Overview:  The most widespread problem affecting our national infrastructure is corrosion.  Metallic corrosion also affects nearly every industry sector.  In fact, the world-wide economic impact of corrosion to be $2.5 trillion annually, equating to 3.4% of the global gross domestic product.  To better design steel bridges for corrosion protection, objective methods are needed for predicting the services lives of common coatings in the diverse range of climates in which they are applied.

In Phase 1 of this study, the performance of six corrosion protection methods was established by developing a novel laboratory protocol simulating harsh real-world environments. Now, further work is needed to establish the performance of these systems in other environments, provide life-cycle cost estimates for these solutions, and perform laboratory testing to evaluate the performance of a broader range of corrosion protection systems, including new systems and repairs to damaged systems.

Project Start Date: Summer or Fall 2023

Lead Researcher: Jennifer McConnell, Ph.D.

Failing Corrosion Protection Systems: (left) failing paint system, (middle) failure of uncoated weathering steel member due to corrosion in the Fern Hollow Bridges, which collapsed in Pittsburgh, PA on Jan. 28, 2022, (right), laboratory specimens simulating corrosion of different base materials with failing corrosion protection systems.

Overview: Bridges are designed to resist a variety of static and dynamic loads arising from vehicular, pedestrian and environmental loads. Thermal loads acting on a bridge can vary as temperature changes, resulting in expansion and contraction in bridge components. The variation in temperature on a daily, seasonal, and yearly basis can influence the bridge response and lead to more cracking. With the changing environment as evident from sea level rise and extreme weather-related events, temperature differentials may increase, thereby inducing stresses beyond the estimated thermal loads for which the bridge was initially designed. The effects of thermal loads plus overweight vehicles on existing distressed bridges may have unintended consequences that need to be studied, including but not limited to more cracking and nonlinear thermal load, which in turn, influence the overall structural behavior and dynamic characteristics.

This project utilizes a combination of existing climatic data from the National Bridge Inventory (NBI) and structural health monitoring data to evaluate various structural components impacted by increasing variations in temperature on existing concrete slab and slab-on-girder bridges. Frequencies and mode shapes will be studied to better understand temperature loading, heat transfer by radiation, and increased vehicular loads due to overweight vehicles on existing bridges. The expected outcome of this research is to predict changes in dynamic characteristics of bridges due to increasing temperature and vehicular loads in the wake of the changing environment, and how this may influence future design loads.

Project Start Date: Fall 2023

Lead Researcher: Monique Head, Ph.D., P.E.

Temperature distribution in composite bridges (Source: Zhou and Yi, 2013). Preliminary work by PI Head has been focused on analyzing overweight vehicular loads and its influence on live load distribution factors used for analysis of existing bridges, where the effects of thermal loads need to also be considered.

Overview:  Biochar is a charcoal-like material formed by heating organic waste biomass (e.g., waste wood, manure, organic materials) in an oxygen-free environment. Biochar production is an ancient technology that has seen a resurgence worldwide due to bicohar’s ability to increase water infiltration, water retention, and pollutant retention and transformation if amended to soil or environmental treatment media.

We are evaluating the mechanisms by which biochars from different feedstocks and pyrolysis conditions when added to soil alter pore structure, redox conditions, microbial communities, plant growth, and nutrient retention and transformation. This study focuses on the impact of biochar amendment of roadway soils and compacted soils in urban parks. Activities will include field measurements, laboratory testing such as X-ray CT to quantify pore structure, and development of mathematical models to describe the relevant processes. Students will have the opportunity to interact with environmental scientists and policy makers in state and municipal governments who develop regulations on the use of biochar for stormwater treatment and carbon sequestration.

Anticipated Start Date: January or September 2023

Lead Researcher: Paul Imhoff, Ph.D.

Biochar application to roadway soil to treat stormwater runoff: A – biochar from waste wood, B – application of biochar from supersack (white bag), C – biochar tilled into roadway soil, and D – X-ray CT of soil core containing soil and biochar.

Overview: The Chin lab studies how anthropogenic activity ranging from the discharge of contaminants to greenhouse gas emissions perturbs biogeochemical processes.  We are particularly interested in how chemical reactions contribute to contaminant fate (sorption, photolysis, redox) and the feedback between these processes and the environmental microbiome. We also study how dissolved organic matter influences and facilitates reactions of environmental and biogeochemical importance. We conduct a roughly equal mix of lab and field-based research that range from local sites to both the Arctic and Antarctic as well as locations in between.  Currently, the Chin group is engaged in redox/electrochemistry research in wetlands at locations across the United States.

Anticipated Start Date: September 2023

Lead Researcher: Yu-Ping Chin, PhD.

Chin Lab collecting field data.

Overview:  Railroads that pass through the desert areas have difficulties dealing with the sand mixed with ballast, which impacts maintenance and operations. Sand infiltrates into the ballast layer due to different factors like the wind transporting sand grains or by migration of sand from the subgrade layer to the ballast layer. When sand fills ballast voids, the ballast can see a change in mechanical properties that can affect maintenance and safety. Thus, for example, sand infiltration into ballast affects the track stiffness (K). A low value of track stiffness can cause differential settlement. Whereas a high value of track stiffness leads to a reduction in track deflections but an increase in rail/tie forces and associated stresses in the track. The project aims to study the behavior of ballast when fouled with sand, and then measure its effect on track stiffness, track deflection, track degradation, and potentially time to the next maintenance.

To achieve project goals, a railway simulator box was built in the lab, which contains the substructure layer represented by the ballast and the superstructure layer represented by the rail, plate, and tie. Different test scenarios are simulated in the lab starting with clean ballast (0% fouling) and then sand-fouled ballast by 10%, 25%, 50%, 75%, 100%, and 125%, respectively. A load, representing a heavily loaded rail vehicle, is applied and deflection behavior measured using Linear Variable Differential Transformer (LVDTs). This allows for the analysis of track deflection, stiffness, and performance under a range of fouling conditions.

Start Date: Spring 2023/Fall 2023

Lead Researcher:  Allan Zarembski, Ph.D.

Figure (1) represents different track locations that have a variety sand fouled ballast ratio (location 1 to 4 sand ratio is 62.7%, 50.7%, 25.5%, and 25.9%) (Zakeri & Abbasi, 2012). Figure (2) represents the lab test’s setup. Figure (3) represents the data collected from the lab experiment (clean ballast test), which measures the deflection over the repeated load cycles. Figure (4) represents the stiffness under the repeated load.

Overview: Railroad rights-of-way often utilize through- and side-cuts to traverse mountainous and hilly terrain and avoid steep grades and tight curves. Consequently, cutting can produce unstable slopes, or geohazards, whose failure may waste material into the right-of-way, foul track, or cause derailments. To keep railways with geohazard populations operational, cuts should be routinely monitored such that slope maintenance and failure mitigation strategies can be implemented in a timely manner.

In Phase 1 of this research project, a geotechnical hazard identification and assessment framework reliant on remotely sensed images of the study was created. Using  computer vision and artificial intelligence techniques to analyze right-of-way inspection videos recorded by track geometry cars and satellite images, portions of Amtrak’s Harrisburg Line in Pennsylvania  were studied without using on-site geotechnical measurements. The framework aimed to relatively assess identified geohazards for failure likelihood to determine which should be prioritized for maintenance. Phase 2 of this research project aims to expand the framework with additional predictors from the available data to demonstrate the model’s ability to identify and relatively assess geohazards by testing it on the entirety of the Harrisburg Line.

Start Date: June 2023

Lead Researcher:  Allan Zarembski, Ph.D.

Relative Risk Assessment Framework: (left) failure event on the Harrisburg Line in June, 2021 which disrupted operations, (right) combined risk scores across the study area calculated using object detection to localize unstable slope features of interest and landslide susceptibility mapping using geospatial data extracted from satellite imagery.