Missouri State University

Dr. Adam Wanekaya

  • Associate professor of chemistry
  • Springfield, Missouri
  • BS in Chemistry, University of Nairobi
  • MS in Chemistry, University of Nairobi
  • Ph.D., State University of New York

These days, "nanomaterials" — extremely tiny materials — are found in many consumer goods.

Silver, known for antibacterial and anti-odor properties, may be in everything from athletic wear to cutting boards.

Silver, known for antibacterial and anti-odor properties, may be in everything from athletic wear to cutting boards. Zinc oxide, which prevents sun damage, has been used in sunscreen and woven into fabric for clothing. Carpet may be treated with nanoscale materials that prevents it from absorbing spills. Carbon-based nanomaterials are found in cell phones and televisions.

One thing is sure: The trend of nanotechnology means we are all more likely to buy goods with these tiny particles, and, later, dispose of these products.

What’s less certain is the affect of these nanomaterials on the environment as these goods decompose in landfills.

Dr. Adam Wanekaya, associate professor of chemistry, has researched nanomaterials since his days as a doctoral student in the early 2000s.

For the last three years, he has been leading a project with undergraduate and graduate students at Missouri State who are studying how nanomaterials age in an accelerated weathering chamber. The research shows how these particles will react in conditions similar to those they would experience outdoors.

"What is the fate of those particles after three, 10, 20 years? We want to make sure they don’t contribute to diseases such as leukemia, or cause harm to plants, animals or the environment," Wanekaya said. "Some of us recall how asbestos was previously thought to be a wonder material, only to later realize it was the cause of many deadly diseases."

Creating conditions that mimic the outdoors

At least once a week, senior Molly Duszynski heads into a chemistry lab at Temple Hall.

First, she attaches carbon nanotubes to glass slides.

Next, she takes the slides to an accelerated weathering tester, where they fit into holders designed for them.

Now, the chamber is closed. It’s time for Duszynski to make decisions about what kind of conditions the slides will face. The chamber has UVA-340 bulbs, which provide the best possible simulation of sunlight. It is also attached to a tank that holds water free of minerals or impurities. She, Wanekaya or others on the project may adjust lighting, humidity, temperature and more to simulate sunlight, rain and dew. The chamber can create conditions for night, evening, afternoon or morning, or cycle through those.

In a few days or weeks, the machine can reproduce the decomposition that would occur in months or years outdoors.

Wanekaya’s team has chosen to mostly focus on conditions that are slightly hotter than normal, in order to see what the carbon nanotubes would do if they were in a landfill in a part of the country with high-intensity sunlight.

They chose carbon to study first.

"This is a good basic material because we can predict a bit about carbon’s behavior," Wanekaya said. "We are starting with something more simple before we more on to something a bit more complex."

Preliminary results, collaborative papers

Wanekaya says the research is yielding some preliminary results.

The team can see that the shapes of the carbon nanotubes change after treatment in the chamber. Before treatment, the nanotubes are more or less linear. After, they are coiled. Using various technologies, the team has shown there are other substantial differences between groups of control nanotubes, which are not subjected to tests, and nanotubes that have been aged.

"Now, we need to find out whether those changes are good, bad or neutral. That’s our next step," Wanekaya said.

The team shared a tested group and a control group with colleagues in the Missouri State biology department. Those researchers exposed yeast, bacteria and other cells to both the control group and the aged group of nanotubes. They wanted to see if either group of nanotubes was potentially toxic to those materials.

One team found that treating yeast with either aged or control carbon nanotubes was significantly toxic to the yeast cells. Results of that study have been submitted for publication to the Journal of Nanoscience and Technology.

No significant differences were observed in bacteria and plants exposed to both the aged and control carbon nanotubes.

Wanekaya plans to keep working with these tiny particles.

"Nanomaterials are very exciting. They have novel properties that can be used for so many things."