Bethany Matthews has been awarded the Ben and Elaine Whiteley Endowment for Materials Research Fellowship.  This endowment, established in 2007, provides support for materials research in the College of Science.

Ms. Matthews is a fourth-year PhD student working with Prof. Janet Tate. Her research involves the design, synthesis, and characterization of thin film semiconductors for the improvement of renewable energy applications such as solar cells, thermoelectrics (materials which can convert heat to usable energy), or piezoelectrics (materials which can convert a mechanical stress or push to a usable energy). These semiconductors are stabilized in higher energy states than they would normally be found in through alloying and appropriate temperature control to improve their properties and make them more suitable for devices. She is particularly interested in studying the microstructure (e.g. size, composition, structure, and orientation of crystals on a very small scale) of these materials by electron microscopy and learning how changes to that microstructure explain changes to properties on a much larger scale. This fellowship will allow her to study these materials and similar systems in greater detail at the microscopy facility at the National Renewable Energy Lab in Golden, Colorado and to explain anomalous property behaviors which, if they can be controlled, could greatly increase device efficiency.

Fourth year graduate student Nicole Quist has been chosen as a member of the United States Delegation for the sixth International Conference on Women in Physics. As a member of the delegation, she is involved in writing the conference proceedings paper for the United States and creating the national poster which focus on the statu

Nicole Quist

s of women in physics in the United States and the problems that women in physics experience. The delegation will also be completing a project that will provide tools to aid women in physics, and Nicole will contribute to this as well. Although she will not be part of the subset of the group that will travel to the conference itself, her contributions will. This is an exciting opportunity for Nicole to work with women around the country to focus on encouraging diversity in physics.

Bethany Matthews, a 4th-year graduate student in Prof. Janet Tate’s lab, has won a U.S. Department of Energy (DOE) Office of Science Graduate Student Research Award.  The award is for the proposed research project, “Microscopy Analysis of Metastable Heterostructural Alloys with Anomalous Piezoelectric Response”, to be conducted at the National Renewable Energy Laboratory (NREL) in Golden, CO during the summer and fall of 2017.

The award citation states that, “The SCGSR award is in recognition of outstanding academic accomplishments and the merit of the SCGSR research proposal, and reflects Bethany Matthews’s potential to advance the Ph.D. studies and make important contributions to the mission of the DOE Office of Science.” Congratulations, Bethany!

Bethany will work with Dr. Andrew Norman of NREL and also with Prof. Brian Gorman and Dr. Andriy Zakutayev, her collaborators in the DOE-funded Energy Frontier Research Center, the Center for Next-Generation Materials by Design. The EFRC members study metastable materials of many types, and Bethany’s role has been understanding metastable alloys.  Her developing interest in transmission electron microscopy, using OSU’s Electron Microscopy Facility under the guidance of Dr. Pete Eschbach, led her to submit a proposal to DOE to study metastable alloys with microscopists at NREL and Colorado School of Mines.

Physics Major Mirek Brandt was just named a National Goldwater Scholar!
Press release: https://goldwater.scholarsapply.org/2017-scholars-press-release/

OSU’s last Goldwater Scholar winner was in 2013; most years there are only a couple successful nominations statewide (3 this year).   OSU also had a second successful nominee this year, True Gibson, a Life Sciences major. Congrats!

The Goldwater Scholarship was established by US Congress in 1986. Each year all universities nominate up to four undergraduates in science or engineering for one of ~240 Goldwater Scholarships.  As all nominees are academically near the top of their school, the primary consideration at the National level becomes “the extent to which that individual has the commitment and potential to make a significant contribution to his or her field. This is judged by letter of references, essays written by the student, and prior research experience.”

Mirek will graduate in June 2018 as a Physics and Math major and plans to pursue graduate studies. Since his freshman year (Fall 2014), Mirek Brandt has been a member of Prof. Matt Graham’s  Micro-Femto Energetics Lab.  His research contributions are very substantial and we thank  URSA-ENGAGE and SURE Science Summer Scholarship programs for funding his research.  He will defend his undergraduate senior project thesis later this year entitled “The Impact of Crystal Morphology on Opto-Electronic Properties of Amorphous and Organic Crystalline Materials”.

To top off this National honor, Mirek was recently recognized internationally by being selected to attend the Kupcinet-Getz International Science School. This program matches top-undergraduates with leading research mentors at the Weizmann Institute in Rehovot, Israel.  Mirek will join a Theoretical Astrophysics group at Weizmann this summer before returning to Oregon State Physics to take-up his Goldwater Scholarship.

On behalf of the OSU Physics Department, congratulations Mirek!

The Oregon State University Society of Physics Students (SPS) made a strong showing at the Sigma Pi Sigma Quadrennial Congress, which was held on November 2-6, 2016 in San Francisco. In cooperation with LBCC students and faculty, SPS secured funding to send 1 graduate student and 7 undergraduates from OSU and 3 LBCC students to the Congress. The students presented posters, toured scientific facilities, networked with professionals, and listened to talks by the leaders in Physics.

Michael Forkner and Tym Mangan (pictured with their posters) were among the undergraduates who presented the innovative research being done at Oregon State University. During the poster sessions, students discussed their work with other physics students from across the country and received feedback from professional physicists on their presentations. They also toured the Stanford Linear Accelerator or the Google X facilities, and listened to talks by professional scientists while looking at the sort of labs they might work in one day.

There were exciting plenary talks, including one by Dame Jocelyn Bell-Burnell who discovered quasars. She thinks that the climate in physics for women has improved considerably since her days as a young scientist. Eric Cornell, Nobel Laureate (and former Yunker lecturer) gave a characteristically upbeat and interesting talk about what the life of a real scientist is like. Between plenary talks, PhysCon conducted workshops that allowed SPS members from across the nation (and beyond!) to network and discuss important topics faced by chapters and individuals during their physics journeys. Grad student Kelby Hahn was a panelist who discussed life as a graduate student. The students were delighted to made connections that will last well beyond their short stay at PhysCon.

OSU/LBCC Participants:
Kelby Hahn, Michael Forkner, Evan Peters, Tym Mangan, Elliot Capek, Hazel Betz, Gabe Nowak, Nikita Rosanov; Osvaldo Galvez, Delphine LeBrunColon, Eric Slyter.

Michael Forkner presents his research at PhysCon
Tym Magnan at PhysCon 2016
Delphine LeBrunColon and Elliot Capek at PhysCon
Students at PhysCon

 

Three Oregon State undergraduates went to the APS Division of Nuclear Physics conference in Vancouver BC in mid-October 2016.

Senior Evan Peters shows how to calibrate neutrino response in the MINERvA detector.
Senior Evan Peters shows how to calibrate neutron response in the MINERvA detector.

Undergraduates Gabe Nowak, Tymothy Mangan and Evan Peters gave posters on their work.  Dept. Head Heidi Schellman gave a talk and provided transportation.  All 3 students had won travel awards from the American Physical Society to cover their hotel costs.

Evan’s poster was placed with theoretical posters presented by students also working on neutrino scattering, leading to much discussion among the neutrino community.

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Tymothy Mangan showing his work from Los Alamos last summer.

Tymothy Mangan showed results from a test stand he built at Los Alamos National Lab last summer.

Gabriel Nowak presented preliminary studies of Lorentz invariance that he did as a SULI student at Jefferson Laboratory.

After the poster session we went on a tour of the TRIUMF nuclear laboratory at the University of British Columbia.

Touring the ARIEL facility at TRIUMF. This room will be filled with equipment very soon.
Touring the ARIEL facility at TRIUMF. This room will be filled with equipment very soon.

image1The annual Fall Meeting of the Materials Research Society’s “best poster” awards are eagerly anticipated, and this year, James Haggerty garnered his second one. James presented a poster on his work on titania polymorphs at the Fall 2016 meeting in Boston, MA. The poster, entitled “The effect of amorphous precursors on the crystallinity of TiO2 thin films using pulsed laser deposition,” is a collaborative effort between Tate group researchers and scientists from the National Renewable Energy Laboratory, the Stanford Linear Accelerator Center, Lawrence Berkeley National Laboratory, MIT and the Colorado School of Mines.  The researchers are trying to understand why a particular metastable form of TiO2 called brookite is difficult to grow. James’s poster presented evidence that the presence of sodium ions, thought to be important in the growth of bulk crystals, is not necessary in thin-film growth.  Bethany Matthews and Janet Tate were co-authors on the poster.  Last year at the Fall MRS meeting, James and Bethany both won best poster awards – maybe a three-peat in 2017?!

SPS 2016 Applications Workshop

Report by Evan Peters SPS chapter President

Randy Milstein talks about NASA
Randy Milstein talks about NASA and the Oregon Space Grant

OSU’s Society of Physics Students chapter held an applications workshop on Saturday (11/19), where students got excited about summer internships, scholarships, and graduate school admissions. Beginning at 11:00 am, over twenty physics and science students passed through during the six-hour event to grab a snack and get to work.

Application frenzy
Application frenzy

Supported by unlimited coffee and a pizza lunch provided by OSU SPS, students began the morning by sifting through lists of REUs and scholarships compiled by the chapter.

Delicious food.
Delicious food.

As the afternoon came around, invited presenters arrived and shared their insights and experiences with students. Dr. Sujaya Rao, director of undergraduate research at OSU, discussed the URSA research program and ways to put together a stellar application. Dr. Randy Milstein from the Oregon Space Grant Consortium office discussed internship and scholarship programs at NASA and OSGC, and shared bios of OSU students who had been successful in the past. Finally, Dr. Janet Tate discussed career professionalism and how to get the most out of interactions with professors and professionals.

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Janet Tate talks about professionalism.

The workshop was successful in raising lower-division students’ awareness of research opportunities and getting students to think ahead about career-building opportunities—we hope to hold another one in the future!

 

Steven Ellefson graduated from Oregon State University in 2014 with a B.S. in

Physics Alumnus Steven Ellefson with with the ViewRay (the world’s first MRI-guided radiation therapy system) and the ArcCHECK-MR (a diode array used for radiation dosimetry measurements of complex therapy plans) that he worked on for his dissertation at UW Madison.
Physics Alumnus Steven Ellefson with with the ViewRay (the world’s first MRI-guided radiation therapy system) and the ArcCHECK-MR (a diode array used for radiation dosimetry measurements of complex therapy plans) that he worked on for his dissertation at UW Madison.

Radiation Health Physics and a minor in Physics. While at OSU, Steven did computational radiation physics research with Dr. Todd Palmer in the School of Nuclear Science and Engineering, completed a summer internship in medical physics at the Samaritan Regional Cancer Center, and was awarded the School’s Lower Division and Upper Division Student of the Year Awards in consecutive years.

After graduation, Steven went on to the Medical Physics graduate program at the University of Wisconsin-Madison, where he focused on the physics of radiation therapy. As a graduate student, Steven researched issues with using the ArcCHECK, a commercial silicon diode array widely used for radiation dosimetry of complex radiation therapy plans, for dosimetry on the ViewRay, the world’s first MRI-guided radiation therapy system. His research on the anomalous behavior of the ArcCHECK device under the influence of the ViewRay’s large magnetic field was presented at the annual conference for the American Association of Physicists in Medicine in 2015 and is currently under review for publication in the Journal of Applied Clinical Medical Physics.

Steven graduated from the University of Wisconsin-Madison in 2016 with his M.S. in Medical Physics and, through a competitive application process, was chosen for the Medical Physics Residency Program at the Mayo Clinic in Phoenix, Arizona, which he is currently attending.

Steven says the fundamental problem-solving skills and ability to think outside the box developed in the Physics program at OSU were essential to his success.

He points out some special courses here.

“K.C. Walsh and the general calculus-based physics sequence: Dr. Walsh made the fundamental concepts so easy to grasp and his enthusiasm is contagious. He was able to simultaneously encourage and challenge me to be a better physicist. He was also always willing to talk about interesting extracurricular physics problems and even try to work them out if a student requested (such as why a motorcyclist will turn into or away from a corner depending on the speed).

“Dr. Tevian Dray and Vector Calculus II: I feel that I did not truly understand calculus until I took Tevian’s class. Taking his class made a collection of seemingly unrelated facts about calculus learned in previous courses coalesce into a singular paradigm in my brain. I am very thankful for his dedication to helping physicists and engineers understand vector calculus and the integral (no pun intended) role it plays in describing the physical world.”

“Dr. Corinne Manogue: While Corinne is amazing at teaching, what I remember most is her encouragement of students. She truly tries to bring out the best in students and challenges them to be better than they think they can be. I will never forget her telling us all before a final that our performance on the test does not determine our value as human beings.”

“Last but not least, Dr. David Roundy’s computational physics course was a great preparation for graduate school. So many problems are approached with computers today that being able to translate theories/models into a computer program ended up being an essential skill for me.”

 

Prof. Bo Sun and student Amani Alobaidi’s work on 3-D tumor modeling technology has been highlighted in an article in Advantage-Impact.

DIGME discoids shaping the growth of tumor cells.
DIGME diskoids shaping the growth of tumor cells. (full caption in article below)

Here is the full article

DIGME shapes better cancer therapies

A new 3-D tumor modeling technology could drastically change the way cancer is treated. Diskoid In Geometrically Micropatterned Extracellular matrix (DIGME) is a tissue-patterning solution that uses a low-cost device to control the shape of tumors — as well as the directionality and rigidity of their surrounding matrix — to stop cancer cells from spreading.

Bo Sun, an assistant professor of physics in Oregon State’s College of Science, says DIGME will help doctors test their own cancer treatments and create new ones. And it could even improve the efficiency of early cancer detection.

“Right now, cancer detection is relying on techniques that were developed decades ago,” Sun says. “I think tumor modeling is going to show us the new things we should look at. There may be a different set of metrics that make the accuracy and sensitivity of early detection much better.”

Sun’s device can facilitate development of new cancer treatments by better mimicking the physiological condition of tumors. Oregon State University has filed for a patent and is looking for potential licensees and research collaborators to further develop the technique.

Understanding how cancer cells spread

In order for a cancer cell to dissociate from the main tumor and spread — also known as metastasis — it must dig a hole through the extracellular matrix (ECM). The ECM is the area that surrounds a tumor, which is made up of connective tissues like collagen. It can act as a barrier to keep tumor cells in or out, depending on its porousness.

For example, an ECM that is very porous provides a soft environment for cancer cells to easily squeeze through and enter other areas of the body. An ECM that is very rigid, on the other hand, provides a barricade that is very difficult for a cancer cell to dig into. However, a rigid ECM also promotes tumor growth; therefore the relationship between ECM and cancer is anything but simple. This relationship is one of the central problems of cancer research.

Modeling tumors

Sun’s team worked with standard cancer cell lines in the lab. To shape a tumor, a micro-fabricated stamp is used to create a mold made of collagen. Tumor cells are then suspended in a collagen solution and poured into the mold. The liquid collagen turns into a gel and links to the mold. The device can precisely control the location and rotation of the stamp, creating an exact shape.

Different tumor shapes equal different clinical outcomes for patients, Sun explains. If a tumor has very high curvature corners, these sharp corners are more likely to become cancer stem cells, which are very invasive and lead to metastasis.

Changing directions

Directionality is an equally important factor. The ECM — which is covered in polymer fibers — can be rotated with the help of DIGME technology. When the ECM is polarized — or given positive and negative charges — the orientation of those fibers can be rotated circularly, preventing additional cancer cells from disconnecting and spreading throughout the body. Controlling the shape and directionality allows DIGME to create challenging environments for cancer cells, testing their adaptability and understanding how they respond to treatments in complex physiological conditions.

“A tumor — no matter where it starts — is going to experience many different environments when it metastasizes into many parts of the body,” Sun says. “If a cell has no way to adapt to this new environment, it is going to stop there and won’t be able to spread.”

Sun’s research began with the goal of determining how tumors migrate and communicate with one another. Two-and-a-half years later, DIGME has the potential to help save lives.

For licensing information, please contact Jianbo Hu at jianbo.hu@oregonstate.edu or 541-737-2366.

This figure shows a breast cancer cell.

(A) DIGME consists of a diskoid – a tumor cell aggregate whose shape is tightly controlled. The example shown in A is a hexagonal diskoid of monolayer thickness. Typical diskoid thickness can range from one to five cell layers. (B) A triangle diskoid of MDA-MD-231 cells (green) in collagen matrix (labeled with fluorescent particles, blue). Top: top view. Bottom: side view. (C) A MDA-MD-231 diskoid (green) surrounded by two layers of collagen matrix with different concentrations (1.5 mg/ml, red and 3 mg/ml, blue). Top inset: the diskoid invasion into the surrounding ECM after five days. Bottom inset: confocal reflection imaging showing distinct fiber microstructures across the interface of two collagen layers. (D) A MDA-MB-231 ring diskoid with its sounding ECM circularly polarized. The configuration mimics the ductal carcinoma in vivo. Scale bars: 200 μm.