Energy Applications

Building Energizing Connections: Front Range Researchers Unite

Daniel Morton — Wed, 10 Sep 2025 16:33:38 +0000

Building Energizing Connections: Front Range Researchers Unite Daniel Morton Wed, 09/10/2025 - 10:33

Daniel Morton

This August (18-19, 2025), the Front Range came alive with scientific collaboration as the 2025 Front Range Electrochemistry Workshop (FREW) brought together over 100 researchers from across the region. Hosted at 51�Թ��'s Sustainability, Energy, and Environment Community (SEEC) building, this two-day gathering showcased the power of regional partnership in tackling some of our most pressing energy challenges. The workshop was funded by NSF’s Institute for Data Driven Dynamical Design.

Find out more about the workshop

Front Range Electrochemistry Workshop

ChBE Highlight

What is Electrochemistry and Why Does It Matter?

Electrochemistry might sound complex, but it's essentially the science of using electricity to drive chemical reactions—and it's at the heart of our clean energy future. Think of the battery in your phone or car, the fuel cells powering some buses, or emerging technologies that can capture carbon dioxide from the air and turn it into useful materials. All of these rely on electrochemical processes that researchers are working to improve and expand.

Regional Collaboration

The Front Range is developing as a hub for this critical research. This workshop exemplified that spirit, bringing together researchers from Colorado School of Mines, 51�Թ��, Colorado State University, the University of Wyoming, and several National Laboratories to share ideas, forge new partnerships, and identify opportunities for joint research.

"It was a really great meeting, with participants bringing an excited and motivated attitude that made for a really fantastic atmosphere," noted RASEI Fellow Mike Toney, who served on the organizing committee. The participants generated a great atmosphere at the workshop as researchers moved between presentations, interactive poster sessions, and innovative "collaboration pitch" sessions designed specifically to spark new partnerships, especially among graduate students. “The poster session was a great experience. I really enjoyed sharing my sodium-ion battery research and was exposed to a lot of fresh ideas across the electrochemistry space from other students and speakers” explained Loren Andrews, a Graduate Student at 51�Թ��.

Tackling Real-World Challenges Together

The workshop covered a diverse range of applications that could transform how we store and use energy:

Advanced Battery Technologies: Improving today's lithium-ion batteries and developing next-generation alternatives, including solid-state batteries that could be safer and more efficient
Grid-Scale Energy Storage: Exploring redox flow batteries that could store renewable energy for entire communities
Clean Transportation: Advancing fuel cell technology for cars, trucks, and other applications
Sustainable Chemical Manufacturing: Developing electrochemical processes to catalyze chemical transformations
AI-Powered Discovery: Using machine learning to accelerate the development of new materials and processes

Using Interactive Approaches to Develop Connections

What made this workshop particularly engaging was the opportunity to connect across different institutes along the Front Range region. The interactive format encouraged researchers to step out of their individual labs and think collectively about connected strengths and opportunities. Rather than just have lecture style presentations, the organizers developed a mixed schedule. The poster sessions weren't just about presenting results, they were also networking opportunities. The pitch sessions weren't just about sharing ideas, they were also about identifying concrete ways to work together.

To incentivize participation and develop some friendly competition in th poster and collaborative pitch sessions the organizers were able to offer a prize structure. For the poster session Abby Cardoza (Colorado School of Mines) won first place and Loren Andrews & Peter Romero (51�Թ��) won second place. For the Pitches a team with Cindy Wong (51�Թ��), Colby Evans (NIST), Emily Hansen (Colorado School of Mines), and Olajide Aijbade (University of Wyoming) took first place, and second place went to a team including Rebecca Beswick (51�Թ��), Peter Romero (51�Թ��), Bryce Rives (51�Թ��) Chris Sedmak (Colorado School of Mines), Matt Hammel (Colorado School of Mines). Congratulations to everyone!

The success of this workshop provides an opportunity for the regional electrochemistry community. Future gatherings will help to strengthen these collaborative connections and accelerate research

In a time where large scientific challenges are increasingly complex, events like this demonstrate how regional collaboration can be a powerful catalyst for innovation—bringing together diverse expertise, building new partnerships, and fostering new ideas.

August 2025

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Liquid Crystals that Keep Time: Scientists Create Matter that Dances to Its Own Beat

Daniel Morton — Fri, 05 Sep 2025 19:29:45 +0000

Liquid Crystals that Keep Time: Scientists Create Matter that Dances to Its Own Beat Daniel Morton Fri, 09/05/2025 - 13:29

Adapted from an article run in 51�Թ�� Today by Daniel Strain

A team led by RASEI Fellow Ivan Smalyukh has discovered a new type of liquid crystal that exists in perpetual, rhythmic motion, creating, for the first time, time crystals visible to the naked eye.

Reporting their findings in Nature Materials, the team demonstrates how liquid crystals, the same materials found in your phone display, can form a phase of matter that spontaneously breaks both space and time symmetries. Unlike previous time crystals that existed only in quantum systems invisible to the naked eye, these can be observed directly under a microscope.

Find out more

Read the Article

51�Թ�� Today Highlight

Phys.Org Highlight

Bioengineer.Org Highlight

SSBCrack News Highlight

Gizmodo Highlight

Nature News Highlight

Science Alert

Popular Mechanics

The Debrief

The researchers designed special glass cells filled with liquid crystals and coated with light-sensitive dye molecules. When illuminated with blue light, something remarkable happens: like dancers following a lead, the liquid crystal molecules respond to cues from the dye molecules, creating an elaborate molecular waltz that repeats its steps over and over.

Here's how the molecular choreography works: The azobenzene dye molecules at the surface respond to light by rotating, which then guides neighboring liquid crystal molecules to reorient. This creates a feedback loop where the changing liquid crystal orientation affects how light polarizes as it passes through, which then influences more dye molecules at the bottom surface. The result is a self-sustaining temporal rhythm.

The researchers discovered that these time crystals are built from special molecular arrangements called ‘topological solitons’, think of it like stable whirlpools in a stream that maintain their shape while the water flows around them. These soliton "particles" interact with each other through the liquid crystal's elasticity, forming arrays that oscillate in time with remarkable precision.

What makes these time crystals remarkable is their resilience, similar to a heartbeat that continues despite disturbances, these patterns persist even when perturbed. The team demonstrated that the crystals maintain their rhythm when subjected to random light fluctuations and recover their ordered state after disruptions, meeting stringent criteria that distinguish true time crystals from simple periodic behavior.

The temporal periods can be tuned from milliseconds to tens of seconds by adjusting temperature and light intensity, while the spatial patterns can extend over areas larger than a square millimeter—making them easily visible and potentially practical for applications.