Bioinspired Nanocomposites Research Articles

Bio-inspired nanocomposite by layer-by-layer coating of chitosan/hyaluronic acid multilayers on a hard nanocellulose-hydroxyapatite matrix

This study proposed a layer-by-layer technique on the hard CNCs/hydroxyapatite (HAP) matrix using biodegradable and biocompatible chitosan and hyaluronic acid (HA). Inspired by the mineralized collagen in human bone, the CNCs/HAP matrix was synthesized by a facile in situ HAP coating on the CNCs fibers. The chemical and crystalline structure of the CNCs/HAP matrix was investigated with FTIR, XRD, HRTEM, and SAED. The surface of the CNCs/HAP matrix was analyzed by AFM which showed a flat structure with a roughness of 23.12 nm, however, the surface roughness increased to 56.09 nm with the assembly of chitosan and HA. After the LBL assembly, the surface hydrophilicity of the CNCs/HAP films was improved. Moreover, the CNCs/HAP matrix showed enhanced mechanical property than pure CNCs matrix. Although there is compromise in the mechanical property after the LBL assembly, it is anticipated its bioaffinity and biocompatibility will increase with the incoporation of chitosan and HA.

Combination of PPy with three-dimensional rGO to construct bioinspired nanocomposite for NH3-sensing enhancement

For general nanoparticle-like gas-sensing materials, high dispersion, low agglomeration, and high active surface available for gas adsorption are highly desirable for achieving high sensing performance. Inspired from the distribution structure of olfactory cells of mice, this work describes a macroporous nanocomposite of polypyrrole/three-dimensional reduced graphene oxide (PPy/3D-rGO) with biomimetic structure for highly sensitive application. The PPy/3D-rGO nanocomposite was prepared via in-situ chemical polymerization of sensitive PPy nanoparticles on the pore wall of rGO with 3D architecture. The 3D-rGO, pre-prepared by a facile hydrothermal reduction method, serves as 3D skeleton to provide solid support for sensitive PPy nanoparticles attachment. The as-formed nanocomposite displays loose 3D morphology and the fine PPy nanoparticles with high dispersion and low agglomeration distribute on the pore walls of 3D-rGO uniformly. The NH3-sensing properties of the PPy/3D-rGO nanocomposite and the single components were evaluated at room temperature. It is found that the bioinspired PPy/3D-rGO nanocomposite displays a 4–5 times enhancement in gas response compared with pure PPy and can rapidly response NH3 with sub-ppm level. It also demonstrates good dynamic characteristic, satisfactory selectivity and stability for PPy/3D-rGO nanocomposite sensor. The enhanced sensing performances of PPy/3D-rGO nanocomposite are analyzed reasonably based on its unique microstructure and the effective nanocompositeization between rGO and PPy nanoparticles.

Bioinspired nanocomposites film with highly-aligned silicon carbide nanowires and polyvinyl alcohol for mechanical and thermal anisotropy

This work reports a bioinspired anisotropic nanocomposite by polar solution assisted mechanical stretching method, consisting of polyvinyl alcohol (PVA) and silicon carbide nanowires (SiCNWs) with aligned morphology in one direction. Inspired by the structural mimicry of myofibers, in which the uniaxial mechanical property of materials can be improved evidently, highly-aligned SiCNWs and PVA chains that interact using intermolecular force can be obtained. Hysteresis is observed and reversible deformation occurs while tensile–relaxation cycles are applied to the 100% stretched SiCNWs/PVA nanocomposites. The nanocomposites exhibit excellent properties and the tensile strength of 100% stretched SiCNWs/PVA nanocomposites is 188.30 ± 4.2 MPa and elastic modulus is 6.95 GPa, which are increased by 421.90% and 581.37% compared with pure PVA. Finite element simulation of fracture mechanism shows good agreement with the experimental results. An improvement of thermal conductivity is also achieved in well-aligned SiCNWs/PVA. The work imitates the structure of mammal muscle and also has great potential for the macroscopic application of one-dimensional nanomaterials as super flexible heat dissipation materials.

Nanoscale bending properties of bio-inspired Ni-graphene nanocomposites

At the nanoscale, bone consists of a hierarchical structure of mineral crystals (hard material) and collagen (soft material). Inspired by bone’s nanoscale structure and properties, we design a nanocomposite with flexible pristine/polycrystalline graphene embedded in a hard Ni matrix. We model Ni graphene nanocomposites, with different structural arrangements for graphene in the Ni matrix. We use molecular dynamics to investigate the deformation of Ni-graphene nanocomposites under 3-point bending. We find that nanocomposites can deform approximately 30% more than pure Ni. The flexibility of the nanocomposite is optimally enhanced with a distance between graphene sheets greater than or equal to 3.05 nm. Polycrystalline graphene nanocomposites show approximately 15–20% improvement in bending modulus compared to pristine graphene nanocomposites. The increase in bending modulus of polycrystalline graphene nanocomposite is because polycrystalline graphene has higher interfacial shear strength compared to pristine graphene. We also find that the structural arrangement of graphene sheets is more important than increases in their volume fraction in the Ni matrix. These results suggest that graphene sheets scattered in the Ni-matrix is preferable to other structural arrangements. The results from this simulation could help in tuning nanocomposite with desired mechanical properties for various engineering applications.

Effect of processing conditions on the mechanical properties of bio-inspired mechanical gradient nanocomposites

Photo-induced thiol-ene crosslinking of allyl-functionalized cellulose nanocrystal (CNC)/polymer nanocomposites allows access to films that mimic the water-enhanced mechanical gradient characteristics of the squid beak. These films are prepared by mixing the functionalized CNCs and polymer in a solvent before solution casting and drying. The photocrosslinking agents are then imbibed into the film before UV exposure. Reported herein are studies aimed at better understanding the effect of the film preparation procedure, film thickness and the conditions under which the UV treatment is carried out. It was found that when the film is heated at a temperature higher than its glass transition temperature (Tg) during the UV irradiation step there is a greater enhancement in the mechanical properties of the films, presumably on account of more efficient crosslinking between the CNC fillers. Moreover, composite films that were compression molded (at 90 °C) before the imbibing step displayed lower mechanical properties compared to the as-cast films, which is attributed to phase separation of the CNC fillers and polymer matrix during this additional processing step. Finally, the film thickness was also found to be a critical factor that affects the degree of crosslinking. For example, thinner films (50 µm) displayed a higher wet modulus ca. 130 MPa compared to ca. 80 MPa for the thicker films (150 µm). Understanding the processing conditions allows access to a larger range of mechanical properties which is important for the design of new bio-inspired mechanical gradient nanocomposites.

Effect of interface strength on the mechanical behaviour of bio-inspired composites: A molecular dynamics study

Nanoscale composites inspired from biological materials such as nacre and bone are excellent candidates for improving the mechanical properties of ceramic matrix composites (CMC) or in general any brittle-matrix composites. These composites are based on the regularly staggered model (RSM) and on the stair-wise staggered model (SSM), and consist of stiffer platelets embedded in a compliant matrix. The interface between the platelets and the matrix plays a key role as an enormous amount of interfacial area exists in the nanocomposite materials. We investigate the influence of interface strength on the overall mechanical properties and deformation mechanisms of bio-inspired brittle-matrix nanocomposites. Atomistic simulations are used for this purpose and the interface strength is controlled by varying the binding energy between the platelet atoms and the matrix atoms. We found that the mechanical properties of both models initially increase with the interface strength. However, above a critical value, the trend changes drastically between the two models. The RSM model continues to maintain the flow stress and toughness at higher interface strengths, due to the persistence of deformation mechanisms such as bulk matrix plasticity and platelet pullout. In contrast, in the SSM model the flow stress and toughness are deteriorated as softening of stress and fracturing of platelets occur at higher interface strengths. The knowledge gained from this study paves new way for the development of bio-inspired ceramic-matrix composites with improved mechanical properties.

Self-Assembly of Ultralarge Graphene Oxide Nanosheets and Alginate into Layered Nanocomposites for Robust Packaging Materials

The assembly of graphene oxide (GO) nanosheets into bioinspired nacre-like nanocomposites is a potential strategy for the development of robust alternative packaging materials. At sufficiently high concentrations, the self-assembly of ultralarge GO into liquid crystals (LC) in colloidal suspensions with alginate biopolymer is observed. Studying freeze-dried partially cast nanocomposites reveals the gradual reorientation and merging of these LC domains during evaporation. Evaporation of LC alginate–GO suspensions yields nanocomposite films with highly ordered layered microstructures, with excellent mechanical properties, thermal stability, and moisture barrier performance. Spectroscopic studies and comparison with theoretical models establish the role of hydrogen-bonding interactions between the components and confirm the parallel alignment of ultralarge GO above 2 wt %, corresponding to the formation of LC domains in aqueous suspension. The insights afforded by this study can help guide the commercial dev...

Nanoindentation on the bio-inspired high-performance nature composite by molecular dynamics method

The determination of mechanical properties at the nanoscale is of such importance today that researchers pay special attention to it. Discovering the mechanical properties of biological composite structures in the nanoscale is much interesting today. Top neck mollusk shells are among biomaterial nanocomposites that their layered structures are composed of organic and inorganic materials. Since the nanoindentation process is known as an efficient method to determine mechanical properties like elastic modulus and hardness in small scale, therefore, due to some limitations of considering all peripheral parameters, particular simulations of temperature effect in the atomic scale are considerable. The present article provides a molecular dynamics approach for modeling the nanoindentation mechanism with three types of pyramidal, cubic, and spherical indenters at different temperatures of 173, 273, 300, and 373°K. Based on load-indentation depth diagrams and Oliver–Pharr equations, research findings indicate that the temperature has weakened the power between the biological atoms; this leads to reduced mechanical properties. An increase in temperature causes a reduction in elastic modulus and hardness. There was correspondence between the results obtained from the spherical indenter and experimental data. This study can be regarded as a novel benchmark study for further research studies which tend to consider structural responses of the various bio-inspired nanocomposites.

Vitrimer Chemistry Meets Cellulose Nanofibrils: Bioinspired Nanopapers with High Water Resistance and Strong Adhesion.

Nanopapers containing cellulose nanofibrils (CNFs) are an emerging and sustainable class of high performance materials. The diversification and improvement of the mechanical and functional property space critically depend on integration of CNFs with rationally designed, tailor-made polymers following bioinspired nanocomposite designs. Here we combine for the first time CNFs with colloidal dispersions of vitrimer nanoparticles (VP) into mechanically coherent nanopaper materials. Vitrimers are permanently cross-linked polymer networks that undergo temperature-induced bond shuffling through an associative mechanism and which allow welding and reshaping on the macroscale. The choice of low glass transition, hydrophobic vitrimers derived from fatty acids and polydimethylsiloxane (PDMS), and achieving dynamic reshuffling of cross-links through transesterification reactions enables excellent compatibility and covalent attachment onto the CNF surfaces. Moreover,the resulting films are ductile, stretchable and offer high water resistance. The success of imparting the vitrimeric polymeric behavior into the nanocomposite, as well as the curing mechanism of the vitrimer, is highlighted through thorough analysis of structural and mechanical properties. The dynamic exchange chemistry of the vitrimers enables efficient welding of two nanocomposite parts as characterized by good bonding strength during single lap shear tests. In the future, we expect that the dynamic character of vitrimers becomes a promising option for the design of mechanically adaptive bioinspired nanocomposites and for shaping and reshaping such materials.

Exceptional contact elasticity of human enamel in nanoindentation test

ObjectiveTooth enamel has unsurpassed hardness and stiffness among mammalian tissue structures. Such stiff materials are usually brittle, yet mature enamel can survive for a lifetime. Understanding the nanoscale origin of enamel durability is important for developing advanced load-bearing biomaterials. Here, nanoscale exceptional contact elasticity of the human tooth enamel, based on nanoindentation tests, is reported. MethodsSpherical indenter tips with radii of 243 and 1041nm were used to determine stress–strain curves of enamel. Force–displacement curves were recorded using quasi-static loading strain rates of 0.031, 0.041, and 0.061s−1. The storage moduli from a superimposed signal amplitude (dynamic strain at 220Hz) embedded during primary quasi-static loading and from quasi-static elastic theory were simultaneously measured. Modulus mapping was considered to be an extremely low quasi-static loading strain rate indentation test. ResultsThe elastic limits were 7–9GPa and 5–6GPa for the small and large indenters, respectively. The elastic–plastic transition point and elastic modulus value increased with substantially increased quasi-static loading strain rate. The results suggested that the increase of the elastic limit during high-loading strain was associated with exceptional contact elasticity at the nanoscale of the enamel structure and the consequent extension of the contact area (i.e., a temporary pile-up response, dependent on the enamel nanocrystals and protein glue). SignificanceStructural modification at this scale effectively prevents the initiation of cracking from localized strain, thus reinforcing the bulk structure. These results may provide valuable insight for conceptualizing bio-inspired nanocomposites.

Atomistic Simulations of Length-Scale Effect of Bioinspired Brittle-Matrix Nanocomposite Models

AbstractAtomistic simulations are performed to investigate the effect of length scale on the mechanical properties and associated plasticity of bioinspired brittle-matrix nanocomposites. The regula...

Facile and On-Demand Cross-Linking of Nacre-Mimetic Nanocomposites Using Tailor-Made Polymers with Latent Reactivity.

The development of on-demand cross-linking strategies is a key aspect in promoting mechanical properties of high-performance bioinspired nanocomposites. Here, we embed styrene sulfonyl azide groups with latent chemical reactivity into water-soluble copolymers and assemble those with high-aspect-ratio synthetic nanoclays to generate well-defined layered polymer/nanoclay nacre-mimetics. A considerable stiffening and strengthening occurs upon activation of the covalent cross-linking using simple heating. Varying the amount of cross-linkable units allows molecular control of mechanical properties from ductile to stiff and strong. Moreover, the covalent cross-linking enhances the moisture stability of water-borne nacre-mimetics. The strategy is facile and versatile allowing for a transfer into applications.

Enhanced surface and mechanical properties of bioinspired nanolaminate graphene-aluminum alloy nanocomposites through laser shock processing for engineering applications

The combination of interlocked lamellae grains is the primary feature of biological material “nacre” to constitute its highest strength. The mimic of this hierarchical assembly of biological material combinations remains the challenge for the future trending bioinspired engineering materials. In this study, the interlocked nanolaminated architecture of graphene-reinforced aluminum alloy nanocomposite achieved via multi-step powder metallurgy route and industrial extrusion process followed by laser shock peening. Interrupted re-nucleation to obtain lamellae grains, controlled laminates sliding through interlock mechanism and inhibited large dislocation loop formation in the nanocomposites during laser shock peening was significantly influenced the mechanical properties of the nanocomposites. Consequently, enhancement in the hardness, tensile strength, wettability characteristic properties and prolonged fatigue life cycles were achieved significantly for nanocomposites.

Fabrication and characterization of nanoengineered biocompatible n-HA/chitosan-tamarind seed polysaccharide: Bio-inspired nanocomposites for bone tissue engineering

In this communication we describe the fabrication of nano-hydroxyapatite/chitosan-tamarind seed polysaccharide (n-HA/CS-TSP) nanocomposite with a weight ratio of 70/20/10, 70/15/15 and 70/10/20, respectively through a co-precipitation method. A comparative assessment of the properties of n-HA/CS-TSP and n-HA/CS nanocomposites was done by FT-IR, SEM–EDX, TEM, TGA/DTA, XRD and mechanical testing. The results suggested strong chemical interactions between the three components, decreased particle size and homogeneous dispersion of n-HA particles in n-HA/CS-TSP as compared to n-HA/CS. The n-HA/CS-TSP (70/10/20) showed the most porous and rough surface, enhanced thermal stability and highest compressive strength (4.0 MPa) and modulus (81 MPa). In addition, n-HA/CS-TSP (70/10/20) exhibited greater swelling character, acceptable degradation and increased biomineralization in simulated body fluid (SBF) as compared to n-HA/CS-TSP (70/20/10, 70/15/15) and n-HA/CS nanocomposites. The superior non-toxic response with MG-63 cells and better haemocompatibility was observed with n-HA/CS-TSP (70/15/15). Thereby, n-HA/CS-TSP nanocomposites could be promising alternative biomaterials in the field of bone tissue engineering compared to the n-HA/CS nanocomposite.

Bioinspired graphene-based nanocomposites via ionic interfacial interactions

Abstract In nature, small amount of metal ions play a critical role in improving mechanical properties, such as the jaws of marine polychaete Nereis and Glycera. Recently, the multivalent cations metals have been successfully introduced to enhance the interfacial strength of graphene based-nanocomposites through forming ionic crosslinking networks with graphene oxide (GO) nanosheets by coordination. Combination with other interfacial interactions, the synergistic effect was constructed in the resultant bioinspired nanocomposites, leading to outstanding integrated performance, including thermal, electrical, fatigue resistant and mechanical properties. These excellent properties make this bioinspired graphene-based nanocomposites to be great candidates for applications in many fields, for example, flexible electronics devices, artificial muscles, supercapacitors , and aerospace.

Fabrication of strong nanocomposite films with renewable forestry waste/montmorillonite/reduction of graphene oxide for fire retardant

It is desirable to develop products comprised of biodegradable components from green resources or renewable waste due to a shortage of fossil fuel. Wood auto-hydrolysates (WH) are generated in the hydrothermal treatment of the pulping process, which contains large amounts of hemicelluloses and some lignin. In this work, a green and facile route similar to paper making is proposed to convert WH to value-added nanocomposite films. WH was combined with montmorillonite (MMT) as the basic components together with a small quantity of graphene oxide (GO) to produce a ternary, bioinspired nanocomposite film with high strength and fire resistance properties. GO was initially introduced to fabricate the WH-MMT-GO nanocomposites, the interfacial interaction between WH, MMT, and GO was enhanced by the synergistic effect of hydrogen and covalent bonds. The nanocomposite film WH-MMT-rGO (F0.8%rGO) with only 0.8 wt% rGO exhibited promising features, such as a good thermal stability, and a high strength of 124 MPa, which was better than other hemicellulose-based films or wood auto-hydrolysate based films. The combustion behavior of WH-MMT-GO films was determined by microscale combustion calorimeter (MCC), and the results suggested the films had excellent fire resistance, where the peak heat release rate (PHRR) of the films was reduced by more than 90% compared to the neat WH. Furthermore, the hemicellulose-based films are reported to be hydrophilic, while the WH-MMT-rGO films proved to be hydrophobic due to the introducing of rGO. The proposed synthetic strategy could make the wood auto-hydrolysate useful for fabrication of fire-protective films, coatings, packaging, etc.

Beihang University: (Adv. Mater. 45/2017)

Advanced MaterialsVolume 29, Issue 45 Back CoverFree Access Beihang University: (Adv. Mater. 45/2017) First published: 01 December 2017 https://doi.org/10.1002/adma.201770326AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinkedInRedditWechat Graphical Abstract Beihang University celebrates its 65th Anniversary in 2017. The New Main Building is a landmark at Beihang University and demonstrates the recent rapid development of this University. Natural structural materials such as nacre, bone, bamboo, wood, and squill that can be used to make high-performance, lightweight bioinspired nanocomposites are shown. Volume29, Issue45Special Issue: Nature-Inspired Surface and Materials Research at Beihang UniversityDecember 6, 2017 RelatedInformation

Nanocomposites: High‐Performance Nanocomposites Inspired by Nature (Adv. Mater. 45/2017)

Natural materials combine orderly hierarchical architectures with abundant interface interactions. To learn from nature, various building blocks are used to build bioinspired nanocomposites with the design of interface interactions. The resulting nanocomposites possess extraordinary mechanical properties, as well as other functions, which are promising in various fields. The recent progress in the area of high-performance inspired by nature is discussed by Qunfeng Cheng and Jingsong Peng in article number 1702959.

High-Performance Nanocomposites Inspired by Nature.

Natural materials, including nacre, bone, and the lobster cuticle, exhibit excellent mechanical properties, combining high strength and toughness. Such materials have the added benefit of being light in weight. These advantageous features are due to such natural materials' orderly hierarchical architectures and abundant interface interactions. How to utilize these design principles created by nature to fabricate high-performance bioinspired nanocomposites remains a great research challenge. A logical roadmap for developing these nanocomposites can be described as "discovery, invention, and creation." Here, the discovery of the relationship between natural materials' design principles and such materials' extraordinary mechanical properties is discussed. Then, the invention of bioinspired strategies for mimicking natural materials is considered and representative strategies addressed. Next, the creation of multifunctional nanocomposites is discussed and bioinspired nanocomposites, including fiber nanocomposites, 2D film nanocomposites, and 3D bulk nanocomposites reviewed. Finally, a perspective and outlook for future directions in making bioinspired nanocomposites is provided to offer inspiration to the community and a clear vision for future research.

Bioinspired graphene-based nanocomposites and their application in electronic devices

The increasingly popular flexible electronic devices, such as electronic papers, touch screens, roll-up displays, and wearable sensors, etc., require maintaining high performance, including mechanical and electrical properties, under repeatable deformation state. Graphene, as a two dimensional (2D) carbon nanomaterial with integrated high mechanical properties and electrical conductivity, could serve as the ideal building block for constructing functional materials in application of flexible electronic devices. There have been several attempts to use graphene-based nanocomposites in these devices. However, their assembly using traditional approaches, exhibit relatively poor mechanical and electrical properties, which largely limits the efficiency of these devices. Thus, it remains a great challenge to assemble microscopic graphene nanosheets into macroscopic high performance graphene-based nanocomposites. As known, the performance usually depends on the unique structure of materials, especially for the nanocomposites. Thus, it will be the next hot-topic that how to achieve the high performance flexible electronic device through designing and constructing the unique structures of graphene-based nanocomposites. Nacre, the “gold standard” for biomimicry with both high strength and toughness, has been the source of inspiration for designing many synthetic hybrid materials and nanocomposites. This is achieved through a precise architecture that resembles that of a brick wall, and the clever design of the interface. Compared to other approaches for constructing graphene-based nanocomposites, this bioinspired concept results in good dispersion, high loading and excellent interfacial interaction design. The resultant bioinspired graphene-based nanocomposites (BGBNs) demonstrate significant enhancement in mechanical and electrical properties. In this review, we summerize recent research progress on the BGBNs, following the research philosophy of discovery, invention, creation. Firstly, we analyze in detail the sophisticated interfacial architecture of natural nacre, which is responsible for its unique integration of high strength and toughness. Subsequently, we discuss the excellent mechanical and elertrical properties of graphene nanosheets. Then, we analyze and compare the effect of different interfacical interactions on the mecahnical and electrical properties of BGBNs. Furthermore, we discuss the synergistic effect from different interfacial interactions and building blocks for the fabrication of integrated strong and tough BGBNs. We highlight the fundamental physical properties of BGBNs, such as strength, toughness, and electrical conductivity. Specially, some other functions, including fatigue resistance, fire-retardant properties, etc., are also discussed. In addition, we also summarize the applications of BGBNs in flexible electronic devices, and discuss their challenges. Finally, we offer a perspective on the roadmap and target for BGBNs in the next 5−10 year as follows: (1) The essence of synergistic effect through different interfacial interactions and building blocks should be demonstrated and revealed by further theoretical simulation. (2) The tensile strength and stiffness of BGBNs can reach up to that comparable to carbon fiber reinforced composites, realizing application of BGBNs as structural materials in aerospace and aeronautics. (3) The integrated electrical and fatigue resistant properties should be simultaneously enhanced to satisfy the needs of flexible and wearable electronic devices. (4) Some simple, easy operation techniques will be explored for scaling up the fabrication of BGBNs, which could provide amount of BGBNs for practical applications in many fields.