Applied Research
  
SSP&A's recognized expertise in groundwater, geochemistry, and environmental science has led to several ongoing research projects.

Fate and Transport of PCBs in the Subsurface

Since 1988, SSP&A staff members have participated on an expert panel assembled by the Texas Eastern Transmission Corporation to develop feasible remedial alternatives for sites contaminated with polychlorinated biphenyl (PCB) compounds in soil and groundwater. The Texas Eastern Groundwater Panel, directed by Dr. Charles Andrews, President of SSP&A, conducts investigations on the behavior of PCBs in the subsurface environment and the chemical properties of PCBs and their degradation products. These investigations include laboratory and field studies in biodegradation, surfactant chemistry and transport, PCB transport and sorption, and the behavior of DNAPL in the subsurface, and field testing methods for PCB solubilization and recovery in fractured and porous media.  PDF Figure

Research Efforts at the University of Alabama

Dr. Chunmiao Zheng, developer of the MT3D code and liaison of SSP&A, is currently leading an interdisciplinary research team at the University of Alabama to develop a comprehensive framework for designing pump-and-treat groundwater remediation systems. The project integrates groundwater simulation, optimization, and parameter estimation techniques to design groundwater pump-and-treat systems which meet various physical, environmental, and budgetary constraints. The key components of the framework are Modflow and MT3D, two of the most popular flow and transport simulation models used in groundwater remediation designs. These simulation models are being coupled with an optimization model to automatically determine optimal well locations and pumping/injection rates under realistic field conditions. In addition, the optimization model is capable of optimizing flow and transport parameters required by the simulation models. This makes it possible to automatically update flow and transport parameters, and accordingly, the well locations and pumping/injection rates, based on the monitoring results after the remedial operation has begun.

Several additional research projects are underway as part of the comprehensive simulation-optimization framework. Alternative optimization approaches, including differential dynamic programming, simulated annealing, and generic algorithms, are being investigated for their efficiency and flexibility in developing optimal remediation designs and parameter estimation under realistic field conditions. New and improved numerical algorithms are being incorporated into the MT3D code to significantly increase the computational efficiency that is essential to a simulation-optimization approach. The feasibility of linking MT3D with a multi-species geochemical code is also being studied. This linkage could dramatically enhance the ability of the MT3D code to simulate more sophisticated chemical reactions and bioremediation.

Parameterization and Predictive Analysis in Environmental Modeling

Watermark Numerical Computing (creator of PEST), SSP&A, and the Department of Environmental Engineering, University of Queensland are undertaking collaborative research to improve environmental data processing through the use of numerical models, pooling resources and expertise to improve the use of computer simulation in environmental management.. The theme of much of this research is parameter estimation and predictive uncertainty analysis. More details here.

Assessment of Performance Limitations of Soil-Vapor Extraction

SSP&A participated in a comprehensive assessment of soil-vapor extraction as a remedial technology for volatile organic compounds. The study was initiated as part of an evaluation of the effectiveness of a soil-vapor extraction system in operation at a Superfund site. Although the extraction system had removed a significant quantity of volatile organic compounds from the soil, clean-up levels had not been met and the mass of contaminant remaining was found to be several thousand times greater than that predicted by the initial studies on the performance of the extraction system. Site conditions such as variability in the physical and chemical characteristics of the soils were found to have a profound influence on the performance of the soil-vapor extraction system. The work summarized the fundamental chemical and physical phenomena which can influence the effectiveness of soil-vapor extraction systems on a practical field-scale, and described the scientific basis upon which the performance of the systems can be evaluated and predicted.