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Benefits and Applications of Self-Healing Materials

Self-Healing Materials

Chemicals | Jul, 2024

Self-healing materials are an innovative class of substances designed to automatically repair damage without the need for any external intervention. Inspired by biological systems like human skin, these materials can mend themselves when they experience wear and tear. This ability to self-heal allows these materials to extend their lifespan and maintain their structural integrity, making them highly valuable for a variety of applications.

There are two main types of self-healing mechanisms. Intrinsic self-healing materials possess inherent properties that allow them to heal through reversible chemical bonds or physical interactions. On the other hand, extrinsic self-healing materials contain embedded healing agents, such as microcapsules or vascular networks, which release a repair substance when damage occurs. The benefits of self-healing materials are significant. They can extend the lifespan of products, reduce maintenance costs, and enhance the safety and reliability of structures and components. However, there are still challenges to overcome, such as developing materials that perform reliably under diverse conditions, creating cost-effective production methods, and optimizing the balance between self-healing capabilities and other essential properties like strength and flexibility.

According to TechSci Research Report “Self-Healing Materials Market– Global Industry Size, Share, Trends, Opportunity, and Forecast, Segmented By Form (Extrinsic and Intrinsic),By Material Type (Polymer, Concrete, Coatings, Others) By End Use (Building & Construction, Mobile Devices, Transportation, Others), By Region and By Competition, 2019-2029F” Global Self-Healing Materials Market was valued at USD 1642.34 Million in 2023 and is anticipated to project impressive growth in the forecast period with a CAGR of 9.16% through 2029. This growth is driven by advancements in material science and increasing applications across various industries. Self-healing materials are designed to autonomously repair damage caused by mechanical wear, environmental factors, or other external stimuli. This technology offers advantages such as prolonged product lifespan, reduced maintenance costs, and enhanced durability, making it increasingly sought after in sectors like automotive, electronics, construction, and healthcare.


Let us dive deep in the science and business favorability of these materials and how sustainable they are compared to their competitors.

Understanding the Science Behind Self-Healing Materials

The science behind self-healing materials is truly fascinating, combining advanced chemistry and smart engineering to create substances that can fix themselves when damaged. Intrinsic self-healing materials have special bonds and interactions, like hydrogen bonding, that allow them to mend breaks and restore their structure naturally. Extrinsic self-healing materials take a different approach by embedding tiny capsules, hollow fibers, or networks filled with healing agents. When these materials get damaged, the capsules or fibers release the healing agents, which then react, often through polymerization or mineral precipitation, to fill in the cracks and repair the damage.

In metals, shape-memory alloys can return to their original form when heated, effectively "healing" any deformations. For ceramics and concrete, self-healing might involve high-temperature reactions or even the use of bacteria that produce minerals to seal cracks. The success of these self-healing processes depends on precise material design and a deep understanding of the chemical reactions and physical processes at play. This cutting-edge technology promises to revolutionize how we build and maintain everything from everyday products to critical infrastructure.

Benefits of Self-Healing Materials: Reason For Their Popularity

Self-healing materials are shaking up various industries with their amazing, self-repairing capabilities. And why not? Imagine products that can fix themselves when damaged – that's the magic of self-healing materials! They offer a host of benefits that are hard to ignore.

·        Reduced Maintenance Costs

Since self-healing materials can repair themselves when damaged, the frequency of required repair drops dramatically. With the reduction in the need for manual repairs, businesses can save significantly on labor costs. Technicians and maintenance crews spend less time fixing issues, allowing companies to allocate these human resources more efficiently. In addition, products and components made from self-healing materials last longer due to their ability to fix themselves. With fewer repairs needed, there is also a reduced need for keeping a large inventory of spare parts. This not only cuts costs related to storage and inventory management but also minimizes the capital tied up in unused parts.

·        Improved Safety

With the ability to maintain its structural integrity through self-repair, these materials ensure that buildings, bridges, and other infrastructure remain sound and secure. In addition, by addressing damage early, self-healing materials reduce the likelihood of sudden, catastrophic failures. This is especially important in applications where material failure could result in significant harm, such as in aircraft, medical devices, and heavy machinery. To the benefit, self-healing materials reduce the dependence on human inspections and repairs, minimizing the risk of human error.

·        Increased Efficiency

Self-healing materials offer substantial benefits in terms of increased efficiency across various applications and industries. Products and components made from self-healing materials have a longer lifespan due to their ability to self-repair. This longevity reduces the frequency of replacements and downtime associated with equipment failure, thereby improving overall efficiency in terms of resource utilization and lifecycle management. Hence, rather than diverting resources towards reactive maintenance and emergency repairs, companies can focus on proactive strategies and operational improvements that enhance efficiency and productivity.

·        Environmental Sustainability

Self-healing materials offer significant benefits in terms of environmental sustainability, making them a promising innovation for industries aiming to reduce their ecological footprint. By minimizing the need for replacements and repairs, self-healing materials decrease the amount of waste generated during the manufacturing, use, and disposal phases. The extended lifespan and reduced maintenance requirements of self-healing materials and its ability to optimize manufacturing processes tend to contribute to energy savings throughout their lifecycle.

Beyond Breakdowns: Advancing with Self-Repairing Materials

Self-healing materials have become increasingly significant in diverse applications, including biomaterials and protective coatings. Over the past two decades, advancements in material science have progressed from research and development to the production of practical self-healing materials. Major players in the global market have innovated self-healing materials featuring repeated healing mechanisms. Among these innovations, self-healing polymers, a type of functional polymer, exhibit the ability to autonomously repair scratches, cracks, and other mechanical damages.

·        Scratched Surfaces

In the event of a scratch on a self-healing material, it has the capability to close or fill the scratch, effectively restoring its surface to its original state as if the damage had never occurred. This technology finds practical application in sectors such as automotive coatings and paints, where scratches traditionally necessitate extensive repainting of the affected area or even the entire vehicle. Similarly, self-healing materials are also being integrated into mobile phones, where certain models now feature these advanced materials to maintain scratch-free screens and cases over time.

·        Cracks

A vast majority of materials and components lose their integrity or functionality upon cracking, often necessitating immediate replacement. Self-healing materials offer the potential to significantly prolong their operational lifespan. This capability is particularly advantageous in critical applications such as aircraft wings, asphalt pavements, and construction elements, where inspections and repairs are costly and labor-intensive endeavors.

·        Corrosion

Damage to the surface of paints, coatings, or protective layers on metallic materials can potentially initiate corrosion. This issue can be mitigated if the protective layer possesses the ability to self-repair promptly, thereby re-establishing isolation of the metal substrate from external elements and effectively shielding it against corrosion. Such advanced paints and coatings are already available in today's market and hold promise for substantial advancements within the industry in the years ahead.

Sectors/Industries Benefiting Through Self-Healing Materials

Over the years, material advancement has been highly important in shaping the development of infrastructure and industries as an entirety, making it relevantly important in the progress of Material Science and Material Processing. Since the advent of self-healing materials, number of industries have strived towards reaping the benefits of the technology:

Aerospace and Aviation Industry

Aerospace sector falls under one of those categories where its components are subjected to extreme conditions and potential impact damage, like aircrafts. Presently, in contemporary aircraft structures, fiber-reinforced composites (FRCs) are commonly employed, where low-velocity impacts can induce micro-cracks and interfacial debonding. These issues are effectively addressed by integrating self-healing composites. For instance, glass fiber-reinforced epoxy laminates embedded with microcapsules exhibit extrinsic self-healing capabilities, reversing damage from impact-induced matrix microcracks and significantly mitigating structural degradation over time. FRCs traditionally struggle to maintain structural integrity during prolonged service life, whereas self-healing materials like epoxy-matrix composites with embedded microcapsules offer a modern solution. These materials counter fatigue cracks induced by cyclic mechanical and structural loads, reducing crack propagation rates by more than 80% and thereby extending operational lifespan substantially. Moreover, these "smart" materials are lighter than conventional counterparts, contributing to overall component lightweighting efforts.

Real Life Instance:

Over the past few years, Carbon Fiber Reinforced Polymer (CFRP) composites have become a staple material for aerospace and wind energy equipment due to their compact size, excellent durability, and corrosion-resistant properties. Similarly, Magnesium composites are employed in a range of applications, including engine assemblies for aerospace vehicles, braking elements, and motion axles. In the F16 aircraft, aluminum entryways have been substituted with magnesium composites reinforced with silicon carbide (SiC) particles, thereby improving fatigue life.

Construction

Self-healing materials offer several promising applications within the construction industry, addressing durability, maintenance, and sustainability challenges. Self-healing concrete is a notable application where microorganisms or encapsulated healing agents are embedded within the concrete mix. These agents react when cracks form, sealing them and preventing water ingress, which can lead to corrosion of reinforcement. Similarly, self-healing mixes are designed with rejuvenating agents that flow into cracks under temperature changes or traffic loads, preventing the formation of potholes and extending the service life of roads. This approach not only lowers maintenance costs but also minimizes disruptions to traffic flow. Additionally, self-healing coatings applied to steel structures and building facades repair minor damages autonomously, ensuring long-term aesthetic appeal and corrosion resistance. These coatings react to environmental factors, effectively maintaining their protective properties over time.

Real Life Instance:

Schlumberger, a leading multinational technology company, has already demonstrated its interest and current involvement in cutting edge materials and construction technologies. The company recognizes the need of self-healing concrete, a revolutionary concrete type, possessing the ability to repair cracks caused by wear, tear, or environmental factors. Also, October 2023 saw the launch of COASTALUME with U.S. STEEL, a specifically designed material to be able to withstand coastal environment. It is widely known in industrial scenarios to combine self-healing characteristics and strengths of U.S. Steel’s GALVALUME and DuPont's Tedlar PVF film barrier, with the ability to withstand saltwater corrosion, cracking, and UV damage.

Electronics

Numerous studies and practicalities have been conducted on contemporary self-healing polymers and their applications. Primarily, the research has been focusing on mechanical properties and durability for electronic applications. Though the field remains majorly unexplored due to complexities involved, some examples have proved self-healing materials’ worth. For example, Nissan Motor and Bayer Corporates announced the wide commercialization of self-healing clear coat paint to protect vehicle surfaces. Note that the wider adoption of advanced intrinsic self-healing polymers still faces challenges such as difficulties in scaling up complex chemistries, lower robustness than that of conventional materials, and performance degradation at extreme temperatures. On the contrary, Self-healing materials are particularly valuable in flexible and wearable electronics, where durability and robustness are essential. Also, Self-healing materials are being explored for use in battery electrodes and electrolytes. These materials can mitigate electrode degradation and enhance battery cycling stability by repairing microcracks that develop during charge-discharge cycles.

Real-Life Instance:

Thanks to R&D, researchers have developed numerous techniques and materials that could make possible a variety of self-healing electronic components and structural parts. Scientists at Technion – Israel Institute of Technology have developed eco-friendly nanocrystal semiconductors with self-healing capabilities. Their research, recently published in Advanced Functional Materials, details how a class of materials known as double perovskites exhibit self-healing properties when damaged by electron beam radiation. Perovskites, first discovered in 1839, have recently attracted significant scientific interest due to their unique electro-optical properties, which enable efficient energy conversion at a low production cost. Notably, lead-based perovskites have been a focal point in the development of highly efficient solar cells.

Bio-Medical Industry

Self-healing polymeric materials, designed to autonomously repair damage induced by external stimuli, are at the forefront of sustainable materials research. Their capability to preserve product quality and functionality, while extending the lifespan of products, plays a pivotal role in alleviating the environmental impact of plastic waste. Historically, early research on the development of self-healing materials has concentrated on extrinsic self-healing systems, characterized by the incorporation of embedded healing agents. Self-healing materials are currently utilized in numerous implanted devices, wound dressings, and drug delivery systems. Among the most exciting areas of research today is the exploration of hydrogels, a broad category of water-based, biocompatible materials that can be engineered to possess self-healing properties. Soft contact lenses represent a notable example of hydrogel application in biomedical contexts; however, researchers are continuously discovering additional potential uses for these versatile materials.

Real Life Instances:

Self-healing (bio)materials are pivotal in advancing towards a circular economy in healthcare. Each year, numerous studies report on the development of self-healing materials (SHMs) and their practical applications. Recently, a self-healable photochromic polymeric matrix was designed using a biomass-derived elastomer, incorporating multiple hydrogen bonds (UPy groups) and covalent cross-linking. The elastomer's soft characteristics and dynamic nature contributed to its healing capability and greater extensibility, while the covalent cross-linking facilitated the reassociation of damaged hydrogen bonds. The synthesized elastomer demonstrated excellent toughness (42.76 MJ m−3) and high extensibility (>2600%). Additionally, it exhibited robust self-healing properties, achieving full damage repair, with a toughness of approximately 24.1 MJ m−3 and impressive mechanical recovery (elongation of 1900%) after healing at 60 °C for 24 hours.

The Vision: What Future Holds For Self-Healing Materials

Since the advent of industrial revolution, continuous innovations in material science has helped shape work and social lives. However, how these materials are used and reused is critical considering the face of complex global challenges such as sustainable development, climate change, etc.

Significant Potential Opportunities in Sectors

·        Efficient Operation in Harsh Environments

Self-healing materials are particularly valuable in scenarios where products need to last a long time or operate in challenging environments. This includes buildings and bridges, wind turbines, and deep-sea cabling within the energy sector. They're also used in satellites for deep space exploration and even within the human body, such as with medical implants and prosthetics. These materials reduce maintenance costs and enhance the reliability of critical infrastructure. Moreover, their ability to autonomously repair damage ensures continuous performance and longevity, making them indispensable in high-stakes applications.

·        Enhanced Aesthetic Resilience

Wear and tear is considered one significant driver for why products tend to be prematurely replaced by consumers. Products that are able to resist scratches and are able to return to new condition would notably mitigate the issue. Currently, the focus is primarily on the automotive sector, but the technology holds promise for broader applications. For instance, municipal councils could use it to maintain the quality of building facades and public furniture, enhancing the appeal of social spaces. The greatest potential impact lies in consumer electronics, where it could extend the service life of mobile phones, iPads, and household appliances, contributing to sustainability efforts by reducing electronic waste.

·        Facilitating Assembly and Disassembly

The disassembly and reassembly of products are crucial for their longevity, yet this process frequently leads to component damage that limits their salvageability. Self-healing rubbers, capable of repairing cuts even up to 18 hours after they occur, offer extended material functionality that could significantly simplify product disassembly and reassembly. For example, envision a product with a completely sealed casing that can be cut and seamlessly re-bonded. This innovation has the potential to reduce the complexity of parts and components required for manufacturing, thereby optimizing production efficiency and resource utilization.

Summing Up

In conclusion, self-healing materials represent a transformative innovation poised to reshape various industries by enabling automatic repair of damage without external intervention. Inspired by biological systems like human skin, these materials possess the remarkable ability to mend themselves, thereby extending product lifespan and ensuring structural integrity. There are two primary mechanisms through which self-healing materials operate: intrinsic materials utilize reversible chemical bonds or physical interactions for healing, while extrinsic materials incorporate embedded healing agents that release repair substances upon damage.

The benefits of self-healing materials are substantial, encompassing reduced maintenance costs, enhanced safety and reliability of structures, and prolonged product longevity. However, challenges remain in optimizing their performance under diverse conditions, scaling production economically, and balancing self-healing properties with essential material attributes such as strength and flexibility.

The scientific exploration and business viability of self-healing materials underscore their potential to revolutionize industries across the globe. By understanding their intricate chemistry and engineering, these materials promise to enhance efficiency, sustainability, and durability in applications ranging from aerospace and construction to electronics and biomedical devices. As research and development continue to advance, self-healing materials are poised to play a pivotal role in shaping a more resilient and sustainable future.

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