Currently Reading

U. of Oregon’s new Knight Campus is set up to turn ideas into reality

University Buildings

U. of Oregon’s new Knight Campus is set up to turn ideas into reality

Its design encourages occupant productivity and well-being.

By John Caulfield, Senior Editor | December 13, 2020
New Knight Campus at University of Oregon at Eugene

The purpose of the Knight Campus for Accelerating Scientific Impact is to create greater interactions among researchers from a wide range of scientific fields. Images: Bruce Damonte

Earlier this month, the University of Oregon in Eugene opened the Phil and Penny Knight Campus for Accelerating Scientific Impact. The 160,000-sf complex, which consists of two facing L-shaped towers, supports a mission to shorten the timeline between discovery, development, and deployment by bringing together engineering, applied science, business innovations, and culture. Its environment priorities revolve around wellness, human performance, and community. (The Campus’s tagline is “Science Advancing Society.“)

Phil Knight, co-founder and chairman emeritus of Nike, donated $500 million for this project. “Phil was most interested in the mission” of acceleration, Todd Schliemann, FAIA, Design Partner at Ennead Architects, tells BD+C. The Campus’s current focus is bioengineering, and OU partners with Oregon State University to offer a PhD program in that discipline.

Ennead Architects was this project’s design architect, Portland, Ore.-based Bora Architecture & Interiors was its AOR and designed some of the interiors, and Hoffman Construction built the campus.

Lab space (above) and work space (below) intersect in the campus's buildings. Mass timber was applied throughout the Campus, including the labs' ceiling.

Built on land where a Domino’s Pizza, a mini-mall and parking lot once stood, the Knight Campus is situated between the University of Oregon’s main campus and parkland straddling the Willamette River. A 190-ft-long, 48-ft-wide enclosed bridge, stretching 35 ft above street traffic, connects Knight Campus to Oregon’s existing campus.

Schliemann says the university is positioning the Knight Campus—which he calls a “humanistic research machine”— as a “gateway building” to a possible future research complex.

During the design process, the university hadn’t decided what disciplines these towers would house. So before designing the Knight Campus, representatives from the design team visited several other universities, including MIT’s Media Lab, Harvard, Stanford, and University of California at San Francisco. What they all have in common, says Schliemann, are collaborative spaces where knowledge can be shared. Stanford’s engineering complex, he adds, is noteworthy for how much natural light it lets inside.


Staircases made from cross-laminated timber connect the floors.


The Knight Campus has several distinguishing characteristics:

•Its two upper floors include four research “neighborhoods” that each has a wet bench area, computational space, and offices where Principal Investigators work. Schliemann contends that this is one of the first lab buildings in the U.S. where PIs are this visible to other research teammates.

•The Campus’s double-skinned façade showcases an outer wall consisting of 650 glass panels and designed to resemble water flowing over rocks. This cascading wall is stabilized by an inner curtainwall made up of 900 glass panels. Schliemann says that this design and materials were chosen to let more natural light and panoramic exterior views into the building (which, he contends, improves working conditions), and for passive energy performance (the inner wall of the façade never gets exceedingly warm).

Exterior details of facade's folding glass panels.

The Campus's double-skinned facade lets more natural light into the buildings and keeps heat from penetrating the inner curtainwall.


The wall structure was light enough to be hung from the roof component.

•Mass timber is prevalent throughout the Knight Campus, whose construction used 20,500 sf of cross-laminated timber that includes 180 CLT panels and 4,000 lbs of wood for each of the building’s staircases. The 21-foot floor-to-floor height allows for suspended mezzanine structures of mass timber containing offices for faculty, creating a new level of connectivity to their labs and graduate students.

Mass timber “is one of the most sustainable ways to construct a building” says Schliemann. (The Knight Campus is targeting LEED Gold certification.) Using mass timber also supports Oregon’s local economy. While vibration prevents a lab space from being made entirely with mass timber, “we could use it for offices, stairs, ceilings and bridges. Plus, we didn’t have to sheetrock the ceilings, as fire codes have finally caught up with mass timber” as a fireproofing agent.

Also see: Researchers use U. of Arkansas buildings as testbed for CLT panels.


Among the Knight Campus’s amenities are a 6,000-sf Innovation Center and 1,000-sf Wellness Center. While the Innovation Center might seem small when compared to other university research facilities, Schliemann counters that its scale is deceptive. “It gets innovators out into the real world.” He adds that all Knight Campus labs are leasable and tenant-adaptable.

The Wellness Center started out as a locker room with showers. Then spaces for yoga and other exercise regimens were included. Schliemann says the campus has a program where students can take bike rides with researchers.

An elevated terrace and courtyard between the Campus's two buildings is covered with a canopy made from ETFE.


Between the Campus’s two buildings is an elevated terrace and courtyard, protected by a transparent plastic canopy, where students and faculty can relax, socialize, and connect with nature, as the terrace overlooks landscaping and the tree-covered Coburg Hills.

Related Stories

Laboratories | Oct 14, 2021

Pandemic puts science and technology facilities at center stage

Expanding demand for labs and life science space is spurring new construction and improvements in existing buildings.

University Buildings | Sep 28, 2021

Designing for health sciences education: Specialty instruction and human anatomy labs

It is a careful balance within any educational facility to provide both multidisciplinary, multiuse spaces and special-use spaces that serve particular functions.

University Buildings | Sep 7, 2021

Gateway to the West: Kansas City University Center for Medical Education Innovation

Kansas City University Center for Medical Education Innovation uses GKD Omega 1520 metal fabric.

Giants 400 | Aug 30, 2021

2021 Giants 400 Report: Ranking the largest architecture, engineering, and construction firms in the U.S.

The 2021 Giants 400 Report includes more than 130 rankings across 25 building sectors and specialty categories.

Giants 400 | Aug 26, 2021

2021 University Giants: Top architecture, engineering, and construction firms in the higher education sector

Gensler, AECOM, Turner Construction, and CannonDesign head BD+C's rankings of the nation's largest university sector architecture, engineering, and construction firms, as reported in the 2021 Giants 400 Report.

University Buildings | Aug 19, 2021

School of Medicine completes on California University of Science and Medicine’s new Colton campus

The project was designed and built to address critical public health needs in an underserved region.

Resiliency | Aug 19, 2021

White paper outlines cost-effective flood protection approaches for building owners

A new white paper from Walter P Moore offers an in-depth review of the flood protection process and proven approaches.

University Buildings | Aug 12, 2021

Central Michigan University’s Chippewa Champions Center completes

The project was designed in partnership between Populous and GMB Architecture + Engineering.

Magazine Subscription

Get our Newsletters

Each day, our editors assemble the latest breaking industry news, hottest trends, and most relevant research, delivered to your inbox.


Follow BD+C: