Scientists at the Technical University of Denmark have developed a new way to integrate ultra-thin oxide membranes onto flexible metallic supports, paving the way for next-generation wearable sensors, foldable displays, and flexible energy devices. Their study demonstrates that, by carefully choosing the supporting metal surface, these fragile crystalline sheets can adhere strongly while maintaining their ability to stretch and bend.
“The main finding of this study is the successful integration and adhesion of freestanding single-crystalline oxide membranes—thin crystalline sheets that are detached from their original growth surface—onto metallic titanium nitride (TiN)-coated flexible polymer substrates,” Professor Dae-Sung Park, one of the lead authors of the study, said in an email.
Why flexible oxides matter
Materials known as complex oxides—compounds made of oxygen combined with metals such as manganese, titanium, or nickel—are considered among the most versatile in modern materials science.
They can display an extraordinary range of behaviors from magnetism, where materials generate their own magnetic field, to ferroelectricity, where they develop an internal electric field that can be switched on and off. They can also show unusual electronic and catalytic properties, making them attractive for use in electronics, energy, and sensing technologies.
“Certain complex oxides offer many useful and diverse functionalities with high property tunability, some of which are not available in 2D materials,” explains Professor Nini Pryds, also a lead author of the work.
Until recently, however, most oxide films had to be grown on rigid crystalline bases, which limited both the material choices and the range of possible applications. This changed with advances in fabricating freestanding membranes. These membranes open the possibility of integrating oxides onto flexible substrates like polymers or metals, which is critical for building future bendable or stretchable devices.
Overcoming challenges in flexible oxide integration
Despite the promise, working with freestanding oxides is far from simple. Because they are brittle and crystalline, they tend to crack or peel off when placed on flexible supports. As Park notes, “The remaining challenges for the practical use of these membranes in various devices include enhancing their quality by minimizing defects such as microcracks, wrinkles, and surface contamination.”
Another key difficulty is finding a substrate that can hold the membrane firmly while still allowing it to be strained and tuned by external forces like electric fields or mechanical stress.
To tackle this, the researchers used a two-pronged strategy. They refined the fabrication process to produce large, defect-free membranes and then tested how these membranes adhere to different metallic layers. The oxide membranes were transferred onto thin polymer sheets coated with various metals, including gold, platinum, and titanium nitride. The idea was to see which metal provided the best balance of adhesion and flexibility.
The role of titanium nitride
The results were striking. While gold and platinum are widely used in electronics, they did not perform as well as TiN. On TiN-coated polymers, the oxide membranes stuck firmly and could be uniformly strained by about one percent without peeling off. “This arises due to a strong interfacial interaction between oxide and TiN,” says Park. In other words, the chemical bonding and structural match at the interface helped create a stable connection that held up under bending.
The researchers tested a well-studied oxide called LSMO, which can display unusual magnetic and electronic properties under strain. By successfully adhering LSMO membranes onto TiN-coated supports, they showed that strain engineering—tuning a material’s properties by stretching or compressing it—can be realistically achieved on flexible devices. Pryds emphasizes that “selecting an appropriate metal surface for membrane integration is crucial for enhancing adhesion and ensuring structural integrity of the membranes.”
Toward real-world applications
The potential applications of this breakthrough are wide-ranging. The ability to strain-engineer oxides on flexible substrates could lead to improved flexible electronics, wearable medical sensors, foldable displays, and energy-harvesting devices. “Our demonstrated approach provides a robust framework for producing large-area, high-quality, freestanding oxide membranes with exceptional structural integrity and controllable strain,” says Park.
By tuning how oxides behave under strain, researchers could unlock new functionalities, such as adjustable magnetic states, meaning their magnetism can be strengthened, weakened, or switched on demand, tuneable conductivity that changes how easily electricity flows, or enhanced catalytic activity, where the material more efficiently speeds up chemical reactions. These could be applied not only in consumer electronics but also in advanced energy systems, memory technologies, and neuromorphic computing inspired by the brain.
Looking ahead
The team sees this work as just the beginning. One key future direction is scaling up the process to create larger, defect-free membranes — an essential step for industrial applications. They are also interested in stacking and twisting different oxide layers to build more complex structures with novel properties. “Our future research focuses on developing large-area, defect-free membranes, fabricating complex heterostructures through stacking and twisting, and exploring emergent physical phenomena,” says Pryds.
Ultimately, as wearable and flexible technologies become more central to everyday life, the ability to reliably integrate advanced oxides onto bendable supports could prove transformative. By demonstrating how to overcome one of the key hurdles—adhesion—the study from Denmark lays a foundation for turning the unique capabilities of oxides into practical devices.
Reference: E. Brand et al., Strain Engineering of Complex Oxide Membranes on Flexible Metallic Support, Advanced Physics Research (2025), DOI: 10.1002/apxr.202500075
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