Cody Knight and crew

Renewable materials student Cody Knight is a recipient of three scholarships: the Lois & Dick Kearns Scholarship, John R. Snellstrom Scholarship and the Friends of Renewable Materials–Roseburg Forest Products Wood Science and Engineering Scholarship. Before coming to Oregon State, Knight served in the military.

The financial support he receives and his experience in the military inspired him to serve others through his work in the renewable materials program.

“My military experience left me asking a lot of questions about humanity, sustainability the western world and material possessions,” Knight says. “I want to create products from renewable materials that aid in sustainability.”

Knight, who grew up in northern Idaho, remembers spending summers at the lake, sleeping in log cabins.

“There, it was easy to appreciate the beauty of nature,” he says. “I want to preserve that beauty and those kinds of experiences for future generations.”

He’s working to reach his goals through hands-on learning activities outside the classroom. Knight has participated in undergraduate research with Arijit Sinha, associate professor of renewable materials at Oregon State. Knight is helping conduct testing on Freres Lumber’s new mass plywood panel product.

“I was also selected for the Research and Extension Experience for Undergraduates (REEU) program,” Knight says. “This is a three-month long mentored research program with students at Oregon State and from colleges across the United States.”

Knight says his research will evaluate the shear strength of plywood and oriented strand board (OSB) after it has experienced varying degrees of temperatures and cooling times to get a clear picture of the mechanical strength of both products in the event of fire and seismic activity.

“The importance of this is plywood and OSB are typically used in residential housing for the exterior sheathing, which provides lateral support and stability for the structure,” Knight says. “Little research has been done to test their behaviors under these conditions, and I’m excited to find some answers.”

trees

Logging on steep slopes is the most hazardous environment for a forest worker according to John Sessions, University Distinguished Professor and Strachan Chair of Forest Operations Management at Oregon State.

Sessions is part of a team of investigators researching innovative technologies to improve logger safety on steep slopes. Other research team members include Woodam Chung, Ben Leshchinsky, Francisca Belart, Tamara Cushing, John Garland, Jeff Wimer and Brett Morrissette from the College of Forestry and Laurel Kincl from the College of Public Health and Human Sciences. The three-year project is funded by the National Institute for Occupational Safety and Health.

“Logging has consistently been one of the most hazardous industries in the U.S. It has a fatality rate 30 times higher than the national occupation average,” Sessions says. “Increasing mechanization of felling and skidding has removed workers from the forest floor in flat terrain, however, workers remain on the forest floor for felling and extraction in steeper terrain.”

The study examines strategies for replacing forest workers on forest slopes with tethered and non-tethered felling, forwarding equipment and combining mechanized felling with traditional cable yarding methods. The research would improve safety in the steep forest workplace.

Preston Green, a graduate research assistant on the project, focuses specifically on harvesting productivity, cost and environmental impacts of cable-assisted harvesting systems.

“I conduct detailed time studies of harvesting, forwarding and cable yarding equipment, with and without the use of cable-assistance, to quantify the differences in harvesting system productivity and environmental impacts,” Green says.

Green says he first became interested in cable-assisted harvesting as an undergraduate forest engineering student at Oregon State. Industry internships peaked his interest in the subject, and Green decided to attend graduate school to conduct additional research.

“My family has worked in the timber industry for four generations, and I’ve seen the long-term effects that logging injuries can have on families and communities,” Green says. “We’re striving to make improvements in the industry, not just improve statistics. We are dealing with real people that live and work in our communities.”

The project has 15 collaborating companies. The research team includes forest engineers, forest operations specialists, occupational health and safety specialists and a geotechnical engineer.

“Due to the steep slopes throughout Oregon’s forests, we believe the introduction of cable-assisted harvesting equipment can be a paradigm shift that will improve safety and economic competitiveness for the industry in Oregon and beyond. It will provide the ability to implement safe forest restoration practices across the difficult terrain in many public forests,” Sessions says. “Our research results and the widespread interest about the study from forest owners, logging contractors, equipment manufacturers, and state and federal agencies suggest we are on the right track. This technology and our research will likely save lives.”

OFSC construction

The new George W. Peavy Forest Science Center will be unique, not just because of the atmosphere, but because the building will also be a living laboratory.

This living laboratory is one aspect of the SMART-CLT project, led by Mariapaola Riggio, assistant professor of wood design and architecture at Oregon State. The goal of the SMART-CLT project, which stands for “Structural Health Monitoring and Post-Occupancy Performance of Mass Timber Buildings,” is to analyze critical factors impacting the performance of cross-laminated timber during its service life, and develop protocols to monitor these factors in buildings. The SMARTCLT project will study cross-laminated timber on a small and large scale, and will be applied inside the Peavy Forest Science Center, soon to be the new home of the College of Forestry.

“Our project is looking at what is sometimes deemed as ‘serviceability of a structure,’ which includes everything from how the material vibrates, which can be a limiting factor in terms of design for long spans; deflections of the material and acoustics. We’re looking at a variety of factors,” says Evan Schmidt, outreach coordinator at the TallWood Design Institute (TDI).

Riggio says the study is multidisciplinary. The research team involves architects, engineers and industry professionals who will analyze the project from a variety of perspectives. The project is funded by TDI, a collaboration between Oregon State and the University of Oregon and the nation’s leading research collaborative focused on advancing structural wood products.

“It’s not just how the system and the building performs in terms of standard and code requirements, it’s also how it is accepted or how it contributes to the well-being and the comfort of the occupants. That’s why it’s important the project involve a number of partners,” Riggio says.

The living laboratory will provide information for many generations to come.

“Usually research is just a limited amount of time, but this project will last as long as the life of the building,” says Riggio.

The sensors used to monitor the building are a unique aspect of the project, an original idea which will help researchers see what is happening inside the materials of the building.

“We want to understand which approach can be the most effective when analyzing the overall performance while delivering meaningful and valuable information,” says Riggio.

Schmidt says the sensors outfitting the building will monitor the indoor environment, temperature of the mass timber elements, moisture content inside of the wood at various depths and locations, vibration, post-tension loss in the wall systems and more. There will be about 176 different sensor locations.

“We’re measuring a bunch of performance parameters relative to the environment,” Schmidt says. “It’s important to capture because wood is not an inert material. The way it interacts with the environment will impact the way it performs, long-term and short-term.”

While the project will last the life of the building, researchers will also monitor short-term insights during construction to understand the immediate effects.

Researchers believe this project will provide a better understanding of how best to promote the use of mass timber in construction in the U.S.

“We need flagship structures,” Schmidt says. “We need to conduct research during and after construction. The combination of the two will make the public aware and excited about the benefits of mass timber buildings.”

The College of Forestry’s world-class students and faculty conduct ground-breaking research within the subjects of forestry, natural resources, tourism and wood science and engineering. Our research happens in labs and outdoors– on public and private lands across the state and in the College’s own 15,000 acres of College Research Forests as well as around the nation and the world.

Contributing to Oregon State University’s second-best year ever in competitive grants and contracts for research, the College of Forestry received $11.04 million in new grants and awards. As Oregon’s largest comprehensive public research university, OSU earned a total of $382 million in the fiscal year ending June 30.

Industry and agency partnerships thrived via the college’s 10 research cooperatives, with more than 100 private industry and government agency members providing an additional $2.18 million to support collaborative research.

Here are some examples of newly funded research out of a portfolio of 40 new projects.

The Role of Managed Forests in Promoting Pollinator Biodiversity, Health, and Pollination Services to Wild Plants and Agricultural Crops

Jim Rivers
Awarded by: USDA National Institute of Food and Agriculture
Amount: $1,000,000

This project will provide new information on how managed forests support healthy pollinators including bees, flies, butterflies, beetles and hummingbirds. Other objectives of the project include determining how pollinator health is influenced by forest management intensity, evaluating whether management changes to pollinator communities alters pollination of wild plants and testing whether forests serve as source habitats for pollinator populations within agricultural landscapes.

CRISPR/Cas9 Mutagenesis for Genetic Containment of Forest Trees

Steve Strauss
Awarded by: USDA National Institute of Food and Agriculture
Amount: $500,000

The goal of this project is to develop and test systems to edit floral genes of poplar and eucalyptus trees.  The edited, non-functional genes should prevent the release of pollen or seeds of these species because their genetically engineered forms are considered undesirable. These trees are often propagated from cuttings, making fertile flowers unnecessary for commercial use. These tools are expected to simplify regulatory decisions, promote public acceptance, and avoid unintended effects from exotic or genetically engineered trees in wild or feral environments.

Automated Landslide “Hot Spot” Identification Tool for Optimized Climate Change and Seismic Resiliency

Ben Leshchinsky
Awarded by: Oregon Dept of Transportation
Amount: $425,090

Landslides are increasingly frequent hazards that affect the operation, maintenance, and construction of Oregon highways, resulting in negative economic, environmental and social impacts for Oregon communities. This project will develop approaches towards creating enhanced means of assessing landslide risk considering topography, rainfall, and seismicity, primarily through the creation of mapping tools. Through these endeavors, planners will be able to maintain the safest and most efficient transportation system possible.

Inventoried landslides used for future projections of landslide hazard.

Monitoring Recreation Use in the Golden Gate National Recreation Area

Troy Hall
Awarded by: USDI National Park Service
Amount: $344,078

This project is developing protocols to monitor recreation use across 21 units of Golden Gate National Recreation Area, the most heavily used National Park in the US.

Multiscale Investigation of Perennial Flow and Thermal Influence of Headwater Streams into Fish Bearing Systems

Catalina Segura
Awarded by: California Department of Forestry and Fire Protection
Amount: $221,271

The impacts of timber harvesting and other land uses on water quality have been an environmental concern for many years. This project will assess the effectiveness of the rules currently applied in California. These rules are aimed at identifying headwater streams that require special protection given their likelihood to influence stream temperature in downstream watercourses.  This project will assess the vulnerability to temperature increases after timber harvesting of fish-bearing streams draining different geologic units.

SusChEM: Naturally Produced Fungal Compounds for Sustainable (Opto)Electronics

Seri Robinson – Co-Principal Investigator
Awarded by: National Science Foundation
Amount: $190,580

The project will explore fungi-derived pigments as a sustainable optoelectronic material for organic photovoltaics.  Wood stained fungi native to the Pacific Northwest will be explored for potential incorporation into solar cells.  Fungi-derived pigments are abundant and represent a largely unexplored resource for organic electronics and renewable electricity generation.  The project is in conjunction with principal investigator Oksana Ostroverkhova in the College of Science.

Lidar- and Phodar- based modeling of stand structure attributes, biomass, and fuels

Temesgen Hailemariam
Awarded by: USDA Forest Service
Amount: $ 164,000

This project will support the growing need for land managers to fully utilize Lidar products to obtain timely and accurate information. The project integrates traditional measures of fuels with remotely-sensed point cloud data to provide estimates of pre- and post-fire fuel mass, volume, or density in physical measurement units and in 3D within the same domain as physics-based fire models, and to scale up observations from fine-scale inputs to physics-based models to coarse scale fuels characterization required by smoke models. Hierarchical sampling across a range of spatial scales will also provide an important sensitivity analysis at varying scales.

Multi-scale analysis and planning to support Forest Service fire management policy

Meg Krawchuk
Awarded by: USDA Forest Service
Amount: $146,511

The purpose of this research is to investigate management policies to address wildfire impacts to human and ecological values. Current suppression policies are not financially sustainable and not desirable from an ecological standpoint.

Towards Resilient Mass Timber Systems: Understanding Durability of Cross-Laminated Timber Connections

Arijit Sinha
Awarded by: USDA National Institute of Food and Agriculture
Amount: $489,793.00

This project will test moisture intrusion and biological decay in cross-laminated timber connection systems to help architects, contractors and product supplies understand how connections in wood buildings will fair over time.

Bogdan Strimbu heads the Management, Algorithms and Remote Sensing Lab (MARS) at Oregon State. Most of his research involves sitting at a computer and pouring over data, but recently, he’s been able to fill a niche in his field with his beloved ‘birds,’ a nickname for his collection of drones.

“People love drones because they are fascinated by flying,” Strimbu says. “God didn’t make us with wings, but now we can fly as we want with a first-person view. We can see what the cameras see right away, like a bird. It’s a miracle.”

Right now, Strimbu has a few drone-based projects, but word about the ‘birds’ has leaked around campus, and now his lab is assisting other researchers who need to see things from another perspective. They’ve worked with the Department of Ecosystems and Society, the College of Engineering, and the University Research Forests.

“It’s refreshing when we have a drone flight,” says masters student Scott Heffernan. “I mostly work in front of my computers, so it’s nice to get outside.”

Heffernan’s own project uses radar data from the Sentinel-1 mission in Europe to model ambient canopy moisture on a stand level. The projects will eventually help managers make better decisions about how to manage for fire threats.

Ph.D. student Chu Qi’s thesis is extremely theoretical, as it is focused on applying computer vision and deep learning techniques in forest inventory and operations. Qi holds a master’s degree in mechanical engineering from Oregon State University, but was lured to the College of Forestry by Strimbu and the promise of working with drones. He uses his mechanical experience to repair the flying machines after their inevitable accidents.

Using his skills in forestry appealed to him because of the pollution problem his home city in China faces. He believes he can reduce the cost of labor when it comes to measuring ‘difficult’ forest attributes, such as taper.

“If I’m successful at developing my algorithm, you will be able to fly a drone over a stand, and the computation of stem volume and diameter will only take a few minutes,” Qi says. “It will be much faster than LiDAR.”

Qi says the accessibility of drones is what appeals to him.

“A few years ago, this wasn’t popular,” he says. “Air companies could see things from the sky, but now, as a normal person, I can gather information from the sky easily and cheaply.”

Strimbu agrees.

“It’s a very good time to fly for research,” he says. “It’s also very easy because of new, relaxed regulations in 2016. The biggest challenge our lab faces is lack of resources. I don’t even tell my students how many requests I get to do other work for faculty because it’s too overwhelming.”

Strimbu’s lab will continue to do their best to keep up with demand and to feed the passion they have for flight.

“We want to help give everyone a different perspective,” Strimbu says. “Getting higher helps you look at things in a new way.”

Savannah Stanton is just a junior, but she already has plans to graduate from Oregon State debt free and work to change the world.

“I’ve always wanted to do something for my community and for the world,” she says. “Through renewable materials, I have the opportunity to do that.”

The Newburg High School valedictorian chose to attend Oregon State after she was awarded an academic achievement scholarship, but she still attended classes simultaneously at Portland Community College to get her baccalaureate core classes out of the way and discover her passion. She found it in a class taught by Seri Robinson called “Are You Wearing Mold?”

“The class drew me into the world of renewable materials,” Stanton says. “In the class, we dove into the world of fungi and what could be done with it. It was fun to do a hands-on class like that. It really appealed to me.”

Stanton believes an interdisciplinary course of study will be the key to her future success. He focus within renewable materials is science and engineering. She’s taken business classes, math classes and she will also earn a minor in Spanish.

“Every time a new term starts, I get new ideas,” she says. “My business classes inspired me to think about owning my own business someday instead of working for someone else.”

But Stanton isn’t exactly sure what she wants to do yet. Instead, she’s excited about a world of possibilities at home in Oregon and around the world.

During the summer of 2016, Stanton interned at a wood mill in Chile.

“That was my first time working in a mill setting,” she says. “It helped me understand the traditional part of our industry as well as an idea of the current needs are and expanded who I know within the small world of renewable materials.”

Stanton says her entire experience in Chile was funded through scholarships from the College of Forestry.

Back at home, Stanton is also involved in the student chapter of the Society of American Foresters at Oregon State. SAF is a professional organization dedicated to education and scientific pursuit in the field of natural resources.

“I got involved in SAF because I think it’s important to know what other parts of the industry are up to and what their concern are for the future,” Stanton says. “If you’re able to understand what other components need to make the whole machine work, you won’t get bogged down as much.”

She says that as a new professional, she expects to depend on the timber industry for the renewable materials needed to produce wood products.

“Renewable materials has a lot to do with timber production at some point,” she says. “Right now renewable materials only make up about five percent of the market, but I think it’s important to keep that in mind as I work toward establishing my career.”

Wood science graduate student Kendall Conroy is focused on sustainability. She says the issue has been a hot topic in the Pacific Northwest her whole life. Conroy grew up in Hillsboro in a family of Oregon State graduates. Attending Oregon State as an undergraduate was an easy decision, she says. Picking a specific area of focus, however, was a bit more difficult.

“Oregon State has so many great options that I felt OK about coming here, even with no idea of what I wanted to do,” Conroy says. “Initially, I was kind of interested in forestry, but I didn’t actually want to work outside. When I learned about the renewable materials program, and that I could kind of marry a forestry degree and a business degree, it seemed perfect.”

Conroy was awarded a scholarship from the Dean’s Fund for Excellence and Innovation and chose to major in renewable materials and later added a second major in sustainability to further explore her life-long interest in sustainability. She participated in the SEEDS (Strengthening Education and Employment for Diverse Students) program, which matches students with a mentor and gives them opportunities to participate in hands-on research as an undergraduate.

Conroy was matched with Professor Eric Hansen and worked on a project researching gender diversity within the forestry industry.

“I learned a lot through that research project,” Conroy says. “Within the wood science program we have quite a few female students, but when you look at the industry and when you do internships, there aren’t as many. Experiencing this during an internship I experienced made the study more real and relevant to me.”

During her undergraduate experience, Conroy participated in a short-term, faculty-lead study abroad experience in central Europe. During her time in Slovenia, Conroy connected with a researcher there, and returned the summer after graduating to complete a research-focused internship.

“I got to help out with a literature review for them and a few other ongoing projects,” Conroy said.

Conroy enjoyed Slovene culture, learning a bit of the difficult language and enjoy a different culture in an international environment.

“Everyone in Slovenia was so nice, and I really enjoyed being part of a research team there,” Conroy says. “It seemed like every other week someone would visit from another country, and I was able to travel to Austria and Hungary to attend conferences. It was an amazing experience.”

Encouraged by her professors, Conroy returned to Oregon State in the fall to begin working toward her master’s degree.

Her research will determine architects’ perception of wood products in terms of general knowledge and sustainability.

“From this we will be able to better understand material choice and potentially how we can get more information to the people making choices about implementing wood as a building material,” Conroy says.

Conroy says that after completing her graduate degree, she would like to work with architects and designers as a consultant on sustainability and material choice.

“When contractors want to build a green building and they want to use wood, I want to be the person who can show them the sustainability of the timber they’re using,” Conroy says. “We don’t have very advanced ways of explaining that right now, so it’s my goal to tell the story of the sustainability of wood in the built environment.”