What is reversible smart glue from Newcastle University?

A water-based, pH-responsive adhesive developed by Newcastle University's School of Engineering. It bonds via electrostatic forces at neutral pH and debonds in acidic or alkaline solutions. Details in their 2026 Soft Matter paper .

How does the pH-responsive mechanism work?

Oppositely charged polymers (polyanion/polycation) attract at pH 7. Acid (pH≤2) collapses polycations; alkali (pH≥12) collapses polyanions, breaking bonds cleanly.

Who are the key researchers?

Dr. Adriana Sierra-Romero (lead), Prof. Mark Geoghegan, Prof. Katarina Novakovic, Emmanuel Abotsi. Learn more via research assistant jobs .

What are the main applications?

Recycling labels/laminates, automotive/electronics disassembly, potential in drug delivery for controlled release.

How does it improve UK recycling?

UK discards 90bn plastic pieces yearly; this glue enables clean separation, boosting 44% recycling rates and reducing exports.

What is the one-pot formulation?

2026 update adds clays for single-mix application, non-drip, full detachment—no dual coatings needed.

Is it commercially viable?

Uses cheap materials, paint-like production; shelf-stable 1+ year, EPSRC-funded, industry trials at Biffa.

Controlled release applications?

pH-trigger suits hydrogels for targeted drug delivery in tumors (acidic pH), minimizing systemic exposure.

Bond strength compared to others?

>1 MPa lap shear; between pressure-sensitive and structural glues, ideal for non-load-bearing.

Dual stimuli-responsive variants, broader commercialization. Newcastle leads sustainability research—see higher ed career advice .

Environmental benefits?

VOC-free, supports net-zero; aligns with UK plastic waste targets amid 5M tonnes annual use.

Reversible Smart Glue Newcastle University

a hand holding a white tube — Photo by Ellie Eshaghi on Unsplash

🔬 The Breakthrough in Reversible Adhesive Technology

Newcastle University engineers have made headlines with their latest advancement in adhesive science: a water-based reversible smart glue that bonds materials securely under normal conditions but debonds effortlessly when exposed to specific pH changes. This innovation, detailed in a recent publication in Soft Matter, represents a significant step forward in sustainable materials engineering, particularly for applications requiring advanced bonding and controlled release.

The glue, developed by a multidisciplinary team from the School of Engineering, addresses long-standing challenges in recycling and material separation. Traditional adhesives create permanent bonds that complicate disassembly, leading to increased waste. In contrast, this pH-responsive adhesive—formulated as an emulsion similar to industrial paint—allows for on-demand release using simple acidic or alkaline solutions, opening doors to greener manufacturing and recycling processes.

Funded by the Engineering and Physical Sciences Research Council (EPSRC), the project builds on years of foundational research, evolving from blue-sky experiments into a practical, scalable solution. Its potential extends beyond recycling to controlled release systems, where precise debonding could revolutionize sectors like biomedical devices and pharmaceuticals.

The Research Team Driving Innovation

At the helm is Dr. Adriana Sierra-Romero, a Research Associate whose expertise in polymer chemistry was pivotal in synthesizing the glue via emulsion polymerization. As first author on the latest paper, she highlights the growing industry interest: "Reversible adhesives are starting to attract attention in industry. They’re not yet mainstream, but we expect adoption to grow as companies look for more sustainable solutions."

Lead investigator Professor Mark Geoghegan, Roland Cookson Professor of Engineering Materials, brings a physicist's perspective on nanoscale interactions. Collaborating closely is Professor Katarina Novakovic, a chemical engineer focused on sustainability, and MSc student Emmanuel Abotsi, who contributed to the one-pot formulation incorporating clays.

This team's synergy exemplifies how higher education institutions like Newcastle University foster cutting-edge research. For those pursuing careers in materials science or polymer engineering, opportunities abound in UK universities—explore research jobs or higher ed jobs on AcademicJobs.com to join similar impactful projects.

Newcastle University reversible smart glue research team including Dr. Adriana Sierra-Romero, Prof. Mark Geoghegan, and Prof. Katarina Novakovic

How the Reversible Smart Glue Works: A Step-by-Step Breakdown

Understanding the mechanism requires grasping the basics of electrostatic adhesion. The glue consists of oppositely charged polymers: polycations (positively charged) and polyanions (negatively charged). Here's how it functions:

Application: Coat surfaces with the water-based emulsion, which dries to form a stable film at neutral pH (around 7). The extended polymer chains repel within their own layer but attract across layers due to opposite charges.
Bonding: Press coated surfaces together; electrostatic forces create a strong lap shear strength exceeding 1 MPa, comparable to white glues, effective on low-energy plastics like polypropylene (PP) and polyethylene (PE).
Debonding Trigger: Immerse in acidic solution (pH ≤2, e.g., dilute citric acid) for polycationic bonds or alkaline (pH ≥12, e.g., sodium hydroxide) for polyanionic. Charges neutralize, chains collapse, and entropy drives separation without residue.
One-Pot Innovation: The 2026 update adds clays (montmorillonite for polyanions, hydrotalcite for polycations), enabling a single formulation that thickens for non-drip application and fully detaches under trigger.

This process uses commodity materials like styrene, butyl acrylate, and acrylic acid, ensuring cost-effectiveness and scalability via existing paint production lines. Shelf-stable for over a year, it resists humidity, making it industrially viable.

From Lab to Publication: The Development Timeline

The journey began in 2007 with Professor Geoghegan's work at the University of Sheffield on pH-switchable polyelectrolytes. By 2020 at Newcastle, collaboration with Professor Novakovic secured EPSRC funding—initially £250,000, extended to £760,000.

Dr. Sierra-Romero joined in 2021, achieving a prototype in four months. The first milestone was the 2023 paper in Angewandte Chemie International Edition, introducing the electrostatic reversible adhesive. Tested at Biffa’s Seaham recycling plant, it proved effective for label detachment.

Patents filed, the team entered the Royal Society of Chemistry’s Emerging Technologies competition as finalists. The February 2026 Soft Matter publication (DOI: 10.1039/D5SM01039J) details the clay-enhanced one-pot version, marking readiness for commercialization. More details in the Newcastle University press release.

A philips earbud charging case on a table.

Photo by Daba Sir on Unsplash

♻️ Key Applications in Recycling and Beyond

Primarily targeted at recycling, the glue excels in separating dissimilar materials:

Packaging: Detach PP labels from PET bottles in alkaline wash, recovering 3% mass lost to contamination. UK households discard 90 billion plastic packaging pieces yearly, with only 17% recycled domestically— this could boost rates.
Laminates and Automotive: Disassemble multi-layer plastics and car parts for material repurposing.
Electronics: With input from Professor Volker Pickert, enable e-waste recycling.
Controlled Release: In biomedical fields, pH-responsive debonding suits drug delivery systems. Similar hydrogels release therapeutics in acidic tumor environments (pH 6.5-6.8) versus neutral blood (pH 7.4), minimizing side effects.

Broader potential includes temporary construction bonds or smart packaging that opens on cue.

Environmental and Economic Impacts in the UK Context

UK plastic use hit 5 million tonnes in 2026, with recycling rates at 44% in England (provisional 2025 data). Exports rose 84% to developing countries, sparking sustainability concerns. This glue supports net-zero goals, aligning with Newcastle's QS Sustainability ranking (22nd UK, 64th global).

Economically, it reduces recycling costs by simplifying workflows—no harsh solvents or mechanical shredding. The global recycled plastics market in the UK is projected to grow from USD 983.6 million in 2025 to over USD 2 billion by 2033. Reversible adhesives tap into this, with industry adoption expected as regulations tighten.

Stakeholders like recyclers (e.g., Biffa) and manufacturers praise its VOC-free nature, potentially cutting landfill waste and emissions.

Challenges Overcome and Comparisons to Existing Solutions

Vs. Pressure-Sensitive Adhesives: Stronger bonds, true reversibility without pulling.
Vs. Structural Glues (e.g., Epoxy): Debonds cleanly, eco-friendly.
Challenges Addressed: Drip prevention via clays (viscosity up 800x for polycations); broad substrate compatibility; stability in humidity.

While bond strength is intermediate (not for load-bearing), it's ideal for non-structural uses. Future iterations may enhance durability.

Future Outlook: Commercialization and Research Frontiers

Professor Geoghegan is optimistic: "It is really exciting to see how this technology is developing." Professor Novakovic emphasizes education: "Newcastle embeds sustainability in curricula." The team attends trade fairs, signaling industry partnerships.

Horizons include temperature/pH dual-responsive variants for drug delivery, inspired by pH hydrogels in cancer therapy. In higher education, this spurs demand for polymer experts—check academic CV tips or lecturer jobs.

Photo by Marija Zaric on Unsplash

Implications for Higher Education and Careers

Newcastle's success underscores UK universities' role in innovation. With EPSRC backing, such projects train students like Abotsi, preparing them for green jobs. AcademicJobs.com connects talent to roles in UK higher ed, from postdocs to faculty.

Rate your professors or courses via Rate My Professor and explore career advice for thriving in research.

Conclusion: A Sticky Solution to Sustainability

This reversible smart glue exemplifies how university research translates to real-world impact. As adoption grows, it promises cleaner recycling streams and novel controlled release tech. Stay informed on higher ed innovations and find your next role at higher-ed-jobs, university-jobs, rate-my-professor, or post a job via post-a-job.