Materials Research Institute | Our integrated research laboratories turn concepts into prototypes Skip to main content
Transparency discovered in crystals with ultrahigh piezoelectricity

Transparency discovered in crystals with ultrahigh piezoelectricity

A Wearable Gas Sensor for Health and Environmental Monitoring

A Wearable Gas Sensor for Health and Environmental Monitoring

Lithium whisker growth and stress generation in an in situ atomic force microscope–environmental transmission electron microscope set-up

Lithium whisker growth and stress generation in an in situ atomic force microscope–environmental transmission electron microscope set-up

A Fast and Inexpensive Device to Capture and Identify Viruses

A Fast and Inexpensive Device to Capture and Identify Viruses

Researchers optimize additive manufacturing on a molecular level

Researchers optimize additive manufacturing on a molecular level

Research News

A Fast and Inexpensive Device to Capture and Identify Viruses
Dec 23 2019

A device to quickly capture and identify various strains of virus has been developed, according to researchers at Penn State and New York University.

Researchers optimize additive manufacturing on a molecular level
Dec 19 2019

A paper published in the Physical Chemistry Chemical Physics Journal details how researchers examined additive manufacturing methods and materials using atomistic-scale simulations to optimize their performance for ultimately stronger and more useful 3D-printed components. 

“We went down to the most fundamental level, looking at the physical chemistry and the strengths of these molecular interactions,” van Duin said.

New, slippery toilet coating provides cleaner flushing, saves water
Nov 19 2019

Every day, more than 141 billion liters of water are used solely to flush toilets. With millions of global citizens experiencing water scarcity, what if that amount could be reduced by 50%? 

The possibility may exist through research conducted at Penn State, released today (Nov. 18) in Nature Sustainability. 

360 Virtual Tour of Our Labs

From anywhere, from any device, visit some of our labs virtually. Walk through the Nanofab Lab, the MCL X-ray Diffraction Lab, and the NanoSEM Lab.

History of Materials at Penn State

Millennium Café

Jan 21 2020
“SMaL, but Functional! From “hairy” nanocellulose to Protein Microgels for Applications in Healthcare and the Environment”

Can we chemically break down cellulose fibers into functional nanomaterials which could provide new strategies for treating water, for filtering blood? Can we convert proteins into particle gels for accelerated wound healing, disease modeling, and tissue engineering? These are just a few questions motivating work in the Soft Materials Laboratory (SMaL).

Presenter: Amir Sheikhi | Chemical Engineering Visit presenter's website

“Wearable Sensors”

Current gas sensors are mostly rigid, bulky, and require significant energy to operate. In this talk, I will introduce the use of laser-induced porous carbon materials to construct wearable gas sensors to detect toxic gas molecules such as nitrogen dioxide. These wearable gas sensors are flexible, stretchable, and highly sensitive to various target gas species. 

Presenter: Ning Yi | Cheng Group Visit presenter's website

Focus on Materials Magazine

Quantum at Penn State - An overview of quantum information science, quantum materials, and quantum sensing.

To receive a FREE printed issue, subscribe to "Printed Materials" and add/update your mailing address.

Sign Up for Print Focus Magazine

View the ONLINE ISSUE HERE

The Materials Research Institute

A Culture of Interdisciplinary Research

Penn State’s investment in its interdisciplinary research institutes, including the Materials Research Institute (MRI), has created a culture of strong collaborations across disciplines. At Penn State, many researchers have the support of both their academic departments and the university-wide institutes, such as MRI. By encouraging crosscutting research, MRI and its sister institutes open up traditional silos of knowledge to the stimulus of other viewpoints and new ideas. This mingling of disciplines, often called “convergence,” brings together the physical and life sciences with engineering and computation to solve the most complex problems facing society today and in the future.

Request a Tour of the MSC

Four Lab Solution: Theory, Synthesis, Fabrication, Characterization

NSF MIP Materials Innovation Platform
2D Crystal Consortium (2DCC)

The 2DCC-MIP is focused on advancing the synthesis of 2D materials within the context of a national user facility.

The Materials Characterization Lab
Materials Characterization Lab

The Materials Characterization Lab (MCL) is a fully-staffed, open access, analytical research facility charged with enabling research and educating the next generation of highly qualified researchers.

The Materials Computation Center
Materials Computation Center

Our primary goal is to support internal and external users working in computer-based simulations of materials across the various length and time scales.

The Nanofabrication Lab
Nanofabrication Lab

Our staff scientists and engineers will enable users to transition fundamental research in nanomaterials to innovation-driven multicomponent integrated devices and systems.

New Capabilities & Emerging Materials Research

High-res Image from the TEM
In Situ Characterization

Flurry of innovations in new components that can be placed inside the TEM

Materials-Related Institutes, Facilities, & Centers

2DLM

ICAT

ATOMIC

CIMP-3D

Energy Institute

HESE

CNS MRSEC

PSIEE

Institute for Computational and Data Sciences

CDP

Industry and University Collaboration

Every organization has different priorities and resources. Directors of the MRI facilities recognize this and help your company leverage our labs in various ways.
Find out more...