By Maegan Murray, ���سԹ�

RICHLAND, Wash. – After seeing initial success in developing an ultra high-performance grout to potentially encapsulate solid secondary waste at the Hanford Site, (WRPS) is providing a Washington State University Tri-Cities professor and his research team with more than $300,000 to further the research.

The ���سԹ� team, led by civil engineering professor Srinivas Allena, is developing what is known as an ultra high-performance cementitious composite grout. The team’s final formulation will use industrial byproducts such as coal ash and steel slag that have the potential to reduce costs compared to commercially available and prepackaged high-performance grouts, while reducing the impact on the environment. The solid secondary waste it would encapsulate could include items such as used or broken equipment, contaminated tools and equipment that require stabilization and encapsulation prior to disposal.

WRPS is the ’s Tank Operations contractor responsible for managing Hanford’s 56 million gallons of highly radioactive waste and preparing it for delivery to the . The organization provided the WSU team last year with more than $140,000 to develop a grout to encapsulate solid secondary wastes from tank farms and future Waste Treatment Plant operations, and the team came up with several formulations. Now, the WSU team is further optimizing those formulations to produce a cost-effective and sustainable grout formulation.

The end formulation has to be able to handle large physical stresses while proving resistant to rapid freezing and thawing cycles, low porosity and long-term durability.

For one of their formulations, Allena and his team showed success in replacing a typical ingredient in commercially available encapsulation grouts, known as silica fume – a byproduct from the silicon industry – with a substance known as fly ash, which is a remnant product from burning coal in thermal power plants. The fly ash, often a waste product, would serve as a cheaper and locally sourceable option, in addition to reducing the amount of coal-based ash that is sent to landfills or returned to coal mines for disposal.

For another formulation, the team plans to replace fine sand typically used in encapsulation grouts with locally-sourced, larger-particle sand, which would not require a sieving process. The removal of the sieving process saves on cost and previous results have shown that the large sand-containing formulation holds the needed strength and low porosity required for an encapsulation grout.

The technique, though promising, is in the proof-of-concept phase. Any future use at Hanford would still need to meet disposal criteria for any given waste stream and undergo regulatory approval and any applicable permitting processes.

“We’re repurposing waste products and also reducing the cost while ensuring and enhancing the durability properties required for an encapsulation grout,” Allena said. “Our initial testing has shown good results.”

The team also plans to partially replace regular cement with blast furnace slag, which is a byproduct powder from steel industries. Using slag would help reduce greenhouse gas emissions.

“Cement industries cause approximately 7 to 11 percent of greenhouse gas emissions worldwide,” Allena said. “Cement is made from the burning of limestone and leads to the release of a lot of carbon dioxide. Reducing the demand on cement by using slag will therefore reduce cement production and the associated greenhouse gas emissions.”

Allena said if they are successful with their end formulation, their grout has the potential to be used in a variety of applications, such as bridge construction, and has large commercial potential.

 

Media contacts:

Srinivas Allena, ���سԹ� engineering faculty, 509-372-7161, srinivas.allena@wsu.edu

Jeffrey Dennison, ���سԹ� director of marketing and communication, 509-372-7319, Jeffrey.dennison@wsu.edu

Maegan Murray, ���سԹ� public relations specialist, 509-372-7333, maegan_murray@wsu.edu

By Maegan Murray, ���سԹ�

RICHLAND, Wash. – It was the proximity that brought Louis Theriault to Washington State University Tri-Cities, but it has been the valuable opportunities that have made him successful as a student and so far in his goal of becoming a civil engineer.

Theriault was homeschooled for most of his life, taking courses through the Mid-Columbia Partnership offered by the Kennewick School District. So when he had the opportunity to take running start classes at the university level at ���سԹ�, he thought he would give it a go.

The option turned out to be a perfect fit. Theriault completed his entire general education requirements for his university degree in two years at no cost to him through running start, all before entering as a full-time student at ���سԹ�. Before entering as a junior standing, he applied for and was awarded the STEM Scholars scholarship, which would pay for $8,400 per year for up to four academics years in tuition. And in his remaining few years at ���سԹ�, he could dive right into his engineering classes.

As a result of connections he had built at ���سԹ�, Theriault landed an internship at the Bechtel National campus in Oak Ridge, Tennessee, this summer, which paired perfectly with what he had learned and is continuing to learn in his engineering classes.

The combination of the experiences, he said, has provided him with the foundation to be successful both in his career and as a young professional.

“I’ve had an amazing experience here at ���سԹ�,” he said. “The combination of what I’ve learned through my classes, my internship at Bechtel, and even opportunities for student life activities on campus, has allowed me to stretch myself as an individual and learn lots about my path as an engineer and as a professional.”

Small classes, large potential

In his courses, Theriault said he continues to learn essential engineering fundamentals and theory that applies directly to his future work as an engineer. And in conjunction with his work, his small class sizes have allowed him to really get to know his classmates, which he formed study groups with and therefore, a tight-knit peer group that he could count on.

Combining those things with getting to know his professors and their teaching styles, he has been able to excel in his engineering classes and thrive on campus.

“The personalization of the courses here and all of the individualized attention through the small classes has been really nice,” he said. “It’s easy to ask our professors questions because we get to know them. And I’m in a lot of the same classes as my peers throughout my time here at ���سԹ�.”

From course work to dream work

Through his internship this summer, he was able to apply what he’s learned and experienced in his classes to his job.

His work this summer focused on designing a support structure for a tank pertaining to the nuclear industry. He was responsible for the design, calculations to ensure that it would support the structure and for getting it reviewed and approved by his peers. By the end of the experience, he had an approximately 30-page report detailing the design. The support structure will be implemented to support a tank in the next several years.

Theriault said not only did the experience provide him with real-world, on-the-job skills in engineering, but it was an opportunity that allowed him to directly put to use all the things he had learned in his classes and more.

Theriault said he has been invited back for another summer experience next year. He hopes it will throttle him into a full-time job after graduating in the spring of 2020.

“I think that practical experience is crucial,” he said. “I am going into week three in some of my courses, and I know exactly what they’re talking about before we get to that material. I’ve been able to already apply some of those ideas. It’s been a big learning curve, but it’s definitely increased my knowledge, for sure.”

Feeling at home through student life

In addition to his academic experiences, Theriault also formerly served as a student ambassador with the ���سԹ� Office of Admissions. He gave campus tours and presented to students a genuine feel for what he had experienced through ���سԹ�.

He also participates in many of the campus activities. Whether it be resource fairs and networking events held by the Office of Student Life and the Career Development Office, or fun activities between classes in the Student Union Building or in the Floyd Atrium as hosted by the Student Entertainment Board, he said he tries to participate in as much as he can.

“It’s these types of activities that really help students get involved and have fun on campus,” he said. “I try to go to as many of the campus events as I can. I really appreciate that they have so many options for students, in addition to the academic-based activities and events.”

For more information on the ���سԹ� engineering programs, visit .

By Maegan Murray

Stemming from his background growing up in Ethiopia, Yonas Demissie views water as a commodity more valuable than oil.

In the nation of more than 94 million people, just 42 percent have access to clean water in Ethiopia. That is why the ���سԹ� assistant professor of civil and environmental engineering has directed his research efforts toward the monitoring, exploration and evaluation of the resource that is vital in sustaining life.

“Here in the U.S., we take water for granted,” Demissie said. “Our daily water use here is as much as 10 times than that of a person in other countries where water is in limited supply.”

Demissie said he has personally never experienced not having access to clean water, because he grew up in Ethiopia’s capital city of Addis Ababa where infrastructure is more advanced than other parts of the nation. But that doesn’t mean the issue doesn’t hit close to home.

“I may have grown up in the city, but the water scarcity issue and famine in the country are regular news,” he said. “It always bothered me to see images of starving children. There is no excuse for a child to get hungry. As a society, we should all be responsible for that. I want my research in water to be my contribution to society. Water is a very critical resource that needs to be accessible, protected and properly managed.”

Demissie is currently working on a myriad of research projects at ���سԹ� that focus on various aspects of water-related issues.

“In terms of overall impact, any study on understanding and properly managing water resources is key,” he said.

Climate research on Department of Defense facilities

Demissie is currently half-way through a four-year project studying the impact of climate change on military infrastructure, focusing specifically on whether defense infrastructure and facilities could handle increased flooding and abnormal increases and fluctuations in precipitation. His research is funded as part of a $1 million contract with the U.S. Department of Defense.

“DOD has many facilities across the globe and many of those installations are close to coastal areas,” he said. “They are worried about sea level rise, increased extreme storms and how that will affect their facilities and operations. Our research is to assess flooding risk with the DOD facilities’ existing storm water management system and whether it is sufficient or needs to be upgraded.”

Demissie said when there is an increase in the temperature, there is an increase in the atmosphere’s ability to hold more water, which increases the chance of heavy rainfall. He said he and his team are currently analyzing the historical climate data to see if precipitation has increased over the years, whether storms now last longer and whether there has been an increase in the intensity, frequency and duration of the precipitation.

A change in precipitation caused by climate change and/or other factors, Demissie said, could also have drastic impacts in other areas such as agriculture.

“In our regions, for example, how snowfall on the Cascade Mountains is going to be affected due to climate change will be an important issue in determining future agriculture productions,” he said. “Even though the total amount of annual precipitation may not be affected, there may be a shift in when that precipitation may occur.”

Instead of most of the precipitation occurring in the winter and early spring, as it is now, Demissie said it may occur mostly in winter, or even in the fall. He said farmers may not have the water when they need it for their crops and that the timing shift could have a significant negative effect.

In a similar study funded by the state’s water center, Demissie recently completed evaluating and updating decades-old design standards used to construct water related infrastructure, such as culverts, bridges and dams, for all the counties in Washington state.

Additionally, he and his team were also recently awarded funding from the state’s water center to study drought characteristics in the Yakima basin and to evaluate effectiveness of a $4 billion water management plan currently under consideration for tackling drought in the region.

“Climate change is one of our generation’s major issues that we are going to have to deal with,” he said.

Reducing effects of nitrates and phosphors stemming from biofuels industry on Gulf of Mexico

Researchers are making significant strides in the biofuels industry, creating fuels for jet airplanes, cars and more that help reduce the United States’ carbon footprint. WSU is leading the industry in research for biofuels with its Northwest Advanced Renewables Alliance (NARA). But increases in the crops in the Midwest required to make certain biofuels may be having a damaging effect on ecosystems in the Mississippi River and Gulf of Mexico.

Demissie is studying the impact of increased nitrates and phosphors from farming practices related to the biofuels industry in Midwest on the Mississippi River and Gulf of Mexico, and how they can minimize those issues.

“In the Midwest, they are making biofuels from corn, which requires increased nitrogen and phosphors applications, which end up in the streams,” he said. “Increased nitrate and phosphors lead to algal bloom, which eventually prevents vegetation and fish from growing in lakes and other water bodies.”

Demissie said increased algae prevents the natural process of photosynthesis from happening in the water as the sun can’t reach the lower levels and life essentially ceases from occurring. Because the Gulf of Mexico is connected to the Midwest through the Mississippi River, those nitrates and phosphors run directly into the gulf, causing algae bloom that currently covers areas as large as Connecticut and Rhode Island, combined.

“The Gulf of Mexico is one of the important regions for fishing,” he said. “We are growing more corn in the Midwest to meet demands of biofuels, but at the same time, we could end up killing an important industry downstream. We want to make sure that doesn’t happen.”

Monitoring groundwater contamination at Hanford

Since he started at ���سԹ� in 2012, Demissie has consistently worked with Hanford Site contractors and Pacific Northwest National Laboratory staff in monitoring and modeling the groundwater flow from the site to ensure there is no radiation and other toxic contamination with vital sources such as aquifers and reservoirs used for human daily water use.

Contamination from the Hanford Site stems back to the facilities’ production of plutonium from World War II and the Cold War. Chemicals were released, both planned and unplanned, into the soil around the site. Scientists have since worked to develop and improve upon models that are used to predict the flow, as well as determine which areas they should treat.

“We are consistently monitoring groundwater contamination for Hanford, using various monitoring and modeling projects to tell where it’s flowing and how fast it is traveling,” he said.

“We’re always working to improve methods and models for doing so,” he said. “We’ve made significant strides in reducing the contamination from those early years.”

Researching means to open access for Nile River

Demissie is presently working with a team of people to examine current flow patterns and allocations of the Nile River, and how they can more effectively be shared by all African countries associated with the river.

The Nile River is the world’s longest river, flowing 6,700 kilometers through 10 countries in eastern Africa, where water is mostly scarce. Demissie said any water project in the upstream tributaries of the Nile has been under political contention, as countries like Egypt and Sudan use the river as their main source of water and electric power generation.

Ethiopia, where 80-90 percent of the Nile water originates, historically was not using the river despite being hit by regular famines caused by highly variable rainfall in the region. However, Ethiopia is now constructing the largest dam in Africa on the Blue Nile, the main tributary of the Nile River, for electric power generation. Political officials in Egypt are worried that it would limit their access to the river, which they said they have a natural right to two-thirds of the resource, as indicated in The Nile Waters Agreement that was signed in 1959, which Ethiopia never signed.

Demissie and his colleagues Gabriel Senay, Naga Manohar Velpuri, Stefanie Bohms and Mekonne Gebremichael completed a study in 2014 that integrated satellite data and modeling to detail the variability of water sources in the Nile Basin. Their study revealed that about 85 percent of runoff generated in the equatorial region (Ethiopia, Tanzania, Kenya and Uganda) is lost along the river pathway that includes the Sudd wetlands, which has an area approximately twice the size of Maryland. This proportion is higher than the literature reported loss of 50 percent.

In addition, their study found that the expected average annual Nile flow at the Aswan Dam in Egypt is 13 cubic kilometers greater than the reported amount of 84 cubic kilometers originally reported. Demissie said that means there is a flow amount that equates to more than half of Colorado River of water each year that was not accounted for during the 1959 water agreement.

Demissie said the loss in runoff and flow volume at different sections of the Nile River, however, tend to be more than what can be explained by evaporation losses, suggesting a potential recharge to deeper aquifers that are not connected to the Nile channel systems. He said the study indicated the need for increased instrumentation detailing the hydrometeorology of the basin.

“Our knowledge regarding water availability in the Nile Basin and how much and where water is lost in the system is limited,” he said. “But our analysis shows that we get more water into the system than what was originally estimated. There is extra water that Ethiopia can use.”

Demissie said he hopes his group’s initial research will lead to bigger developments in assessing the direction, flow and amount of water from the Nile, which could lead to positive legislation among the African countries that may help lead to an agreement that would benefit all.

“Having a good understanding of water as a resource and coming up with a better management strategy I believe is critical for most societies,” he said.