Minireview on Self-Healing Polymers: Versatility, Application, and Prospects

Rahman, Md. Wasikur; Shefa, Nawrin Rahman

doi:https://doi.org/10.1155/2021/7848088

Advances in Polymer Technology

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Abstract Introduction Conclusion Conflicts of Interest Acknowledgments References Copyright Related Articles

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Advances in Self-Healing Polymers

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Review Article | Open Access

Volume 2021 | Article ID 7848088 | https://doi.org/10.1155/2021/7848088

Minireview on Self-Healing Polymers: Versatility, Application, and Prospects

Md. Wasikur Rahman¹and Nawrin Rahman Shefa¹

Academic Editor: Gyorgy Szekely

Received25 Jun 2021

Revised15 Aug 2021

Accepted22 Aug 2021

Published17 Sept 2021

Abstract

Nature is blessed with self-healing properties. Mimicking nature is a traditional practice to innovate new classes of materials for researchers. In this practice, researchers made a revolutionary approach to innovate self-healing polymer (SHP) that can be used to treat damage-related losses. Different SHPs with various properties have been developed for a wide range of applications. SHPs unlocked the key to the taste of real life through their application and versatility in the sectors close to our day-by-day life of this age and the near future. In this study, we reviewed the scopes and prospects of the application of SHPs owing to different properties. Varieties of amazing properties made SHPs fit in different sectors such as construction, paint and coat, electronics, healthcare, textile, and automotive and aerospace. Similarly, due to having suitable functionality, SHPs can also be used in different industries. Therefore, it is high time to generalize the production of SHPs by suitable research and make sure the easy application for the welfare of human civilization and other living creatures.

1. Introduction

Self-healing is an innate feature of nature. Nowadays, researchers are concentrating on the development of nature-inspired materials with amazing properties [1]. Self-healing materials are not part of science fiction anymore. They crossed the boundary between fiction and reality. Self-healing is such a property that is raising a storm in this field. Its property inspired by nature has been pursued in biomimetic designs and healing systems; the damaged structures are repaired by the strategic transportation of healed materials and the polymerization healing process of the injured area [2]. Healing means filling of discontinuity in materials with other materials that differ from the base materials. In general, the properties of healing materials are dissimilar from the matrix. Mostly, self-healing is aimed at getting again surface continuity of materials with concurrent repairing of significant physical and mechanical properties [3]. Self-healing polymers are synthetically developed polymers with the aptitude to convert physical energy into chemical/physical or both responses to repair damage autonomously or nonautonomously with external intervention without any human involvement to recover the initial properties, more particularly mechanical properties [4–7].

There is a range of potentials for SHPs. Various natural polymer composites and nanocomposites also show self-healing behavior [8, 9]. Cell walls of higher plant bioadhesives develop by using borate to crosslink neighboring protein chains, hyperbranched polyester, and soy polysaccharides [10]; intrinsically, microporous poly(ether-ether-ketone) membranes with a structured surface of natural honeycomb result in improved performance [11]; biologically soft tissue developing processes inspired nanocomposite hydrogel for wound and hemostatic healing [12]; photosynthesis of plants inspired singlet oxygen generation [13] and CO₂ fixation by a photocarboxylation process [14]. The generations and classification of SHP are shown in Figure 1. The polymers that provide self-healing features are of two types: (a) intrinsic SHP and (b) extrinsic SHP. Intrinsic SHPs are innate reversibility-based compounds that can heal the damage by increasing the mobility of polymeric chains temporarily [15]. On the other hand, extrinsic type self-healing is triggered by the incorporation of exogenous agents which then help for self-healing from embedded microcapsules on cracking [16]. Further extrinsic self-healing is of two types (i) capsule-based and (ii) vascular-based. In the capsule-based extrinsic SHP, external healing agents are encapsulated in a microcapsule. Cracking causes damage to these microcapsules. Then, healing agents get released to the crack where a polymerizing reaction takes place and the crack got healed. In contrast, vascular-based SHP uses a network of hollow fiber connected into a polymer matrix. These hollow tubes contain healing agents; when they break in the damage position, self-healing occurs. Single-time healing capacity is a major drawback of capsule-based self-healing. Another big challenge for researchers is dispersing the vascular network which contains healing agents in the polymer-based matrix to fabricate self-healing [17]. On the other hand, the intrinsic type of SHPs is generally developed based on noncovalent bonds or dynamic covalent bonds [18]. Some noncovalent bonds are π-π stacking, ligand-metal bond, hydrogen bond, or host-guest interaction stacking among other techniques [19–27]. Examples of some covalent interactions are the Diels-Alder reaction, dynamic urea bond, radical exchange, and transesterification, to name a few [27–32].

According to the life cycle and self-healing properties, SHPs can be divided into four generations. 1^st generation SHPs are consisting of only a single-cycle capsule-based extrinsic SHP. 2^nd generation SHPs came with an intrinsic self-healing mechanism based on reversible chemical bonds to eliminate single-cycle healing problems. However, mechanical and self-healing properties are suppressed. 3^rd generation consists of vascular network-based intrinsic healing which showed a way to formulate mechanically stronger SHP. Right now, we are in the fast-growing 4^th generation of SHP based on a combined healing mechanism aiming at the elimination of previous limitations [33]. SHPs get updated generation by generation making their bridge to real field of application in the sectors related to both daily commodities and advanced needs. At present, SHPs are receiving a resurrection of interest, as there is a rising demand to integrate molecular level functionality empowering the damage repair capability, impart reprocess ability, or enable extended lifetimes in polymeric materials [34]. In the year 2020, the COVID-19 outbreak stunned the whole world. It freezes the world like a spell. Nevertheless, researchers came forward with even more approaches and continued their research. In 2020, the number of the published article on SHP was the highest according to Google Scholar in recent years as shown in Figure 2. The trend of publications is increasing proportionally over years with 147 publications in 2011, whereas 899 in 2020. That is enough to understand the level of interest of the researchers and the urgency to take this out of the lab to real field application.

2. Application of SHPs in Different Sectors

Investigation on self-healing started in 1970 due to the healing of polymer cracks [36, 37]. Polymer with self-healing features is newly developed advanced materials with extended lifetimes which can mend themselves when they got damaged without the requirement of detection or repair by manual interference of any kind [38]. The SHP is used to decrease the damage and further chance of material failure along with the long life cycle of polymers and polymer composites [4]. The growth of polymer with self-healing ability is nothing but the advanced modification of the common polymers by incorporating the self-healing features. Application of SHPs covers the field like coatings or paints, sensors, soft robotics, 3D printing, biomaterials, textile, and automobile. Similarly, their potentiality of real-world applications is also analyzed [39].

Now, SHPs are coming out of the lab to real-world applications [8]. It can be used to reduce the cost of maintenance, prolong durability, assure safety, and fabricate advanced materials. In recent years, great emphasis has been given to self-healing materials for real-life engineering approaches [40]. The presence of a material is determined by its functionality in any system. Functionality is a combination of instance properties like electrical and thermal conductivity, color, brightness, adhesion, reflectivity, and hydrophobicity, which are displayed in Table 1. Varieties of SHPs are developing with desired properties to improve functionality for the application in different fields. The enormous versatility of SHPs offers possibilities to apply them in different sectors. The real-world demands, as well as the related implementations, will determine the success of SHPs [34]. Here, we will discuss the application of SHP in different fields with numerous functions.

2.1. Construction Materials

Multiple cycles of self-healing are a matter of concern in the case of the performance of structures made of concrete. Researchers used a mixture of polyvinyl alcohol fibers, steel, superabsorbent polymer, and biochar containing immobilized bacteria to investigate crack healing, recovery of mechanical property, and permeability after multiple cycles of damage. Precipitation of microbial calcite by immobilized bacteria containing biochar combined with a superabsorbent polymer and fiber found superior healing capability for a wider crack surface (>600 μm) and microlevel internal cracks comparing autogenous mechanism and concrete mixed with superabsorbent polymer and fiber [55].

In an alternative investigation, the speedy self-sealing can be improved by mixing composites of sulfur polymer combining superabsorbent polymer with Portland cement and calcium sulfoaluminate composed binary cement. The healing capabilities of the superabsorbent polymer as an SHP are very fast, which can heal the damage within 30 mins. The superabsorbent polymer particles taped up and connected the two crack surfaces quickly by swelling up the absorbing water. This self-healing is promoted by nucleation and growing of hydrated yields around the nucleus. A better rapid self-healing increased proportionally with an increasing calcium sulfoaluminate ratio [56].

Polymer-cement composites were formulated by mixing poly(ethylene-co-acrylic acid) zinc salt powder, bisphenol A diglycidyl ether (BPA), two base cement H, and thermal shock-resistant cement (TSRC). Polymer-cement composites maintained their self-healing property for thirty days at 300°C. These cement composite materials showed a compressive strength of more than 1000 psi after a day, just as the requirement of wellbore applications. These advanced polymer-cement composites are mechanically stable, ductile, and self-healable. It is expected that conventional wellbore cement could be replaced by polymer cement which can be applied for the extraction of geothermal and fossil energy [57].

2.2. Paint and Coat

The addition of epoxy resins to a painting enhances the colors and gives the piece a glossy, clean finish. The development of epoxy resin systems which are mechanically tough yet easily healable and recyclable is highly desirable but remains considerably difficult. These innovative epoxy resins based on plant oils were successfully produced using dithiol modified boronic ester and completely epoxidized plant oils by a “thiol-epoxy” click reaction that is thermally triggered. The maximum tensile strength of the plant oil-based epoxy resins was 43.2 MPa, and the maximum was 25% elongation at break. At normal temperature, the self-healing effectiveness of vegetable oil-based epoxy resins might be 90% in a day. Furthermore, even after 9 rounds of reprocessing, the mechanical qualities of resins that have been recycled remained at 80% of those of the original resins [58]. These recent developments of epoxy resin-based SHPs with desired toughness added a new height to the potential of using SHPs even for critical engineering construction material.

By combining an epidermis-like hierarchical multiple-layered structure with mechanically stable graphene oxide, the fundamental dilemma of achieving stiffness with self-healing can be overcome. This type of smartly ordered system of coating can provide long-term stability with an effective healing ability. Among all self-healing polymeric films, it has the greatest stiffness ( GPa) and hardness ( GPa), which is similar to the enamel of the tooth. This hybrid layer-by-layer assemble technique was demonstrated by depositing a thin quasilinear layer-by-layer (l-LBL) film with graphene oxide (GO) nanosheets as 2D fillers on top of a thick exponential layer-by-layer (e-LBL) counterpart to imitate the hierarchical stratified structure of the epidermis (Figure 3). The exponential layer-by-layer part is generally made of poly(vinyl alcohol)/tannic acid [59].

Epoxy monomer as a self-healing agent and dodecyl amine as a corrosion inhibiting agent is enclosed in a single coated layer providing self-directed corrosion inhibition which helps to develop a smart coating around the metal. Titania (TiO₂) nanotubes with an average size of 0.02 μm were impregnated with dodecylamine and epoxy monomer where titania nanotubes interspersed into the epoxy matrix that can be applied on steel. The damaged area was nearly healed within 96 hrs, and the reduction in the corrosion rate is observed for epoxy and healing additives-coated steel even after emerging in saline water after 5 days [50]. Microcapsules responsive to UV dispersed coating are formulated for repairing damage in space. UV-responsive microcapsules are made by UV-triggered polymerization of Pickering emulsions and then embedded in silicon resin matrices. The inner polymeric shell of microcapsules is quickly degraded by the outer pure TiO₂ shell under UV radiation. Due to the dual release method, UV-responsive microcapsules can discharge more agents even more effectively than commonly employed damage healing systems. Furthermore, the harmful effects of UV radiation in space can be transformed into beneficial ones using this UV-responsive microcapsule. This property makes the material suitable for use in aerospace coatings. Additionally, in a very recent study, researchers described a strategy for creating a strong and low-temperature mendable supramolecular system of polypropylene glycol- (PPG-) polydimethylsiloxane- (PDMS-) Zn by integrating both high dynamic crosslink bonds and low crosslink density into polyurea networks. The resulting PPG-PDMS-Zn-0.5 polymer showed 0.98 MPa tensile strength and showed 97% self-healing efficiency at −20°C. This type of supramolecular polymers with unique features can also be applied in Antarctic pole exploration antifrosting and anti-icing paints [48].

2.3. Sensors, Electrical, and Electronics

A conductive hydrogel with self-healing ability and excellent biocompatibility was prepared based on polypyrrole, oxidized sodium alginate, and aminated gelatin as reported in 2019 (Figure 4). The cracked hydrogel shows self-healing capabilities within 40 min due to its reversible Schiff base structure. The hydrogel was shown to work as healable wires to reconnect disconnected circuits or as a single circuit component to light LED bulbs. Furthermore, polypyrrole hydrogel can be used in mechanical sensors because of its adjustable resistance and good flexibility under compression and bending motion. Therefore, it can be potential material in biocompatible soft electronics devices [60]. The first self-powered, self-healable, and wearable ultraviolet photodetector was made based on agarose/poly(vinyl alcohol) double-network hydrogels which are mechanically strong and can heal multiple cycle damages. The photodetector can restore 90% of primary skills after five healing cycles with the addition of a double-network hydrogel substrate, and each rapid healing time is reduced to only 10 seconds [61]. It can expand the scope of soft robotics and prosthetics with sensors.

Additionally, a highly water-unresponsive self-healing elastomer is polybutadiene-based poly(urea-urethane) (PBPUU) which is highly stretchable (1100%) and mechanically strong (≈6.5 MPa). Without support from an external source, this elastomer shows great self-healing efficiency (>80% after ≈1 day) in a wet environment (e.g., underwater). The polymer’s self-healing efficiency is also good enough for surface scratches in the air. Furthermore, when it functioned in salty seawater or an extremely wet environment, the healing competence directs to the rejection due to the damages in the structure [62]. It is reported that an electronic skin (e-skin) made of PBPUU and nanostructured conductive fillers has an excellent performance in various pH, temperature, and pressure sensing in both atmospheric and underwater conditions. Similarly, silver nanowire-based electrodes were used in the multilayered e-skin (Figure 5) to extend the heater’s connection to the edge. Damage detecting neuron-like complex structure was created using a nanostructured network of conductive carbon black dispersed in the PBPUU for determining and mapping local damage. The sensing layer was made of single-walled carbon nanotubes. The repair process led to the healing of a superficial crack that can be achieved in 30 seconds rather than 24 hrs. On the other hand, healing of extensive damage required 5 min [63].

A new type of self-healing microcapsule has been developed using aqueous conductive core materials that are low-cost, nontoxic, and nonpolluting. An in situ polymerization process was used to create these microcapsules with a melamine-formaldehyde resin shell and an aqueous solution core. During the long-term operation of the gadget, it is beneficial to minimize the temperature of the circuit itself. Furthermore, these microcapsules are capable of withstanding pressures of up to 14 N. These microcapsules had an electrical conductivity of 6.232 ms cm^-1. We believe that these self-healing microcapsules will have a great variety of applications in the long-term development of electronics [64].

2.4. Healthcare

Researchers developed thermosensitive and SHP network hydrogel based on polyacrylamide/gelatin (PG) hydrogel which has a match with native vocal fold tissue both physically and functionally as shown in Figure 6. The PG hydrogel has a minimum reaction with the foreign body when implanted. It also creates strong resistance in a dehydrated environment and lasts for 40 days maintaining 60% humidity. PG hydrogel showed strong adhesion when attached with tissues of the vocal fold. The synthetic vocal fold tissue of PG hydrogel named ex vivo canine can be implanted for the recovery of the function [65].

Based on the Biginelli reaction, a self-healing hydrogel with antioxidant characteristics has been prepared to contain monomer phenylboronic acid (PBA) and 3,4-dihydropyrimidin-2(1H)-one (DHPM) groups. Radical polymerization of monomer PBA-DHPM with poly(ethylene glycol methyl ether) methacrylate produced a water-soluble copolymer. The copolymer is rapidly crosslinked with poly(vinyl alcohol) by borate ester bonds generating a hydrogel with self-healing, noncytotoxic, and antioxidant properties. The implant ability of this hydrogel has been tested by injecting the hydrogel under the skin of a mouse model which did not show any augmentative reaction [66]. Similarly, an injectable self-healing adhesive is made up by interacting polyphenol compound tannic acid with eight-arm poly(ethylene glycol), and end-capping occurred with succinimide glutarate active ester. The poly(ethylene glycol)/tannic acid adhesive can repetitively attach stiffly with porcine tissues. It can also be used for closing the coronary artery under a huge incision tension and can tolerate a load of up to 2 kg. Due to the special features like instant self-healing, antiswelling, shear-thinning, injectability, and strong long-lasting adhesion to effortless outstanding healing effects, poly(ethylene glycol)/tannic acid adhesive may offer an alternative for conventional surgical treatment methods [66].

Besides, poly(vinyl alcohol)-based self-healing hydrogels have a significant effect on healthcare functionalities. In fact, wound healing dressing is desired to be compatible with the skin, endowing good therapeutic properties and enough strength to protect the wounded area safe from the outside environment. Recently, salep/poly(vinyl alcohol)-based ultratough double-network hydrogel has been developed. H-bonds and azomethine crosslinking between oxidized and ethylene diamine-modified salep chains attain self-healing. The resulting hydrogel has great mechanical properties with a maximum of 14 kPa Young’s modulus, 90 kJ m^-3 fracture energy, 400 kPa compressive stress, 48 N m^-1 adhesive strength, and A375 cells having viability of over 80% making it ideal for therapeutic purposes. The macroscopic evaluation demonstrated that fusing the two networks into a single system in green medium Arnebia extract and silver nanoparticles combined resulted in 100% healing in 21 days [67].

2.5. Textile

A polyester fabric coated with crosslinkable polymer consisted of both hydrophilic and oleophilic functional groups having special features. To prepare coating solution, glycerol propoxylate triglycidyl ether was mixed with octadecylamine in ethanol through epoxide-amino coupling reaction. The solution becomes translucent after the completion of the reaction. After treatment with crosslinked polymer, the fabric exhibited a contact angle of 0° for water. Therefore, water adsorbed completely into the fabric within 1 second. The oil absorption yield of the dry and prewetted fabrics is shown in Figure 7. In addition, the oil fluids have the potential to spread fully to the water-wetted fabric within 60 seconds. The most interesting matter is superoleophilicity underwater. It is also self-healable and chemical damage-resistant. The high moisture resistance caused oil recovery very steady. Such rare superamphiphilicity prospects innovative features to apply in diverse fields [68].

(a)

(b)

The use of SHP on various textile products enhances the efficiency and efficacy of textile goods. Similarly, the use of methyl vinyl silicon rubber with inorganic silsesquioxane on rubber gloves increases the life span of the gloves. To understand the effect of textile reinforcement, three unwoven fabrics of different raw materials and the same structure (polyamide, cotton-polyamide, and cotton) were taken, and it was found that the fabric treated with textile reinforcement shows higher stability. It has also been tested that the composites of methyl vinyl silicon rubber and silsesquioxanes can be upgraded with the addition of textile reinforcement, and these types of composites provide good chemical permeation resistance that makes this material suitable for use in barrier protection [69]. For the preparation of a self-healing electromagnetic interference shielding fabric, carbon nanotube-poly(2-hydroxyethyl methacrylate) is aligned on a nonwoven fabric with magnetic field electrospinning and cross-stacking fabric layers that are aligned as shown in Figure 8. Because of the materials’ unique aligned carbon nanotube stacking and porous structure, they can successfully absorb electromagnetic interference even at extremely low carbon nanotube loading levels (0.17 weight percent). Additionally, the host-guest interaction between β-cyclodextrin and the adamantane moieties not only caused the fabric to automatically stick together but also caused it to self-heal scratches in 100 percent humidity. The electromagnetic interference shielding property reclaimed up to after healing [70].

2.6. Automotive and Aerospace

At the nanoscale level, conductivity mapping is achieved by a multifunctional newly developed fire retardant graphene/polyhedral oligomeric silsesquioxane epoxy resin via tunneling atomic force microscopy which can measure ultralow currents starting from 80 fA to 120 pA. This fire retardant graphene/polyhedral oligomeric silsesquioxane epoxy resin composite can be used in the aeronautic and aerospace sectors. The mechanical performance, thermal stability, electrical conduction, and fire resistance of graphene/polyhedral oligomeric silsesquioxane epoxy resin have been verified to understand the properties of this material [71]. A UV-responsive microcapsule-based system can be used for damage healing of spacecraft coatings [72]. Similarly, AA7475 is a high-strength alloy with self-healing properties generally used in the aerospace industry. Additionally, biobased polyurethane coatings are derived from vegetable oils with and without the integration of zinc microsize flakes as a corrosion inhibitor. Zinc-containing coatings deliver effective corrosion inhibition in AA7475, and it has been observed that the inhibiting capability of AA7475 notably got better with the amount of 7.5 weight% zinc microflakes in the coating [73].

Long-lasting tires and reduction of fuel consumption without sacrificing safety are a demand of the automobile industry. A self-healing tire was developed by styrene-butadiene rubber matrix and reclaimed tire waste as the sustainable filler. Furthermore, the addition of ground tire rubber to the matrix got better concurrently the rolling resistance, wet grip, and mending ability. In a recent study, the researcher found that styrene-butadiene rubber and “styrene-butadiene rubber/ground tire rubber” showed a 100% regaining of stiffness and relaxation dynamics as a result of cyclic deformation, leading to the formation of a heterogeneous rubber network. The magic triangle (Figure 9) of the tire can be overcome with these new materials [74].

2.7. Miscellaneous

Researchers reported that polymers of light molecular weight crosslinked together through dense hydrogen bonds which make them robust and self-healable, despite their very slow diffusion dynamics. The incorporation of thiourea in the crosslink is an important point because it irregularly forms a zigzag hydrogen-bonded arrangement that does not induce unwanted crystallization. The incorporation of a structural element for triggering the exchange of pairs of hydrogen bonds empowers the cracked portions to unite by compression [75]. Additionally, self-healable glass can be a potential material for cellphone screens and other delicate devices [76]. A molecularly designed photopolymerization-based additive was manufactured with self-healable elastomeric structures as reported in 2019. This photoelastomer 3D-printable ink incorporates both thiol and disulfide groups. At first, the thiol group reacts with photoplastomer to form thiol-ene photopolymerization, and then, disulfide metathesis reaction takes place which enables the self-healing properties. Projecting microstereolithography systems, researchers established rapid additive manufacturing techniques to produce self-healable structures with single or multimaterial. This self-healable structure can be used to produce multiphase composites, 3D soft actuators, and architectured electronics. The 3D actuator was designed and additively manufactured which was a nacre-like stiff-soft composite and able to lift a weight ten times of its weight. The actuator can reestablish the toughness to over 90% after rupture [77].

Due to the synergistic environmental stability of the polyimide membrane and polydimethylsiloxane/octadecylamine coating, a simple method for fabricating polyimide nanofibrous membranes with self-healing superhydrophobicity, remarkable separation efficiency towards a range of oil/water mixtures and water-in-oil emulsions, and desirable adaptability in harsh environments is developed. Because of these characteristics, the membrane is a prospective separation material for effective oil/water separation in a real-world setting [78].

Green chemistry is also practiced in the field of SHPs by developing green routes to synthesis and environment-friendly SHPs. Using CO₂ as a nontoxic and furfuryl amine as a renewable feedstock, a green method to synthesize biobased nonisocyanate polyurethane-urea Diels-Alder adduct (PUUa-DA) was reported (Figure 10) [79]. The crosslinked PUUa-DA had tensile stress of 18.5 MPa, a modulus of 151 MPa, and a 136% elongation at break. The self-healing response is provided by dynamic Diels-Alder bonds and H-bonds, which contribute to a 94 percent recovery in tensile strength after heating [79].

A composite of polymethacrylamide and carbon mimics the photosynthesis of plants, and carbon fixation from the atmosphere allows its growing, strengthening, and self-repairing. The substance utilized by the researchers, a gel matrix formed of an aminopropyl methacrylamide and glucose polymer, an enzyme called glucose oxidase, and chloroplasts becomes tougher as the carbon is incorporated. Under ambient CO₂ and light for 18 hrs, this system reaches a growth rate of 60 m³ h^-1 per chloroplast, thickening with a 3 kPa shear modulus. This polymer might be utilized in building, repair, or protective coatings in the future turning greenhouse gases into a carbon-based compound that self-reinforces [29].

3. Prospects

There are various sectors where SHP is now being used, for instance, self-healing coating of LG flex 2 cellphones, self-healing asphalt of Heijmans, scratch shield paint of Nissan, self-healing paint for airplanes of KLM-Air France, puncture SHPs for targets, and aerospace [80]. This is indicating that SHP not only is technology confined in the lab but also has wider practical applications. This technology has stepped out of the lab and is getting ready to jump into our daily life. The market size of the international self-healing materials was valued at USD 291.4 million in 2018, and it has been expected that the rising compound annual growth rate (CAGR) will be 46.1% in the time range of 2019 to 2025. The growth rate of the market size of the self-healing materials in the United States is shown in Figure 11. The driving factors of the rising market size of smart SHPs are the application of these materials in various industries and mending capabilities of damage caused by mechanical stress. Due to the escalation of demand for advanced and highly strong materials to enhance productivity and to reduce losses because of the damage of instruments, people are more likely to use SHP composites. Mainly automobile and electronic industries are tending to this type of composite materials. Additionally, the increasing application of SHPs in the paint and coating industry indicates the future demand in various industries [81].

A patent has been published from Apple by the US Patent and Trademark Office related to the application of SHP in a folding iDevice in January 2020. In that patent, they describe that they include a layer of SHP on the display of that device. The display cover layer may comprise a layer of elastomer to increase flexibility. Self-healing may be triggered by external application light, heat, electrical current, or other types of external incentives. While using an electronic device, the display screen can get scratched, but the application of SHP may fill the damage. A partnership between MIT and Lamborghini resulted in a stunning hypercar concept for the future self-healing electric sports car. The TerzoMillenio is a prototype car for a third-millennium vehicle. It is exceptionally capable of delivering high peak power along with regenerating kinetic energy by ensuring electric power release and generation [82]. Human limbs are designed with a critical layer-by-layer structure where soft tissue is attached to the rigid bone. Therefore, it is nearly impossible to construct human limbs artificially, and it is a big challenge for the scientist to develop a suitable technology for the production of human body parts [83]. Accepting that challenge, researchers have developed a technology that can produce a 3D printable new type of SHP combining furan and maleimide, and they believe that this new material can help in the production of more realistic human prosthetics [84]. Additionally, the self-healing asphalt can be used in the construction of a road with longer service life. Therefore, conventional asphalt can be replaced with this newly developed material. This material can repair damage (through a hybrid input-output system) caused by natural disasters or road accidents. They concluded that self-healable roads may decrease emissions by 16 percent and decrease costs by 32 percent compared with a conventional road over the service life [85].

Overall, the future of SHP depends on the ability to expand the service life of products, survivability in critical conditions, being economic, and ecological compatibility. Optimization of mechanical properties of building materials along with self-healing property can be used to build important structures due to having a long service life of SHP. Concealed faults are one of the key problems endangering the long-term stability of mechanically strong polymers which are widely used engineering materials. An SHP created by curing a readily available commercial epoxy monomer with a synthetic dynamic crosslinker may mend internal flaws completely numerous times while sustaining mechanically tough polymers’ structural stability during healing. This method has a lot of promise for industrial uses [86].

SHPs can be a solution to the problems in repairing damages such as flying aircraft, deep-water pipelines, underground structures, and machinery in high thermal conditions. The brand new technology of multilayer SHPs equipped with multisensor circuits can lighten up soft robotics and lead prosthetic organs with sense. Even SHPs with flexibility, nontoxicity, and biocompatibility can play a great role in developing artificial organs too. SHPs of such kind can also be used to develop smart fast healing wound dressing for critical wound management where regular wound dressings struggle or are unable to manage. Using SHP membranes can make filtration methods more efficient by making the process more continuous due to less maintenance. The new run of SHP along with the green chemistry is not only with biocompatible self-healing polymeric materials but also with the green route of synthesis giving a rise to our expectations to SHP for gifting a pollution-free future.

4. Conclusion

Considering the long-term stability, self-heal ability, and flexible nature, SHPs are the best composite material among the next-generation materials. This material can be used in many diverse environments with higher stability comparing conventional material. Therefore, using this composite material would be economic in industrial sectors. The progress of SHPs day by day makes this type of material worth using in every sector. The special features of newly developed SHPs reveal a new way to produce and apply advanced materials. Now, these new types of material enable us to produce various products with a longer lifetime and stability. The experiments to develop new SHPs and experiments on SHP composites incorporating different elements or compounds should be continued to get the best to apply in every sector and obtain more versatility of SHPs. Ensuring the availability of SHPs is a must to apply on large scale. This will not be possible through critical and expensive synthesis methods. Developing synthesis methods that are less critical, greener, and cost-friendly needs more attention from the researchers. The green synthesis route is important because we should not mess with nature, stay with it, and observe the pathways of nature more closely to get inspiration for developing amazing SHPs. At present, products are successfully being used in different sectors containing SHP. Although the development of SHPs has done much through advanced research, there is a lot of progressive research still to be done to take the SHPs in practical and industrial applications. Approaches to the industrial application of SHPs just have started, and it is time to fasten the seat belt and start the journey to the era of SHPs.

Conflicts of Interest

The authors declare no conflicts of interests.

Acknowledgments

This work acknowledges the technical support of MENTECH Labs of Jashore University of Science and Technology, Bangladesh.

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Copyright © 2021 Md. Wasikur Rahman and Nawrin Rahman Shefa. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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