Highlights

MRSEC graduate student Adriana Santiago-Ruiz explaining the details of a hands-on experiment done during an "Exploring Evolving Nanotechnologies" workshop at Experimenta con PREM.

Mark Licurse & Ashley Wallace, University of Pennsylvania

Experimenta con PREM is a two-week hands-on research program for high school students run annually at the University of Puerto Rico (UPR) Humacao & Cayey campuses. It remains a core program for the UPR-Penn PREM program with a history of attracting talented and motivated high school students to materials research; since its inception in 2005, 100% of students have graduated from high school and 78% pursue STEM after.

A graphic showing the sunlight reflecting on a 'wet' surface and transmitting on a 'dry' surface above and image of a white beetle.

May 22, 2024

University of Pennsylvania

Beetle Scales Inspire a Passive Daytime Radiative Cooling Coating

Kathleen Stebe and Daeyeon Lee, University of Pennsylvania

Passive daytime radiative cooling (PDRC) coatings provide an eco-friendly and cost-effective alternative to cool surfaces and structures. Ideally, these coatings would have excellent cooling performance in thin, mechanically robust layers that could switch from rejecting heat to accepting heat during periods of low sunlight and would be produced by low-cost and scalable methods.

Simulations showing how the height (t), length (lx) and spacing (sx) alter the stress (VM) at a crack tip and thereby prevent crack propagation and increase toughness

May 22, 2024

University of Pennsylvania

Architecting Crack Tips to Enhance Fracture Toughness

Kevin Turner (University of Pennsylvania), Michal Budzic (Aarhus, Denmark)

One of the primary ways that materials fail in operation is by the formation and propagation of cracks during loading, often leading to sudden, catastrophic events. The ability of a material to withstand fracture is described as its toughness. Over the years, researchers have developed a variety of way to enhance material toughness, thereby improving the ability of materials to withstand applied loads, but often at the cost of reducing overall strength.

Polarized Optical Microscopy (POM) images of three nematic liquid crystal droplets (16.6, 19.9, and 26.7 μm in radius) reveal a configuration transition at a critical magnetic field. Before the transition, droplets exhibit a deformed radial state with a point defect. After the transition, droplets adopt an axial-with-defect state, featuring a ring defect. The transition is highlighted in a magnified red circle region. Simplified schematics illustrate the defect structures before and after the transition. The magnetic field strength for each frame and the orientation of the polarizer and analyzer are indicated in the images. The text in the bottom of each image indicates the field strength in Tesla.

May 21, 2024

University of Pennsylvania

New Configuration Transitions of Nematic Liquid Crystals in Drops Induced by Magnetic Fields

Arjun Yodh, James Kikkawa, University of Pennsylvania, Peter Collings, Swarthmore College

IRG-3 researchers Yodh, Kikkawa and Collings made a significant discovery about the behavior of liquid crystals (LCs) in droplets exposed to a magnetic field. LCs are unique materials that flow like liquids but also have some order (orientational order) like crystals. In this study, the researchers focused on a specific type of LC phase called a nematic. Field-induced “switching” of nematic liquid crystals (NLCs) in planar geometries is the basis of LC displays. Here, NLCs were put in spherical drops with special molecules (surfactants) on the drop surface that align the molecules, or NLC director, perpendicular to the droplet surface and force a topological hedgehog defect to form at the drop center. Field-induced switching in this case differs fundamentally from the planar cells due to confinement geometry and the topological defect.

(left) Polarized optical microscopy images showing that the ligands can align nanocrystal assembly, (middle) illustration of the proposed ligand arrangement, (right) Dendritic Promesogenic Ligands used in the study

May 21, 2024

University of Pennsylvania

Controlling Nanoparticle Assemblies with Dendritic Ligands

Christopher Murray and Chinedum Osuji, University of Pennsylvania

Liquid crystals are soft materials which see frequent use in optical displays and other smart devices. This is because they can change their optical properties (such as light transmission and polarization) when an electric field is applied. This allows them to selectively block or transmit light, creating the pixels that form images on the screen. Similarly, nanoparticles are materials that can have different optical properties that depend on their size. In this work, Penn researchers have developed new liquid crystal-nanoparticle hybrid systems. They have integrated specially synthesized molecules known as “dendritic promesogenic ligands” that can attach to the nanoparticles.

Shear bands formation in different disordered solids are well-captured by our mesoscopic StEP model. From left to right: simulated atomic glasses (left), experimental granular packing (middle), and a simulated polymer glass (right). The particles are colored according to their local strain with darker red indicating higher strain, and the applied strain localizes in all three cases. The bottom row has the stress/strain response of the three systems measured in simulations or experiments compared to the StEP model for the same three systems, showing very good agreement.

May 21, 2024

University of Pennsylvania

Understanding Deformation in Disordered Materials

Robert Riggleman, Douglas Durian and Andrea Liu, University of Pennsylvania

Disordered particulate solids are ubiquitous in items ranging from plastic to concrete. Despite their prevalence, applications can be limited because they are often brittle. In contrast, ductile materials can be deformed smoothly and significantly without fracturing. Strategies for tuning ductility of disordered solids are empirical and system-specific. Liu, Riggleman and Durian used computer simulations of atomic and polymeric glasses and laboratory experiments on granular packings to develop a general Structuro-Elasto-Plastic (StEP) framework for understanding large-scale deformation of disordered solids in terms of the system-specific interplay between local structure, local rearrangements and larger-scale elasticity.

(A) Spatial distribution of particles with different machine-learned softness, strongly correlated with localized particle rearrangements within the glass. (B,C) Rearrangement barriers (entropic and energetic), rescaled to be dimensionless, against the ML-informed excess entropy of thermal configurations. Approximate collapse is observed in the data at the same temperatures relative to the onset of glassy dynamics. Agreement improves as one moves deeper into the supercooled regime.

May 21, 2024

University of Pennsylvania

Predicting the Softness of Glasses from Thermodynamics

Paulo Arratia and Robert Riggleman (University of Pennsylvania)

The properties of glasses – disordered, amorphous materials – can be hard to predict because of this lack of long-range order and the associate properties of crystal symmetry. Work in this IRG has developed two fundamental descriptors to describe glass properties. The first of these – softness – is a machine-learning derived descriptor that characterizes structural defects in glasses and predicts rearrangements or yield that will occur in disordered materials in response to applied loads. The second – excess entropy – is a thermodynamic quantity that is a simple function of that describes the deviation of atomic arrangements from what would be predicated from ideal gas theory.

Accessing pluripotent materials through tempering of dynamic covalent polymer networks

May 20, 2024

Big Idea: Understanding the Rules of Life

Accessing pluripotent materials through tempering of dynamic covalent polymer networks

In this highlight, researchers at the University of Chicago MRSEC report the development of a polymeric, pluripotent material that can be tempered (akin to the process in metallurgy) to access a wide range of room temperature mechanical properties, from stiff and high strength to soft and extensible, from a single feedstock. The feedstock was composed of a benzalcyanoacetate-based Michael acceptor, a tetrathiol crosslinker, and a dithiol chain extender to form dynamic thia-Michael networks.

Machine learning interpretable models of biomaterials from chemistry

May 20, 2024

Big Idea: Machine Learning / Artificial Intelligence, Understanding the Rules of Life

Machine learning interpretable models of biomaterials from chemistry

This work, carried out by the University of Chicago MRSEC, shows how to integrate neural networks in the construction of predictive phenomenological models in cell biology, even when little knowledge of the underlying microscopic mechanisms exist.

CryoEM finds complexity in structural evolution of active materials

May 16, 2024

University of California, Irvine

CryoEM finds complexity in structural evolution of active materials

UCI MRSEC researchers have performed the first in-depth time-resolved cryo-electron microscopy study on molecular active materials formed under dissipative self-assembly conditions and compared the results to the same molecular formed under thermodynamic control. They found that the dissipative self-assembly conditions can stabilize the formation on transient, thermodynamically unstable phases and that these phases can be highly ordered.