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ChBE faculty earn Air Force Young Investigator Award

Susan Glairon — Thu, 27 Mar 2025 21:52:51 +0000

ChBE faculty earn Air Force Young Investigator Award Susan Glairon Thu, 03/27/2025 - 15:52

Susan Glairon

Assistant Professors Kōnane Bay and Ankur Gupta from ��ֱ�� Boulder’s Department of Chemical and Biological Engineering have been honored with the 2025 Air Force Office of Scientific Research (AFOSR) Young Investigator Program Award.

Each received a $450,000, three-year grant to advance research relevant to the Air Force. The program, offered by the Air Force Research Laboratory, supports early-career scientists and engineers with “exceptional ability and promise for conducting basic research,” according to the AFOSR.

“This is among the most prestigious awards given to junior faculty, and to have both Ankur and Kōnane receive it in the same year is a remarkable testimony to their impressive achievements and very high potential for making future advances,” said Professor Ryan Hayward, chair of the department.

Kōnane Bay, self-healing, innovative materials

Bay says the next generation of polymer materials—materials with long chains of molecules like plastics, rubber and proteins—will need advanced features, such as the ability to repair themselves. While engineering synthetic polymers with these properties is challenging, biofilm-forming bacteria are promising as they use internal material factories to produce polymers on demand to survive changes in the surroundings.

“I am grateful to receive this award which will allow our lab to harness nature to create novel engineered living materials,” Bay said.

The award will support Bay and her team at the Huli Materials Lab in using biofilm-forming bacteria to develop new polymeric materials. The project combines 3D printing with bacteria’s natural movement to control the mechanical properties of biofilm-based synthetic polymers. The findings could lead to self-healing materials that can change shape, with applications in aerospace, soft robotics, and protective coatings.

Bay recently also received a prestigious CAREER Award, a $675,000, five-year grant from the National Science Foundation. The funding will advance her work in characterization of polymer thin film.

Ankur Gupta, more precise chemical sensors

Imagine being able to organize tiny particles as small as one-twentieth the thickness of a human hair.

Gupta’s research aims to do just that. He and his team in the Laboratory of Interfaces, Flow and Electrokinetics (LIFE) study how these tiny particles form patterns through chemical reactions and diffusion. The researchers aim to control this process to develop materials that detect microscopic changes in the air, paving the way for advanced chemical sensors that identify subtle chemical shifts and improve safety.

“It’s an honor for us to receive this award, especially given its prestige and selectivity,” Gupta said. “This recognition is a testament to the hard work of my current and past group members, and I am grateful for the opportunity to work with them.”

The $450,000 three-year grant will support a graduate student and cover travel expenses.

In 2024, Gupta was honored with the Johannes Lyklema Early Career Award in electrokinetics. He was also selected for the prestigious “35 Under 35” award from the American Institute of Chemical Engineers in 2023.

That same year Gupta also received a $517,000, five-year National Science Foundation CAREER Award, to study how ions move through porous materials. His research will help design improved porous materials for more efficient desalination and renewable energy storage.

Assistant Professors Kōnane Bay and Ankur Gupta from ��ֱ�� Boulder’s Department of Chemical and Biological Engineering each received a $450,000, three-year grant to advance research relevant to the Air Force.

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PhD student’s work on engineered adhesives wins national recognition

Susan Glairon — Mon, 24 Mar 2025 17:46:37 +0000

PhD student’s work on engineered adhesives wins national recognition Susan Glairon Mon, 03/24/2025 - 11:46

Susan Glairon

Paula Pranda, a chemical and biological engineering PhD student, earned the top student honor at the Adhesion Society meeting for her research on aligned Liquid Crystal Elastomer (LCE) adhesives. The society’s annual meeting was held Feb. 16-19 in New Orleans.

Pranda received the Alan Gent Distinguished Student Paper Award, recognizing the most distinguished paper among top students who had previously won the Peebles Award for outstanding graduate research in adhesion science. The Adhesion Society advances adhesion science, promotes education and honors achievements in the field.

“Winning this award is an incredible honor,” said Pranda, who works with ��ֱ�� Boulder’s Hayward Research Group and Responsive and Programmable Materials Group. “It’s validating as a young researcher and exciting because it shows that the scientific community values our work.”

LCEs are soft, stretchy materials with a unique structure formed by liquid crystal monomers, which have a long oval shape. Using specific processing methods, these monomers can be aligned in one direction. When stretched along this alignment, the polymer behaves like a classic elastomer, meaning it can stretch and return to its original shape. However, when stretched perpendicular to the alignment, it becomes much softer and stretchier as energy is dissipated into rotating the monomers.

��ֱ�� Boulder and the 3M Company research team leveraged this property to develop pressure-sensitive adhesives (PSAs). Their findings showed that the peel strength depends on monomer orientation—adhesives are harder to remove when monomers are perpendicular to the peeling direction. By using a laser to pattern different alignments, the team was able to create adhesives with regions of varying peel force.

“This award is a testament to the community's excitement about Paula’s findings on how adhesion can be tailored using LCEs, and her outstanding presentation,” said Professor Ryan Hayward, the director of the Hayward Research Group and the department chair. "Tim (White) and I are very proud of Paula—it has been a true pleasure collaborating with her on this project.”

Directional control of adhesion offers many potential applications, Pranda said. In diabetic ports, patterned LCE adhesives can ensure strong skin adhesion while allowing painless removal in a specific direction. Similarly, for screen protectors, aligning monomers perpendicular to common failure points can prevent edge peeling, while parallel alignment allows for easy removal when needed.

“This recognition means so much,” Pranda said. “I couldn’t have achieved it without the support of my amazing mentors and collaborators at ��ֱ�� Boulder and the 3M Company—especially Professor Ryan Hayward, Professor Tim White, Hyunki Kim, Aaron Hedegaard, Jason Clapper and Eric Nelson.”

Paula Pranda, a ��ֱ�� Boulder PhD student, won the top student award at the Adhesion Society's annual meeting for her research on Liquid Crystal Elastomer (LCE) adhesives. Her work has potential applications in medical devices and screen protectors among others.

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Research program sparks student’s transfer to ��ֱ�� Boulder

Susan Glairon — Thu, 13 Feb 2025 22:21:52 +0000

Research program sparks student’s transfer to ��ֱ�� Boulder Susan Glairon Thu, 02/13/2025 - 15:21

Susan Glairon

Kate Lamb stands between YSSRP participants Paloma Suárez Davila (left), who attends ��ֱ�� Mesa University and Runa Kersten-Guiler, who attends the University of New Hampshire.

After a summer in ��ֱ�� Boulder’s Young Scholars Summer Research Program (YSSRP), Kate Lamb was inspired to change her path, transferring from community college to ��ֱ�� Boulder’s Department of Chemical and Biological Engineering as a biological engineering major.

YSSRP’s nine-week program prepares undergraduate students for research careers and graduate study through hands-on experience and professional development. Open to all qualified applicants, the program strongly encourages participation from students underrepresented in engineering and those from schools with limited research opportunities.

You started classes at ��ֱ�� Boulder in January. How’s it going so far?

It’s good! I took chemistry, physics and biology at Arapahoe Community College (ACC), so I am well-prepared for upper-division coursework.

How did you learn about this program?

After reviewing my classes and interests, my career counselor at ACC thought I might like engineering and recommended the YSSRP. I feel really fortunate that I was accepted to the program.

What were your academic plans before participating in the YSSRP?

I was planning to major in math, though I wasn’t sure where I wanted to study. I really love math and biology and have an interest in medicine, but I wasn’t sure how they connected. That’s what drew me to biological engineering at ��ֱ�� Boulder—it brings everything together.

What did you enjoy about your YSSRP research project?

My project introduced me to synthetic biology, a field that combines biology and engineering, which I find fascinating. It involves designing and building new biological systems or modifying cells to give them new traits or to produce useful products.

I worked with two PhD students to optimize a biosensor—a protein that detects biological substances, and converts that detection into a measurable signal. Biosensors have the potential to be used as non-invasive medical diagnostic tools and even as therapeutic devices. Our goal was to improve T7 RNA polymerase biosensors, and after extensive troubleshooting, we finally got results that worked. That moment was incredibly gratifying and showed me how much persistence goes into research. Our results formed the basis of a paper that was accepted for publication.

How did participating in the YSSRP influence you to switch from math to engineering?

It opened a door to a way that I could combine all my different interests. Previously I thought I had to choose one specific discipline like biology or math or chemistry. After I started working in the lab, I began learning about the degrees offered at ��ֱ�� Boulder. Now I'm taking differential equations and organic chemistry—different areas of study that I didn’t know could fit together in one degree program.

Why did you decide to attend ��ֱ�� Boulder?

The graduate students who mentored me, and Dr. (Rob) Davis and Dr. (Tim) Whitehead took the time to discuss what studying at ��ֱ�� Boulder would be like and how the degree programs are structured. The opportunity to continue doing research was a big part of my decision to attend ��ֱ��.

What was your favorite part of participating in the YSSRP?

The research was exciting, but there were other elements of the program that I really enjoyed. We had lunches with professors and weekly talks on different topics such as working in industry, intellectual property and graduate school opportunities. It made me think how cool it would be to be sitting in one of those professor’s classes.

As a group we had regular outings, for example, we went hiking, whitewater rafting and bowling. I made a couple of close friends in the program who worked in labs down the hall from me, and we had a really fun time exploring Boulder together. I only have good things to say about the program and its impact on me.

What are your plans for the future?

I’d like to stay in research, and graduate school seems like a strong possibility. I have ideas that I want to explore, and I hope to contribute meaningfully to developing diagnostics and therapeutics that will improve patient care.

To learn more, visit the YSSRP website.

After participating in ��ֱ�� Boulder’s Young Scholars Summer Research Program (YSSRP), Kate Lamb discovered her passion for biological engineering, leading her to transfer from community college to ��ֱ�� Boulder.

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How the tiger really got his stripes

Susan Glairon — Thu, 06 Feb 2025 15:53:35 +0000

How the tiger really got his stripes Susan Glairon Thu, 02/06/2025 - 08:53

Assistant Professor Ankur Gupta’s research on diffusiophoresis, where smaller particles move through a fluid, dragging larger particles with them, helps explain how this process may create clear biological patterns in nature, such as those seen on fish or a tiger's stripes.

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Jerome Fox receives Presidential Early Career Award for Scientists and Engineers

Susan Glairon — Mon, 03 Feb 2025 17:58:40 +0000

Jerome Fox receives Presidential Early Career Award for Scientists and Engineers Susan Glairon Mon, 02/03/2025 - 10:58

Susan Glairon

Jerome Fox, an associate professor of chemical and biological engineering at ��ֱ�� Boulder, has received the Presidential Early Career Award for Scientists and Engineers (PECASE), the highest honor the U.S. government bestows on early-career scientists and engineers.

President Biden announced nearly 400 recipients of the PECASE on Jan. 14, celebrating their exceptional contributions to advancing science and engineering. Established by President Clinton in 1996, PECASE recognizes scientists and engineers who show exceptional potential for leadership early in their research careers.

“I am grateful for receiving such expansive support early in my career," Fox said. "This award helped my lab grow in new unexpected directions.”

Fox’s research focuses on understanding how enzymes, nature’s catalysts, work together to control chemical reaction networks. His work aims to develop energy-efficient biocatalytic systems capable of performing complex tasks, such as producing chemicals and medicines, or imbuing both living and non-living systems with novel functions (e.g., adaptation and display).

In 2018, Fox received both the National Science Foundation Faculty Early Career (CAREER) Award and the U.S. Army Research Office Young Investigator Award. His research for the latter demonstrated how enzymes collaborate to execute complex operations efficiently.

Fox has been a faculty member in the Department of Chemical and Biological Engineering since 2016. He earned undergraduate degrees in environmental engineering and natural science from Johns Hopkins University and a doctorate in chemical engineering from the University of California, Berkeley.

Jerome Fox, associate professor of chemical and biological engineering, has received the Presidential Early Career Award for Scientists and Engineers (PECASE) for his groundbreaking research on enzyme-driven chemical networks and their applications in biocatalytic systems, including chemical and pharmaceutical production.

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Laurel Hind honored with CAREER Award for advancing immune response research

Susan Glairon — Fri, 17 Jan 2025 22:42:15 +0000

Laurel Hind honored with CAREER Award for advancing immune response research Susan Glairon Fri, 01/17/2025 - 15:42

Laurel Hind is studying the signals that regulate the immune system and contribute to disease, supported by a major grant awarded to promising early-career faculty.

Hind, an assistant professor in the Department of Chemical and Biological Engineering at the University of ��ֱ�� Boulder, has received a prestigious National Science Foundation CAREER Award. This highly competitive program supports faculty with potential to become leaders in research and education.

The $646,000, five-year grant will support Hind's research on how the tissue environment directs the innate immune response. It will also fund outreach efforts to improve scientific literacy in immunology through a new program, “Immunology in our Everyday Lives."

“I am grateful for this award because it recognizes and builds on the work my students have done to understand how the tissue environment regulates innate immunity while also opening a completely new research area for my lab, which is very exciting," Hind said. "I am happy that the field recognizes the importance of understanding how physical cues regulate cell function.”

The innate immune response acts as the body's first line of defense against harmful invaders like bacteria or viruses, injuries and disease, and plays a critical role in maintaining health. However, an imbalance in the immune system can lead to inappropriate responses which are increasingly linked to diseases such as cancer, cardiovascular disease, chronic infections and fibrosis, and aging, Hind said. Understanding the signals that control this response and how they become dysregulated in disease could help develop new treatments.

The award will support Hind and her team in exploring how physical changes in tissues affect immune function and contribute to worsened disease outcomes as diseases affected by immune system problems often involve changes in the physical properties of tissues. For example, tissues become stiffer in cancer and fibrotic diseases, but lose structure during the aging process. While the chemical signals that influence the immune system in these processes are well studied, how the physical properties of tissues impact immunity is not yet fully understood.

Using novel biomaterials in an innovative “inflammation-on-a-chip” device, Hind and her team will examine how properties such as stiffness, elasticity and the dynamics of tissue stiffening affect innate immune cell function. Importantly, it will identify the genes and proteins that drive these changes, providing targets for future therapeutic development.

The award will also support the development of a curriculum to improve scientific literacy in immunology to encourage public health initiatives through community-engaged outreach. This curriculum will use games and hands-on activities to explain how antibiotics and antibodies work and demonstrate the importance of herd immunity. It will also help retain and recruit women and historically excluded students in science and engineering by involving them in research and curriculum development.

“Public health initiatives like broad participation in vaccination and reducing the overuse of antibiotics are so important for the health of our communities, yet many people don’t understand why, which can lead to resistance," Hind said. "I am excited to share our knowledge in an accessible way with students and families in our community.”

Assistant Professor Laurel Hind has received a $646,000 NSF CAREER Award to study immune system regulation and disease, while also promoting scientific literacy in immunology through a new outreach program.

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��ֱ�� Boulder PhD student takes Materials Research Society's top graduate prize

Susan Glairon — Mon, 13 Jan 2025 22:13:19 +0000

��ֱ�� Boulder PhD student takes Materials Research Society's top graduate prize Susan Glairon Mon, 01/13/2025 - 15:13

Susan Glairon

Luis Kitsu Iglesias, a fifth-year PhD candidate in Professor Mike Toney’s lab, received the prestigious gold award—the highest graduate student honor—at the 2024 Fall Meeting of the Materials Research Society (MRS) for his exceptional battery research. The renowned international conference brings together experts from around the globe to showcase and discuss the latest advancements in materials science.

Initially selected as a finalist for the MRS Graduate Student Award, Kitsu Iglesias of the Department of Chemical and Biological Engineering, received the award after presenting his sodium-ion battery research at the MRS fall meeting in Boston on Dec. 3.

“This award marks a personal milestone and highlights the significance of advancing sustainable battery technologies,” Iglesias said. “It underscores the urgency of addressing challenges like energy, equity and environmental responsibility through research.”

Iglesias’s research focuses on advancing sodium-ion batteries as a sustainable alternative to lithium-ion batteries, addressing challenges like safety, cost, limited lithium resources and ethical concerns around lithium extraction. He studies sodium storage in hard carbon anodes, a key material for these batteries, using advanced X-ray techniques to observe how the structure and behavior of hard carbon change during charging and discharging.

By utilizing abundant and environmentally friendly sodium resources, these batteries offer a competitive solution for large-scale grid energy storage.

“My work provides the foundation for designing sodium-ion batteries with higher capacity, improved efficiency and greater durability,” Iglesias said. “These advancements pave the way for more accessible renewable energy storage, enabling the widespread adoption of clean energy technologies and contributing to a more sustainable and resilient energy future.”

Iglesias received his BS in chemical engineering from the Polytechnic University of Catalonia. In his third year, he received a fellowship to study in Chalmers University of Technology in Sweden. His fourth year he received another fellowship to study at ��ֱ�� Boulder.

In May, Iglesias will begin a postdoctoral research position at ETH Zurich, where he will continue exploring energy storage technologies.

“My goal is to lead projects that bridge the gap between cutting-edge research and societal needs, ensuring that advancements in green technologies benefit all sectors of society,” he said. “Being recognized by the Materials Research Society inspires me to keep exploring innovative energy storage solutions and contributing meaningfully to the global scientific community.”

Luis Kitsu Iglesias, a chemical and biological engineering PhD candidate, earned the 2024 Materials Research Society Gold Award for his innovative research on sustainable sodium-ion batteries.

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Kōnane Bay receives CAREER award for polymer fabrication research

Susan Glairon — Thu, 12 Dec 2024 18:33:27 +0000

Kōnane Bay receives CAREER award for polymer fabrication research Susan Glairon Thu, 12/12/2024 - 11:33

Susan Glairon

Polymer thin films can extend the lifespan of everyday products, such as food packaging for preserving freshness and protective coatings for electronics. Advancing their design to be even thinner and more durable could expand their applications further.

Kōnane Bay, an assistant professor based in the University of ��ֱ��’s Department of Chemical and Biological Engineering, recently received a prestigious CAREER Award, a $675,000, five-year grant from the National Science Foundation. The funding will advance her work in polymer characterization and support the development of high school and summer program curricula that integrate materials science and engineering lessons with traditional Indigenous knowledge.

“It feels great to be recognized by the polymer community for both the scientific and outreach work that we are doing,” Bay said.

The award will support Bay and her team at the Huli Materials Lab in investigating how the mechanical properties of polymer films evolve as their thickness is reduced to less than 100 nanometers—about a thousand times thinner than a human hair or cling wrap. Many industrial applications depend on the mechanical performance and stability of these films. The difficulty, Bay said, lies in the fact that when polymer materials are processed into thinner films, their mechanical strength changes in ways that are not yet fully understood.

Assistant Professor Kōnane Bay oversees a graduate student working on an instrument in the Huli Lab.

Using a custom-built instrument, researchers in the Huli Lab will study how variables like thickness, temperature and surface interactions affect the strength of these films. The findings will provide valuable insights for designing more reliable adhesives, coatings and membranes while reducing material costs, energy use and environmental waste.

The project will fund a PhD student for five years to study the mechanics of ultrathin polymer films.

In addition to supporting research, the funding will enable the development of high school and summer program curricula that integrate materials science and engineering with traditional Indigenous knowledge. Growing up in Hawaiʻi, Bay draws from her heritage to shape this initiative, which aims to increase STEM recruitment and retention among women and historically excluded students, particularly Native Hawaiians, through curriculum development, outreach and mentoring to inspire the next generation of diverse STEM leaders.

“The curriculum will be designed to inspire high school students across ��ֱ�� and Hawaiʻi to explore and pursue advanced degrees and careers in STEM disciplines,” Bay said.

Kōnane Bay received a CAREER award to support research at the Huli Materials Lab, where she and her team will investigate how the mechanical properties of polymer films change as their thickness is reduced to less than 100 nanometers—about a thousand times thinner than a human hair or cling wrap.

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Kristi Anseth recognized with international VinFuture Prize for Women Innovators

Susan Glairon — Fri, 06 Dec 2024 22:25:46 +0000

Kristi Anseth recognized with international VinFuture Prize for Women Innovators Susan Glairon Fri, 12/06/2024 - 15:25

Susan Glairon

Kristi Anseth, a Distinguished Professor and Tisone Professor in the Department of Chemical and Biological Engineering, has been awarded the prestigious VinFuture Special Prize for Women Innovators in recognition of her pioneering research in tissue engineering. Winners were selected from nearly 1,500 scientific nominations spanning more than 80 countries and territories worldwide.

Anseth, also the associate faculty director of ��ֱ�� Boulder’s BioFrontiers Institute, said she was deeply honored to receive the recognition.

“It is one that I will cherish for years to come,” said Anseth after being presented with the award Dec. 6 at the 2024 VinFuture Prize Award Ceremony in Hanoi, Vietnam. “I thank the VinFuture Foundation for sponsoring this award to highlight the innovation of women in science and engineering.”

Anseth designs biomaterials that interact with living tissues to promote repair and regeneration, aiding in healing injuries and diseases. Her lab works with hydrogels—a degradable biomaterial—to deliver molecules at the right time and sequence to accelerate the healing process. Her team is also growing miniaturized versions of heart cells and tissues, known as organoids, to better understand disease mechanisms and explore new types of heart disease treatments, such as to repair heart muscles after heart attacks.

Anseth said she has been fortunate to work in the dynamic and evolving field of biomaterials and to be working at ��ֱ�� Boulder.

“The translation of bioengineering across biology and medicine remains a frontier with many opportunities to explore,” she said. "I believe that many of the major breakthroughs in the next decade will continue at this interface and lead to improvements in healthcare for people everywhere.

“��ֱ�� Boulder has provided an amazing environment for a nearly 30-year career. I started as a faculty member in 1996, and the community of faculty and students has been an amazing environment to support my own learning and creativity. What’s the phrase—'minds to match our mountains’? I feel fortunate to be surrounded by exceptional people.”

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Building a just future: Why graduate research must include energy justice

Susan Glairon — Mon, 25 Nov 2024 23:17:35 +0000

Building a just future: Why graduate research must include energy justice Susan Glairon Mon, 11/25/2024 - 16:17

Susan Glairon

In a comment published in “Nature Chemistry,” on Nov. 25, Casey Davis, a chemistry PhD student, along with her advisor, Mike Toney, a professor of chemical engineering and materials science, and others, argue that universities must integrate energy justice into graduate curricula and research.

��ֱ�� Boulder spoke with Toney and Davis about energy justice and the importance of preparing graduates to tackle these challenges in their careers as the world transitions from fossil fuels to renewable energy.

What is energy justice?

Davis: Energy justice means ensuring fairness in how energy is produced and used, as well as addressing past harms experienced by disadvantaged communities.

Can you explain the social aspects of energy justice?

Davis: Community solutions involve engaging with communities to understand their needs, rather than having scientists and policymakers make decisions in isolation. For example, while coal is harmful, communities reliant on it for jobs and the local economy may have different perspectives. Addressing their concerns can foster broader support and accelerate progress, rather than facing resistance.

Mike and I have worked to integrate this focus into our fundamental research, which I find very rewarding.

Toney: As an example, one of the first-year chemical engineering graduate students, Summer-Solstice Thomas, is proposing to specifically engage local communities impacted by Per- and polyfluoroalkyl substances (PFAS), or so-called “forever chemicals,” in her graduate research aimed at improving membranes to remediate PFAS.

Why do graduate students need to understand energy justice?

Davis: Students who understand both the scientific and social aspects of climate change will develop better and more implementable solutions to address environmental challenges in ways that minimize harm to vulnerable communities and address previous injustices.

In STEM, PhD students often focus on their specific science and don’t have all the skills needed to contribute to a just energy transition. For example, students working on renewable energy may learn how batteries work, but not about the negative impacts of mining the materials needed for them.

What are some of these potential negative impacts?

Davis: Sourcing materials and establishing sites for renewable energy can negatively impact adjacent communities in ways similar to fossil fuels. For example, the cobalt mined in the Democratic Republic of the Congo for lithium-ion electric car batteries, has led to severe injustices, including child labor and mining deaths.

Casey Davis

How have scientists historically approached energy justice?

Toney: Historically, many scientists, including myself, have only superficially addressed this issue. However, there is a growing awareness among early-career scientists about its significance. We need to integrate these considerations into our technical work. Recently, there’s been a significant increase in student interest in energy justice. In my experience, recent engineering students are particularly passionate about energy and environmental justice.

Davis: This growing demand highlights the need for professors and academic institutions to consider these concerns more in their teaching and research. It’s essential to address these issues in graduate school, where future scientists and engineers are trained. By teaching students the importance of energy justice and how to incorporate it into their work, they can apply these principles in their careers, whether in industry or regulatory agencies like the EPA.

Are there barriers to integrating energy justice into research?

Davis: PhD students might hesitate to add this new focus due to concerns about extending their graduation time and potential pushback from advisors. Additionally, some journals and reviewers have been resistant.

Toney: Incorporating these concepts at the PhD level has been challenging, but Casey and other students have successfully integrated energy justice into their research, receiving positive feedback during exams. In my generation, nobody really ever thought about this.

Professor Mike Toney

How can these barriers be overcome?

Davis: Solutions should be tailored to each institution, but incorporating more diversity, equity and inclusion initiatives is essential, a point that we discuss more in the Comment. Schools can develop interdisciplinary programs and hire faculty who support these approaches to encourage a culture shift. Equity can become part of the curricula and dissertations of science graduate students. While it’s challenging, these incremental changes have significant impact. We’re already seeing progress.

What is changing in ��ֱ�� Boulder’s graduate program?

Davis: Mike is encouraging me to incorporate energy justice into my dissertation. This sort of support from professors is necessary for graduate students to begin to develop a holistic understanding of how their work fits into larger issues such as climate justice.

Toney: ��ֱ�� Boulder is proposing a new approach to graduate education through an NSF grant proposal. The plan integrates fields like communications, business and social sciences into PhD programs, giving students across disciplines a broader understanding of engineering and science. This multidisciplinary training prepares our students with the tools needed to apply these concepts in their careers end enable a just energy transition. I see this as expanding engineering education to include broader training which would extend into the undergraduate level.

This approach will better equip our graduates to make a more significant, holistic impact in the world.

How will you be integrating energy justice into graduate curricula here at ��ֱ�� Boulder?

Toney: I will be teaching a new one-credit class Spring semester on “Energy Justice in Engineering.”

Do you have a vision for how incorporating energy justice at a college level might evolve?

Davis: I envision energy justice becoming integral to STEM education, where students not only learn science and engineering concepts but also understand its social implications. Solving climate change is also about addressing social issues. If we resolve social inequalities, it would significantly advance our climate goals. For instance, equitable public transportation reduces emissions and supports broader access. It’s about creating a more abundant and connected community.

In a comment published in Nature Chemistry on Nov. 25, Casey Davis, a chemistry PhD student, along with her advisor Mike Toney, a professor of chemical engineering and materials science, and others, argue that universities must integrate energy justice into graduate curricula and research.

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News

ChBE faculty earn Air Force Young Investigator Award

Kōnane Bay, self-healing, innovative materials

Ankur Gupta, more precise chemical sensors

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PhD student’s work on engineered adhesives wins national recognition

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Research program sparks student’s transfer to ����ֱ�� Boulder

You started classes at ����ֱ�� Boulder in January. How’s it going so far?

How did you learn about this program?

What were your academic plans before participating in the YSSRP?

What did you enjoy about your YSSRP research project?

How did participating in the YSSRP influence you to switch from math to engineering?

Why did you decide to attend ����ֱ�� Boulder?

What was your favorite part of participating in the YSSRP?

What are your plans for the future?

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How the tiger really got his stripes

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Jerome Fox receives Presidential Early Career Award for Scientists and Engineers

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Laurel Hind honored with CAREER Award for advancing immune response research

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����ֱ�� Boulder PhD student takes Materials Research Society's top graduate prize

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Kōnane Bay receives CAREER award for polymer fabrication research

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Kristi Anseth recognized with international VinFuture Prize for Women Innovators

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Building a just future: Why graduate research must include energy justice

What is energy justice?

Can you explain the social aspects of energy justice?

Why do graduate students need to understand energy justice?

What are some of these potential negative impacts?

How have scientists historically approached energy justice?

Are there barriers to integrating energy justice into research?

How can these barriers be overcome?

What is changing in ����ֱ�� Boulder’s graduate program?

How will you be integrating energy justice into graduate curricula here at ����ֱ�� Boulder?

Do you have a vision for how incorporating energy justice at a college level might evolve?

Off

Research program sparks student’s transfer to ��ֱ�� Boulder

You started classes at ��ֱ�� Boulder in January. How’s it going so far?

Why did you decide to attend ��ֱ�� Boulder?

��ֱ�� Boulder PhD student takes Materials Research Society's top graduate prize

What is changing in ��ֱ�� Boulder’s graduate program?

How will you be integrating energy justice into graduate curricula here at ��ֱ�� Boulder?