Jim Ketter at a Dept. Picnic, photo by Randall Milstein

Jim Ketter, who served as lab guru and instructor for many years, passed away on June 6th 2018. Jim joined our department in 2005 after a varied career as a geophysicist, high school teacher, graduate student and physics instructor at LBCC and Oregon State.  He was a warm and sensitive instructor and the go-to gadget guy who kept our labs running and our department presentable. In addition to the considerable load of teaching and keeping our labs humming, he loved doing outreach – Discovery days, supervising the SPS and generally bringing his enthusiasm for physics to everyone he met.

There will be a  celebration of life for Jim on July 14th from 2pm-5pm at Deluxe Brewing: 635 NE Water Ave. Albany, Oregon.


has more details and an obituary.

His family requests that donations in his memory go to Albany Parks and Recreation Foundation in lieu of flowers.

The Ostraverkhova group’s work on xylindein, an organic semiconductor produced naturally by fungi, has been featured in a press release.


June 5, 2018
CORVALLIS, Ore. – Researchers at Oregon State University are looking at a highly durable organic pigment, used by humans in artwork for hundreds of years, as a promising possibility as a semiconductor material.
Findings suggest it could become a sustainable, low-cost, easily fabricated alternative to silicon in electronic or optoelectronic applications where the high-performance capabilities of silicon aren’t required.
Optoelectronics is technology working with the combined use of light and electronics, such as solar cells, and the pigment being studied is xylindein.
“Xylindein is pretty, but can it also be useful? How much can we squeeze out of it?” said Oregon State University physicist Oksana Ostroverkhova. “It functions as an electronic material but not a great one, but there’s optimism we can make it better.”
Xylindien is secreted by two wood-eating fungi in the Chlorociboria genus. Any wood that’s infected by the fungi is stained a blue-green color, and artisans have prized xylindein-affected wood for centuries.
The pigment is so stable that decorative products made half a millennium ago still exhibit its distinctive hue. It holds up against prolonged exposure to heat, ultraviolet light and electrical stress.
“If we can learn the secret for why those fungi-produced pigments are so stable, we could solve a problem that exists with organic electronics,” Ostroverkhova said. “Also, many organic electronic materials are too expensive to produce, so we’re looking to do something inexpensively in an ecologically friendly way that’s good for the economy.”
With current fabrication techniques, xylindein tends to form non-uniform films with a porous, irregular, “rocky” structure.
“There’s a lot of performance variation,” she said. “You can tinker with it in the lab, but you can’t really make a technologically relevant device out of it on a large scale. But we found a way to make it more easily processed and to get a decent film quality.”
Ostroverkhova and collaborators in OSU’s colleges of Science and Forestry blended xylindein with a transparent, non-conductive polymer, poly(methyl methacrylate), abbreviated to PMMA and sometimes known as acrylic glass. They drop-cast solutions both of pristine xylindein and a xlyindein-PMMA blend onto electrodes on a glass substrate for testing.
They found the non-conducting polymer greatly improved the film structure without a detrimental effect on xylindein’s electrical properties. And the blended films actually showed better photosensitivity.
“Exactly why that happened, and its potential value in solar cells, is something we’ll be investigating in future research,” Ostroverkhova said. “We’ll also look into replacing the polymer with a natural product – something sustainable made from cellulose. We could grow the pigment from the cellulose and be able to make a device that’s all ready to go.
“Xylindein will never beat silicon, but for many applications, it doesn’t need to beat silicon,” she said. “It could work well for depositing onto large, flexible substrates, like for making wearable electronics.”
This research, whose findings were recently published in MRS Advances, represents the first use of a fungus-produced material in a thin-film electrical device.
“And there are a lot more of the materials,” Ostroverkhova said. “This is just first one we’ve explored. It could be the beginning of a whole new class of organic electronic materials.”
The National Science Foundation supported this research.
About the OSU College of Science:  As one of the largest academic units at OSU, the College of Science has seven departments and 12 pre-professional programs. It provides the basic science courses essential to the education of every OSU student, builds future leaders in science, and its faculty are international leaders in scientific research.


The PhIS group (Physicists for inclusion in Science) has been busy this year! The group fosters inclusion by providing an inclusive community, professional development opportunities, and mentorship for aspiring physicists. This year, their activities have included coffee breaks, mixers (including an amazing dinner and silent auction for the department), book clubs, and many outreach activities.  Check out all the fun at http://blogs.oregonstate.edu/phis/2018/05/07/physicists-inclusion-science-phis/ .  The 2018/19 elections have happened and the new PhIS leadership is: MacKenzie Lenz (President), Kelby Hahn (Vice President), Mike Vignal (Treasurer), Mattia Carbonara (Secretary).  They invite everyone to join!

Rebecca Grollman, Graham Founds, Rick Wallace and  Oksana Ostroverkhova’s paper “Simultaneous fluorescence and surface charge measurements on organic semiconductor-coated silica microspheres” has been featured by Advances in Engineering  as a key scientific article contributing to excellence in science and engineering research.  See


for a short summary of the paper and a short video highlighting the result.