptance is extremely important for the nuclear power renaissance to get started. The Advanced Burner Reactor and other potential designs utilize liquid sodium as a primary coolant which provides distinct challenges to the nuclear power industry. Fire is a dominant contributor to total nuclear plant risk events for current generation nuclear power plants. Utilizing past experience to develop suitable safety systems and procedures will minimize the chance of sodium leaks and the associated consequences in the next generation. An advanced understanding of metal fire behavior in regards to the new designs will benefit both science and industry. This report presents an extensive literature review that captures past experiences, new advanced reactor designs, and the current state-of-knowledge related to liquid sodium combustion behavior.
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