Thank you to the entire RBI community for participating in a transformative 2025.  Please enjoy reviewing the accomplishments we made together.  We look forward to partnering with you in 2026.

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Plastic packaging is ubiquitous in our world, with its waste winding up in landfills and polluting oceans, where it can take centuries to degrade.

To ease this environmental burden, industry has worked to adopt renewable biopolymers in place of traditional plastics. However, developers of sustainable packaging have faced hurdles in blocking out moisture and oxygen, a barrier critical for protecting food, pharmaceuticals, and sensitive electronics.

Now, researchers at the Georgia Institute of Technology have developed a biologically based film made from natural ingredients found in plants, mushrooms, and food waste that can block moisture and oxygen as effectively as conventional plastics. Their findings were recently published in ACS Applied Polymer Materials.

“We’re using materials that are already abundant in and degrade in nature to produce packaging that won’t pollute the environment for hundreds or even thousands of years,” said Carson Meredith, a professor in Georgia Tech’s School of Chemical and Biomolecular Engineering (ChBE@GT) and executive director of the Renewable Bioproducts Institute. “Our films, composed of biodegradable components, rival or exceed the performance of conventional plastics in keeping food fresh and safe.”

Meredith’s research team has worked for more than a decade to develop environmentally friendly oxygen and water barriers for packaging. While earlier research using biopolymers showed promise, high humidity continued to weaken the barrier properties.

However, Meredith and his collaborators found a fix using a blend of these natural ingredients: cellulose (which gives plants their structure), chitosan (derived from crustacean-based food waste or mushrooms), and citric acid (from citrus fruits).

“By crosslinking these materials and adding a heat treatment, we created a thin film that reduced both moisture and oxygen transmission, even in hot, humid conditions simulating the tropics,” said lead author Yang Lu, a former postdoctoral researcher in ChBE@GT.

The barrier technology developed by the researchers consists of three primary components: a carbohydrate polymer for structure, a plasticizer to maintain flexibility, and a water-repelling additive to resist moisture. When cast into thin films, these ingredients self-organize at the molecular level to form a dense, ordered structure that resists swelling or softening under high humidity.

Even at 80 percent relative humidity, the films showed extremely low oxygen permeability and water vapor transmission, matching or outperforming common plastics such as poly(ethylene terephthalate) (PET) and poly(ethylene vinyl alcohol) (EVOH).

“Our approach creates barriers that are not only renewable, but also mechanically robust, offering a promising alternative to conventional plastics in packaging applications,” said Natalie Stingelin, professor and chair of Georgia Tech’s School of Materials Science and Engineering (MSE) and a professor in ChBE@GT.

The research team has filed for patent protection for the technology (patent pending). The research was supported by Mars Inc., Georgia Tech’s Renewable Bioproducts Institute, and the U.S. Department of Defense through the National Defense Science and Engineering Graduate Fellowship Program. Eric Klingenberg, a co-author of the study, is an employee of Mars, a manufacturer of packaged foods.

Citation: Yang Lu, Javaz T. Rolle, Tanner Hickman, Yue Ji, Eric Klingenberg, Natalie Stingelin, and Carson Meredith, “Transforming renewable carbohydrate-based polymers into oxygen and moisture-barriers at elevated humidity,” ACS Applied Polymer Materials, 2025.

 

This story is shared with the University of Illinois Urbana-Champaign newsroom. John R. Reynolds is a professor in the School of Chemistry and Biochemistry and School of Materials Science and Engineering at Georgia Tech. He served as founder of the Georgia Tech Polymer Network (GTPN) and is a member of the Center for Organic Photonics and Electronics (COPE).

Chirality, a property where structures have a distinct left- or right- “handedness,” allows natural semiconductors to move charge and convert energy with high efficiency by controlling electron spin and the angular momentum of light. A new study has revealed that many conjugated polymers, long considered structurally neutral, can spontaneously twist into chiral shapes. This surprising behavior, overlooked for decades, could pave the way for development of a new class of energy-efficient electronics inspired by nature.

The research, a collaborative project that included researchers from the University of Illinois Urbana-Champaign, Georgia Institute of Technology, University of North Carolina, and Purdue University was recently published in the Journal of the American Chemical Society.

“Many molecules essential to life are chiral,” said Ying Diao, professor of chemical and biomolecular engineering at Illinois, who led the project. “The question that has remained a really a big fascination across the field is how chiral symmetry breaking happens in the first place: that is how life selects one handedness over the other. Our work mainly focuses on the origin of chirality: why chirality spontaneously emerges in absence of any chiral sources.” 

To answer this question, the team tested 34 different conjugated polymers. Each polymer was dissolved in a solvent, then the researchers gradually increased the polymer concentration to observe whether liquid–liquid phase separation (LLPS) occurred. When LLPS was detected, they used circular dichroism spectroscopy to analyze the samples, revealing a strong correlation between phase separation and the emergence of chirality. The researchers refer to this phenomenon as spontaneous chiral symmetry breaking.

They found that approximately two-thirds of the polymers spontaneously formed chiral structures when their concentration in the solution increased.

“That took our community by surprise, because conjugated polymers have been studied for half a century,” Diao said. “These new chiral helical states of matter have basically been hiding in plain sight.”

To understand why some of the polymers developed chirality while others did not, Illinois chemistry professor and senior co-author Nicholas E. Jackson applied machine learning to analyze molecular features across the polymer library. The analysis, later backed up by additional testing, revealed that polymers with longer molecular chains were more likely to form chiral assemblies. Unexpectedly, the researchers also found that the presence of oxygen atoms in the side chains was a strong predictor of chiral behavior.

“Machine learning uncovered hidden patterns across dozens of conjugated polymers, relating subtle chemical details to chiral phase formation,” Jackson said. “Such insights would have been very difficult to derive by human intuition alone.”

Diao noted that the discovery not only deepens our fundamental understanding of chiral emergence but also holds significant technological promise. In nature, chiral systems – such as those involved in photosynthesis – enable highly efficient electron transport. Looking ahead, Diao said that mimicking this behavior could lead to major performance gains in electronic devices and innovation of new device types.

“We are thinking about using chirality to control conductivity – for example, in transparent conductors for phones or in solar cells that could be more stable and efficient,” she said. “In our computers, electrons bounce around and heat is a big problem. But if we make chiral versions, we think charge transfer could be extremely efficient, just like in nature.”

“What’s nice about this is, this is not the end of the story,” said Georgia Institute of Technology chemistry professor John Reynolds, a senior co-author on the study. “This work provides guidance to polymer scientists in the field for studying the many, many conjugated polymers that have been synthesized over the years, and for designing new polymers with enhanced properties.”

 

This study was supported by the U.S. Office of Naval Research, the Air Force Office of Scientific Research, the Molecule Maker Lab Institute, and the National Science Foundation. Polymers for the study were provided by Reynolds, University of North Carolina chemistry professor Wei You, University of Illinois chemistry professor Jeff Moore, and Purdue University chemistry professor Jianguo Mei.

In addition to her appointment in Chemical & Biomolecular Engineering, Diao is a full-time faculty member at the Beckman Institute for Advanced Science and Technology, holds a faculty appointment with Chemistry in the College of Liberal Arts & Sciences, and is affiliated with Materials Science & Engineering in The Grainger College of Engineering. In addition to his appointment in Chemistry, Jackson is a group leader at the Beckman Institute and affiliate faculty member in the departments of Chemical & Biomolecular Engineering and Materials Science & Engineering.

The paper, "Ubiquitous Chiral Symmetry Breaking of Conjugated Polymers via Liquid Liquid Phase Separation," is available online at https://pubs.acs.org/doi/abs/10.1021/jacs.5c07995

The 2025 round of Sustainability Next Research Seed Grants has been awarded to 17 transdisciplinary research teams representing a vibrant network of 51 collaborators from across Georgia Tech. These teams span 21 unique units from six of the seven Colleges, including Schools, research centers, and Interdisciplinary Research Institutes. 

The seed grant program, administered by the Brook Byers Institute for Sustainable Systems (BBISS), reaches many faculty members from a diverse array of disciplines due to the generous support provided by broad-based partnerships in addition to the Sustainability Next funds. This year’s partners are the Georgia Tech Arts Initiative, BBISS, Walter H. Coulter Department of Biomedical Engineering, School of Civil and Environmental Engineering, College of Design, School of City and Regional Planning, School of Computer Science, Ray C. Anderson Center for Sustainable Business, Energy Policy and Innovation Center, Parker H. Petit Institute for Bioengineering and Bioscience, Institute for Matter and Systems, Institute for People and Technology, Institute for Robotics and Intelligent Machines, Strategic Energy Institute, and Center for Sustainable Communities Research and Education.

The goal of the program is to nurture promising research areas for future large-scale collaborative sustainability research, research translation, and/or high-impact outreach; to provide mid-career faculty with leadership and community-building opportunities; and to broaden and strengthen the Georgia Tech sustainability community as a whole. The call for proposals was modeled after the Office of the Executive Vice President for Research’s Moving Teams Forward and Forming Teams programs.

Looking ahead, BBISS will support and nurture these projects in collaboration with the relevant funding partners. Beginning in October, BBISS will host a series of focused workshops designed to foster collaboration and provide additional support to help advance these initiatives. Projects have been grouped into five thematic clusters, each of which will be the focus of an upcoming workshop:

• Circularity Programs
• Adaptation to the Changing Environment
• Community Engagement and Education
• Climate Science and Solutions
• Environmental and Health Impacts

BBISS faculty fellows, past seed grant recipients, and other interested Georgia Tech faculty are invited to participate. If you are interested in participating in the workshops, please email kristin.janacek@gatech.edu. The first session on Circularity Programs is Oct. 16 at 1 p.m. in the Peachtree Room (3rd floor) of the John Lewis Student Center.

The 2025 Sustainability Next Seed Grant awards are:

Forming Teams:

• Developing a Sustainable and Ethical Electric Vehicle Ecosystem Workforce for the Future Through Cross-Sector Partnerships. Principal Investigators (PI): Joe Bozeman. Co-Principal Investigator (Co-PI): Jennifer Hirsch.
• Unlocking Circularity at Scale: Platform-Based Solutions for Advancing Material Reuse and Supply Chain Resilience. Principal Investigator: Marco Ceccagnoli. Co-PIs: Matthew Realff, Patricia Stathatou, Christos Athanasiou.
• OpenGUARD: Geospatial Utility Aggregations with Robust Differential Privacy. PI: Patrick Kastner. Co-PI: Juba Ziani.
• Regenerative Framework: A Transdisciplinary Model for Urban Climate Resilience and Soil Health. PI: Jenny McGuire. Co-PI: Nicole Kennard.
• Guiding Transportation With Community Action Through Research, Education, and Service (GT-CARES). PI: Rounaq Basu. Co-PIs: Ruthie Yow,  Sofía Pérez-Guzmán, Rebecca Watts Hull.
• Co-optimizing Design and Coordination for Sustainable Multi-Robot Construction. PI: Edvard Bruun. Co-PI: Harish Ravichanda.
• Campus as Material Ecology: Building Transdisciplinary Circular Systems for Plastic Tracking, Transformation, and Community Engagement. PI: Hyojin Kwon. Co-PIs: Michael Best, Russ Clark, Tim Trent, Meisha Shofner.
• Sonifying Climate Infrastructures: Community Outreach and Education With Shade Synthesizer. PI: Heidi Biggs. Co-PIs: Clint Zeagler, Alexandria Smith.
• Building a Georgia Tech Research Partnership for Community-Based Food System Resilience. PI: Johannes Milz. Co-PIs: Xin Chen, Inge Rocker,  Sofía Pérez-Guzmán, Nicole Kennard.

Moving Teams Forward:

• Are Data Centers the New Landfills? Social, Economic, and Environmental Tradeoffs. PI: Allen Hyde. Co-PIs: Josiah Hester, Cindy Lin, Nicole Kennard, Joe Bozeman, Elora Raymond, Tony Harding, Jung-Ho Lewe.
• Game-Based Learning in Energy Systems: A Rigorous Evaluation of Current Crisis. PI: Jessica Roberts. Co-PI: Daniel Molzahn.
• Strategic Application of Antibiotic-Independent Therapy to Treat Coral Disease Outbreaks. PI: Lauren Speare.
• Advancing Water Reuse Through Research, Education, and Community Partnerships in Atlanta, Georgia. PI: Katherine Graham. Co-PIs: Amanda Nolen, Yeqing Kong.
• Assessing the Accuracy and Reliability of Low-Cost Particulate Matter (PM) Sensors Across Diverse Ambient Environments. PI: Nga Lee (Sally) Ng. Co-PI: Ted Russell.
• Developing a Georgia Community Center Into a Sustainability Hub. PI: Ashutosh Dhekne, Co-PIs: Umakishore Ramachandran, Danielle Willkens, Ruthie Yow.
• What, When, Where of Air Pollution: PM2.5 and How It Impacts Health. PI: Shuichi Takayama. Co-PI: Nga Lee (Sally) Ng.
• Enabling Communities to Baseline the Performance of Energy Systems. PI: Jung-Ho Lewe. Co-PIs: Scott Duncan, David Solano Sarmiento, Danielle Willkens, Anna Tinoco-Santiago.

This round of funding was highly competitive, with 45 proposals submitted. BBISS extends its gratitude to all the individuals and groups who applied, as well as to the faculty and staff who contributed their time and expertise to evaluate the proposals. Their thoughtful input was essential to achieving a fair and collaborative selection process, ensuring that the awarded proposals align strongly with the BBISS’ strategy and show promise for long-term impact and future research opportunities.

According to BBISS Executive Director Beril Toktay, and Brady Family Chair in Management, “The high level of participation demonstrates the enduring commitment to sustainability research and engagement by the Georgia Tech community. BBISS honors this commitment by looking for collaboration opportunities with all who are driving sustainability efforts at Georgia Tech.”

The National Science Foundation (NSF) has awarded School of Materials Science and Engineering (MSE) Professor & Regents’ Entrepreneur Rampi Ramprasad a $2 million grant to advance research at the intersection of artificial intelligence (AI) and polymer science. He and a multidisciplinary team of Georgia Tech researchers will design next-generation polymer-based packaging materials that can easily be recycled or biodegraded at the end of their use. The project addresses one of the most pressing challenges in global sustainability: plastic waste.

Read more on the Georgia Tech Materials Science and Engineering Newspage

The Renewable Bioproducts Institute (RBI) 2025 Spring Workshop, held May 12–13, brought together leading researchers, industry professionals and students to explore innovations in pulp and paper manufacturing. Hosted at the Kendeda Building and the Paper Tricentennial Building, the event opened with remarks from Carson Meredith, RBI executive director, and featured presentations on energy and resource efficiency, carbon accounting and competitiveness.

Highlights included talks on membrane separations, electrochemical processing and low-carbon fuels, with contributions from experts such as Chris Luettgen, Jose Gonzalez, Sankar Nair, Marta Hatzell and Dave Beck.

Insights from the 2025 RBI Spring Workshop

• Revolutionizing Kraft Pulping with Graphene Oxide Membranes
  Georgia Tech’s rGO membrane technology is transforming the kraft pulping process. These membranes enable efficient black liquor dewatering, organic acid recovery and lignin fractionation—leading to significant energy savings, water recycling and new revenue streams from bioproducts.
• North America’s Dual Challenge: High Emissions, High Opportunity
  While North America remains a pulp and paper powerhouse (15% of global capacity), it also has one of the highest carbon intensities. This presents both a challenge and an opportunity to lead in emissions reduction through asset renewal and innovation.
• Biogenic CO₂: From Emission to Asset
  Kraft pulp mills emit large volumes of biogenic CO₂—an untapped resource. With carbon capture and utilization (CCUS), mills could generate up to $300 million annually in carbon removal credits, turning emissions into economic value.
• Integrated Biorefineries: The Future of Pulp Mills
  The vision for pulp mills is evolving—from single-product facilities to multi-product biorefineries. Innovations like lignin-based materials, organic acid conversion to biofuels and advanced nanofiltration are paving the way for circular use of carbon in manufacturing.
• Decarbonization Is a Strategic Imperative
  With increasing regulatory and consumer pressure, especially from global brands targeting Scope 3 emissions, pulp and paper producers must act. Embracing technologies like rGO membranes and CCUS is not just sustainable—it’s essential for competitiveness.
• Electrochemical Carbon Capture and Conversion for On-Site Fuel Production
  Hatzell’s lab is pioneering the use of bipolar membrane (BPM) electrolysis to convert captured carbon (from bicarbonate solutions) into valuable fuels like CO and H₂. This approach enables:
  • 100% carbon utilization with more than 70% Faradaic efficiency for CO production.
  • Integration with pulp and paper processes to valorize CO₂ emissions instead of storing them.
  • Use of acid-stable single-atom nickel catalysts to improve selectivity and efficiency.
• The PAPER-ZERO Initiative
  This initiative explores transformative pathways to decarbonize the pulp and paper industry by:
  • Evaluating scenarios that eliminate combustion of black liquor and waste wood.
  • Investigating renewable energy integration and alternative uses for black liquor.
  • Assessing the cost, energy and environmental trade-offs of emerging technologies.

The workshop also featured a student poster session, networking opportunities and updates on APPTI collaborative projects. The event concluded with a meeting of the RBI Industry Advisory Board, reinforcing the institute’s role as a hub for partnership and innovation in renewable bioproducts.

“We’re grateful to our industry member partners for sharing their time and expertise,” said Belinda Vogel, research engagement manager. “The advisory board meeting highlighted how essential collaboration is in advancing basic science and renewable bioproduct manufacturing.”

Cyrus Aidun has been a distinguished professor at Georgia Tech’s George W. Woodruff School of Mechanical Engineering since 2003. His career is marked by groundbreaking research and significant contributions to fluid mechanics and bioengineering, establishing him as a leading figure in these fields.

In particular, Aidun has focused on industrial competitiveness. His efforts to reduce energy and water consumption in fiber composite products have attracted significant attention and funding. This research is critical for developing sustainable and cost-effective manufacturing processes while reducing environmental impact.

As principal investigator, Aidun has received funding for major projects from the Department of Energy’s Office of Energy Efficiency and Renewable Energy (DOE-EERE, with Devesh Ranjan as co-principal investigator), the DOE’s Advanced Research Projects Agency-Energy, and the Defense Advanced Research Projects Agency (with Art Rangauskas at the University of Tennessee). These projects are affiliated with Aidun’s development of the Multiphase Forming Lab at Georgia Tech’s Renewable Bioproducts Institute (RBI).

The only one of its kind in North America, this innovative system significantly reduces the amount of water required to process paper. As a result, the heat and energy needed to dry the paper — typically an energy-intensive process — are also reduced. The Multiphase Former uses up to 70% less water, which substantially lowers the energy required for drying. This research, which began about five years ago, has drawn broad interest from industry. A more recent project, funded by DOE-EERE and led by Carson Meredith, combines Multiphase Forming with the latest technologies in refining and drying.

Aidun earned his bachelor’s and master’s degrees from Rensselaer Polytechnic Institute and completed his Ph.D. at Clarkson University in 1985. He joined the Woodruff School in 2003 after serving two years as a program director at the National Science Foundation. He began at Georgia Tech in 1988 as an assistant professor at the Institute of Paper Science and Technology. Previously, he was a research scientist at Battelle Research Laboratories, a postdoctoral associate at Cornell University, and a senior research consultant at the National Science Foundation’s Supercomputer Center at Cornell.

Aidun has received several national and international honors, including the National Science Foundation Presidential Investigator Award, the Gunnar Nicholson Fellowship, and the L.E. Scriven Award from the International Society of Coating Science and Technology.

Georgia Tech's Renewable Bioproducts Institute (RBI) is pleased to announce the appointment of Hanjiang (John) Xu as director of the Multiphase Forming Lab. This strategic selection leverages Xu's extensive experience in papermaking, new product and process development, fluid mechanics, and project management.

The only one of its kind in North America, this innovative system significantly reduces the amount of water required to process paper. As a result, the heat and energy needed to dry the paper—typically an energy-intensive process—are also reduced. The Multiphase Forming Lab uses up to 70% less water, which substantially lowers the energy required for drying.

Xu brings over 20 years of experience in managing laboratory paper machines and pilot testing equipment, along with a robust background in fluid mechanics, material science, and instrumentation development. His professional experience includes significant roles at International Paper, AstenJohnson, and Georgia Tech’s George W. Woodruff School of Mechanical Engineering.

"We are thrilled to have John lead the establishment and operation of this new facility," said Carson Meredith, RBI executive director. "His extensive knowledge and industry experience make him the ideal leader to partner with both RBI members and non-members to drive reduced energy consumption and costs.”

Xu's career is marked by innovative research and successful commercialization of new products and processes. At AstenJohnson, he served as a senior research scientist, specializing in forming and press fabrics used in the paper industry. His work led to the commercialization of several new forming and press products, and he managed pilot press stand at AstenJohnson and participated in papermaking trials at different pilot facilities to evaluate the performance of these fabrics.

Prior to AstenJohnson, Xu held positions at International Paper's Corporate Technology Center, where he managed the Microfinishing Lab and Humidity Resistant Liner Lab. His research provided critical insights that influenced the company’s major business decisions. He also developed various unique instruments for different paper mills at International Paper.

Xu earned his Ph.D. in paper science and mechanical engineering from Georgia Tech’s Institute of Paper Science and Technology. His doctoral research focused on the measurement of fiber suspension flow and forming jet velocity profile using Pulsed Ultrasonic Doppler Velocimetry (PUDV). He also holds a B.S. in Material Science and Engineering from Tsinghua University in Beijing, China.

For more information about the Multiphase Forming Lab, please contact: Hanjiang (John) Xu at hanjiang.xu@me.gatech.edu