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Scalable Two-Dimensional Materials Advance Future-Gen Electronics

Four-dimensional physics in two dimensions

Study Shines New Light on How Salmonella "Die" at Low Temperatures

3-D printing improves cell adhesion and strength of PDMS polymer

New desalination method offers low-energy alternative to purify salty water

Research News

Jan 12 2018

For the first time, physicists have built a two-dimensional experimental system that allows them to study the physical properties of materials that were theorized to exist only in four-dimensional space.

Jan 12 2018

A team of researchers from Penn State placed first at the Materials Research Society (MRS) iMatSci Innovators competition at the MRS 2017 Fall meeting in Boston. Their technology, called “LESS,” reduces the amount of flush volume required to remove solids and residue from toilet bowls by 90 percent and could improve hygiene and save significant water resources in water-scarce environments.

Jan 2 2018

Providing safer drinking water to those in need may be a little easier. According to Penn State researchers, a new desalination technique is able to remove salt from water using less energy than previous methods.

NEW Seed Grant Opportunity

Convergence of Materials and Life Sciences – NIH and Imaging Focused Seed Grants 2018-2019:  Learn more about it...

Upcoming 2018 Events

January
30
2DCC-MIP Webinar

Modeling 2D Growth Outcomes

May
9-11
Graphene and Beyond 2018

Enhance synergy and build toward a strong community and future in 2D crystal science and technology.

August
13 - 24
The Penn State Microscopy School

The Penn State Microscopy School: Electron Microscopy Methods at the Convergence of Materials and Life Sciences

Every Week 10 a.m.
Tuesday
The Millennium Cafe

An opportunity to spend time "outside the box" developing new ideas and leveraging the collective expertise.

March
21
Four-Probe Resistivity and Hall Voltage Measurements

This workshop will give a Parametric Analyzer Overview with a focus on making bulk and surface resistivity measurements. 

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.

Millennium Cafe

New Opportunities for Materials Discovery

The foundations of crystal chemistry were developed in the early 1900s when scientists realized that a combination of factors including atomic/ionic radii, electronegativity difference, and preferred valence could be used with incredible success to understand and predict an enormous spectrum of crystalline solids. For 100 years, the materials community depended on this approach to guide material engineering efforts. This presentation introduces the concept of entropic stabilization, an orthogonal approach to materials design, where one uses configurational entropy to stabilize new crystals that “escape” conventional predictive power. We will demonstrate the ability to incorporate metal cations into “unusual” structural environments, and potentially realize new materials with interesting structures and physical properties.

How Stuff Moves in Turbulence: From Particles to Animals

Fluid turbulence is everywhere in the natural and engineered world: a complex tangle of vortices and eddies that span a wide range of length and time scales. However, from the point of view of objects and animals suspended in turbulence, this complexity is highly dependent on scale. Small, nearly-massless things are passive tracers, completely at the mercy of the surrounding flow; large, massive things can pass through even strong turbulence without being affected too much by it. In between, there is a continuum of spatiotemporal complexity where suspended matter is intermittently affected by turbulence. We will explore these intermediate scales and their physics, and discuss what they can teach us about both engineering and biology.

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

Colorized SEM image of graphene
2D Materials and Coatings

One atom-thick substrate of graphene with pristine interfaces between the two layers

Materials-Related Institutes, Facilities, & Centers

2DLM

ICAT

ATOMIC

CIMP-3D

Energy Institute

HESE

CNS MRSEC

PSIEE

Institute for Cyberscience

CDP

Industry and University Collaboration

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