Breaks Away: Jenny Hampton

sabbatical (n): a break from customary work to acquire new skills or knowledge, traditionally occurring every seventh year

Breaks Away: Sabbatical Stories of Hope

Each academic year, a number of Hope faculty take sabbatical leaves away from the college, submersing themselves for extended periods of time into their favored fields of inquiry. If viewed from above and all together, those fields would look like a calico landscape, so varied and colorful is the topography of their collective research, writing, and creative pursuits. Offering both restoration and adventure, sabbaticals are a bit like information and imagination transfusions. These breaks away from normal classroom and committee work give Hope academicians a boost to reinforce and revitalize their teaching and scholarship.

Scientists have been searching for alternative energy sources for years, ones that are more environmentally plentiful and safe. While we tend to think first of wind and solar energy as those natural and prudent ways to power our world, Dr. Jennifer Hampton’s sabbatical research reminds us that other Earth-abundant materials – such as sodium or potassium – have the potential to help with energy usage and storage, too.

JennyHampton
Dr. Jenny Hampton, associate professor of physics, stands beside a monitor in her lab that displays charging and discharging waves of new materials that hopefully will one day provide energy storage.

At the Energy Materials Center (EMC2) at Cornell University last year as a visiting scientist, Hampton went back home in a way to help discover new energy materials and methodology. It was at Cornell where she completed her PhD in 2002, and at EMC2 where her doctoral advisor, Hector Abruña, still conducts research. There once again, Hampton dedicated a year’s worth of her own research – interdisciplinary in nature as it combines physics, chemistry and engineering – to answering these decades-old questions: What can work as energy and how can it be stored?

“There is a lot of interesting work in the fuzzy boundaries between science disciplines,” says Hampton. “That’s where this research is at. And I very much like that cross fertilization of different mindsets that are working on the same problems.”

Hampton is hoping to find ways to optimize cheap, bountiful materials for particular applications that could affect consumer electronics, transportation and even power grids.

This interconnectedness of sciences is part of Hampton’s forte. Her work in electrochemistry for making nanoporous alloys is rife with chemical and physical knowledge, two fields in which she focused her post-doctoral program for three years at Pennsylvania State University. Hampton has involved Hope students in the intermingling of these subject matters during her summer and school year research, sharing with them the importance that “a singular training or emphasis – in chemistry or physics – doesn’t mean you can’t contribute to a broader conversation, or bigger problem or solution. It almost always takes several scientists to achieve one goal.”

The goal of Hampton and her students is to look at a new type of material that has potential for use in energy storage (batteries). The class of materials is called metal hexacyanoferrates and these materials have open pores where ions of lithium, sodium, or potassium can go in and out when charging or discharging. Hampton is hoping to find ways to optimize these cheap, bountiful materials for particular applications that could affect consumer electronics, transportation and even power grids.

So far, Hampton and her battery of three students, who will be presenting their research this Friday at Hope’s Celebration of Undergraduate Research, have found that the thicker the hexacyanoferrate, the faster the charging process occurs.  “We didn’t expect that,” admits Hampton.  “Now we want to find out why.”

Hampton has a substantial grant pending from the NSF to help answer the “why.” (She was also the recipient of two previous National Science Foundation (NSF) grants worth almost $400,00 combined.) Once the reason for faster charging with thicker hexacyanoferrate is found, Hampton foresees the energy industry taking that knowledge and continuing on with their own research to build a better battery. Who knows? Maybe the battery that one day powers your car will have its foundations in a Hope College lab.

Dr. Jenny Hampton is an associate professor in the Department of Physics at Hope College.

 

Leave a comment

Your email address will not be published. Required fields are marked *