Abstract
The excellent mechanical properties of natural biomaterials have attracted intense attention from researchers with focus on the strengthening and toughening mechanisms. Nevertheless, no material is unconquerable under sufficiently high load. If fracture is unavoidable, constraining the damage scope turns to be a practical way to preserve the integrity of the whole structure. Recent studies on biomaterials have revealed that many structural biomaterials tend to be fractured, under sufficiently high indentation load, through ring cracking which is more localized and hence less destructive compared to the radial one. Inspired by this observation, here we explore the factors affecting the fracture mode of structural biomaterials idealized as laminated materials. Our results suggest that fracture mode of laminated materials depends on the coating/substrate modulus mismatch and the indenter size. A map of fracture mode is developed, showing a critical modulus mismatch (CMM), below which ring cracking dominates irrespective of the indenter size. Many structural biomaterials in nature are found to have modulus mismatch close to the CMM. Our results not only shed light on the mechanics of inclination to ring cracking exhibited by structural biomaterials but are of great value to the design of laminated structures with better persistence of structural integrity.
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Introduction
Biological competition between predator and prey happens ubiquitously in nature. Through millions of years' evolution, organisms have developed diverse strategies to enhance their chance of survival. For example, animals such as fishes, turtles and snails, tend to equip themselves with hard exoskeletons to protect their vulnerable bodies. The survival of these species through biological competitions proved the success of the adopted biological materials in protection against the mechanical attacks and may imply ingenious design conceptions potentially applicable to the synthetic protective materials in engineering. In recent decades, intensive efforts1,2,3,4 have been devoted to the studies on bioarmors in an attempt to understand the underlying principles for material design. So far, most works have been focusing on the mechanisms accounting for the excellent mechanical properties such as higher strength and toughness compared to their building constituents5,6,7,8,9,10,11,12,13, inspiring a number of biomimetic endeavors14,15,16,17. Despite the strengthening and toughening mechanisms which increase the difficulty of crack formation and propagation in materials, fracture is still unavoidable when overwhelming loading is encountered. Under this circumstance, reducing the scope of damage to the minimum extent becomes a realistic choice to combat the catastrophic damage which is vital to the survival of the individuals and even the species. Such strategy is believed to be present in nature after reviewing the findings of recent studies on structural biomaterials. For instance, it has been reported that indentation on the scale of Polypterus senegalus, a ‘living-fossil’ fish species, normally causes ring cracks rather than radial ones1. Such inclination to ring cracks was also exhibited by the shell of Crysomallon squamiferum18, a snail species inhabiting in deep sea hydrothermal environment and teeth of Mylopharyngodon piceus (see Fig. 1a), a fish species feeding on mollusks19; but it is not often the case in synthetic systems such as glass coating on polymeric substrate20 (Fig. 1b) and dental crown21. From the perspective of overall structural integrity, ring cracks are more localized and therefore less destructive than the radial ones. Is the inclination to ring cracking exhibited by the above-mentioned biological structural materials an accidental phenomenon or a consequence of evolution? If it results from natural selection, what are the geometrical and mechanical features of the structural materials that regulate their fracture modes under indentation? Are there any guidelines that we can follow to control the fracture modes as desired? Speculation of these questions inspires us to investigate the mechanics of fracture modes of biological materials undergoing external load represented by indentation.
For a material free of pre-existing defects, fracture due to external loadings tends to start from crack initiation, followed by crack propagation. The location of the crack initiation and the orientation of the resulting crack plane depend on the stress field developed by the external loading and the anisotropy, inhomogeneity and “mechanical nature” of the material. For example, a homogeneous and isotropic cylinder specimen, when subjected to uniaxial tension, generally breaks along the plane perpendicular to the longitudinal axis if it is made by brittle material while fractures along conical surface at 45° to the longitudinal axis if it is made by ductile material. This is because brittle materials generally fail along the plane with maximum tensile stress while the ductile materials often fail along the plane having maximum shear stress. To predict the onset of crack initiation as well as the orientation of the resulting crack plane, setting a proper failure criterion is necessary. Due to the lack of a universal failure criterion, various failure criteria have been developed for materials with diverse mechanical natures22. For example, the simple maximum-tensile-stress criterion, also known as Rankine criterion23, states that a crack forms when the maximum tensile principal stress (σ1) exceeds the fracture strength (σf) of the material. It applies to brittle and even quasi-brittle materials such as concrete, rocks, minerals and ceramics if the materials' anisotropy and inheterogeneity are negligible. The plane of the resulting crack predicted by the Rankine criterion is perpendicular to the direction of the maximum principal stress. Considering that most structural biomaterials are biomineralized composites with brittle minerals (e.g. calcium carbonate and hydroxyapatite) being their major constituents, Rankine criterion23 is considered suitable for them.
Most structural biomaterials in nature exhibit laminated microstructures. For example, the shell of Crysomallon squamiferum consists of a compliant organic layer sandwiched by the outer iron sulfide layer and inner calcium carbonate layer18; the scale of Polypterus senegalus comprises four layers including ganoine, dentine, isopedine and bone1; the tooth of Mylopharyngodon piceus is composed of enameloid and dentine layers19. Although these laminated structures display great diversity, common features in structure and mechanical property are still present. For example, the most outer layer in these structures is found to be notably stiffer and thinner than the adjacent layer. We thus speculate that the fracture modes of laminated structures may depend on the layout of thicknesses and mechanical properties in different layers. To shed light on the factors affecting the fracture modes, theoretical modeling is carried out within the framework of contact mechanics.
Results
Theoretical modeling
Consider an idealized bilayer structure consisting of an elastic coating firmly attached on an elastic substrate, as shown in Fig. 2a. The elastic moduli and Poisson's ratios of the coating and substrate are denoted by Ec, Es, νc and νs, respectively. Although structural biomaterials in nature often consist of layers more than two, this simplified bilayer model is still applicable considering that the most outer layer is normally much thinner than the adjacent layer. A rigid (non-deformable) spherical indenter is compressed by force P onto the laminated structure, simulating the external attack from, for example, predators. Friction between the indenter and coating is neglected. Following the convention in contact mechanics, the profile of the spherical indenter is approximated by a paraboloid of revolution described by (see Fig. 2a), where R is the tip radius characterizing the dimension of the indenter. According to the Rankine criterion, the prediction of fracture modes entails the knowledge of the maximum principal stress σ1 especially its peak value(s) and location(s) of emergence.
Evolution of the maximum stress
The contact problem posed above has been extensively studied in literature24,25,26,27,28. Previous results indicated two possible locations of the maximum principal stress σ1 on the coating surface (z = 0) and the axis of symmetry (r = 0) respectively, as illustrated in Fig. 2b, c. In both cases, σ1 was found to be along the radial direction. Therefore, these two local peaks of σ1 represent the maximum radial stresses on the coating surface (CS) and along the axis of symmetry (AoS) respectively. The existence of two local peaks of σ1 on CS and AoS has also been reported in materials with continuously graded Young's modulus29,30. In particular, for materials with exponentially graded Young's modulus29 along the depth direction, E∝eαz, the maximum of σ1 occurs at the contact perimeter when α > 0 while below the surface along the z-axis when α < 0.
It can be shown that (Supplementary Information) the radial stress components in the coating can be expressed as , where is the reduced modulus of coating, t denotes the thickness of the coating, normalized radial stress is a dimensionless function of the normalized coordinates , and four non-dimensional parameters including the normalized contact radius , modulus ratio Ec/Es, Poisson's ratios vc and vs. Given these four non-dimensional parameters, the normalized maximum principal stress can be obtained semi-analytically for any point with normalized coordinates and (Supplementary Information). For example, taking Ec/Es = 4.0, vc = vs = 0.3, the calculated distributions of along AoS (r = 0) and CS (z = 0) at different contact radii are shown in Fig. 3a and b, respectively. It can be seen that the maximum principal stress along the AoS increases monotonically from compressive to tensile as the depth z increases. It reaches the peak value, denoted by , at the coating/substrate interface (z = t). In contrast, on the CS the location of the peak σ1 is not fixed but changes with the contact radius. Fig. 3b shows that the peak σ1 on the CS occurs exactly at the contact perimeter (r = a, z = 0) when the contact radius a is relatively small in comparison with the coating thickness t. With the increase of contact radius a, the σ1 at the contact perimeter decreases while that outside the contact region rises and finally exceeds the former. The peak value of σ1 on the CS, no matter where it occurs, is denoted by.
As indicated by Rankine criterion23, cracking takes place if the maximum tensile principal stress σ1 reaches the fracture strength σf of the material. The presence of two local peaks of σ1 under indentation implies two possible fracture modes. If reaches σf first, ring cracking would happen as the plane of the resulting crack should be perpendicular to the direction of the which is along the radial direction. Otherwise, radial cracking would be initiated first as the crack should be on the plane passing through the AoS. The determination of the initial fracture mode entails the comparison between and . Fig. 4a shows the evolution of and as functions of normalized contact radius when Ec/Es = 4.0 and vc = vs = 0.3. It can be seen that at small contact size, is greater than. As indentation proceeds and contact radius increases, exceeds. But the predominance of over is not lasting. With further increase of the contact radius, would not increase all the way. Instead, there is a critical contact radius, at which reaches its maximum and then decreases. After certain contact radius, is surpassed by. Since the fracture mode of the coating depends on whether or reaches the fracture strength first as indentation proceeds, the varying contrast between and shown above implies the dependence of fracture mode on the fracture strength. For the case with Ec/Es = 4.0 and vc = vs = 0.3, Fig. 4a shows that if the normalized fracture strength is either sufficiently low or high, would reach the fracture strength first, therefore resulting in ring crack. The lower and upper thresholds of the normalized fracture strength for ring cracking can be readily determined from Fig. 4a to be around 0.05 and 0.9. Here normalized fracture strength is defined as . If or ring cracking occurs. Otherwise, radial cracking takes place. It should be noted that the lower and upper thresholds of the normalized fracture strength for ring/radial cracking are functions of modulus ratio Ec/Es and Poisson's ratios vc and vs. Given vc and vs, they are found to converge as Ec/Esdecreases. There exists a critical value of Ec/Es, at which they converge to one value. For the case of vc = vs = 0.3, this critical modulus ratio is found to be around 1.6, at which the evolution of the normalized and is displayed in Fig. 4b. If Ec/Es is lower than this critical value, is always higher than irrespective of the contact radius. In that case, ring cracking is expected to occur first irrespective of the value of . Recalling the definition of the normalized fracture strength , the value of depends not only on the geometrical and mechanical properties of the laminated materials under indentation but also on the dimension of the indenter characterized by the tip radius R. If the modulus ratio Ec/Es is lower than the critical value mentioned above, the advent of ring cracking is ensured irrespective of the indenter radius. Such critical value of Ec/Es is therefore termed as the critical modulus mismatch (CMM) for ensuring ring cracking mode. For homogenous case with Ec/Es = 1.0 and vc = vs, our results show that the maximum tensile stress always occurs on the coating surface along the radial direction. Therefore, ring cracking, instead of radial cracking, occurs first for brittle materials. This conclusion is consistent with the prediction of the classic Hertzian theory31.
Fracture mode map
The dependence of fracture mode on stiffness ratio Ec/Es and normalized fracture strength can be systematically depicted by a map in terms of these two nondimensional parameters, as shown in Fig. 5 for the case of vc = vs = 0.3. It can be seen that a v-shaped curve divides the plane into two regions corresponding to radial cracking and ring cracking respectively. The valley point of the v-shaped boundary corresponds to the scenario with CMM. It shows again that the destructive radical cracking can be inhibited or deferred for indenters of any size as long as the modulus ratio Ec/Es is lower than the CMM.
It should be pointed out that the CMM revealed above depends on the Poisson's ratios of both coating and substrate. To gain a deeper insight into the effect of Poisson's ratios on the CMM, we studied a series of cases with vc and vs in the reasonably broad range from 0.1 to 0.4. Fig. 6a shows the variation of CMM as a function of vc and vs. It can be seen that CMM is proportional to vs while inversely proportional to vc. Therefore, CMM reaches its maximum and minimum at vc = 0.1, vs = 0.4 and vc = 0.4, vs = 0.1 respectively. The corresponding maps of fracture mode for these two limiting cases are displayed in Fig. 6b. In comparison to the case with vc = vs = 0.3 shown in Fig. 5, it can be seen that the territory of radical cracking regime shrinks in the case of vc = 0.1, vs = 0.4 while expands in the case of vc = 0.4, vs = 0.1, resulting in CMMs equal to 3.3 and 1.0 respectively.
Discussion
For the laminated biomaterials in nature, it may not be easy to obtain the precise Poisson's ratio for each layer and then to predict the corresponding CMM. However, if we take 0.1–0.4 as the reasonable range of Poisson's ratio of biomaterials, the CMM of natural laminated biomaterials, in the light of Fig. 6a, is estimated ranging from 1.0 to 3.3. It is interesting to compare this theoretical prediction with the measured value. Table 1 listed the modulus mismatch of some laminated biomaterials reported in literature. The inclination to ring cracking has been confirmed in some of these materials such as the scale of Polypterus senegalus being bitten by its predator's teeth1. It is interesting to notice that the measured modulus mismatch of the listed biomaterials range from 0.93 to 3.6, overlapping the range of the CMM calculated above. However, for a particular case such as the teeth of Mylopharyngodon piceus19, if the Poisson's ratios of the coating (enameloid) and substrate (dentine) are both taken as 0.3, the CMM is estimated to be around 1.6, which is lower than the measured modulus mismatch 3.5 as shown in Table 1. Such discrepancy may result from our negligence of more specific features in our modeling above. For example, in our previous analysis, we assumed that the modulus across the coating/substrate interface is discontinuous. In fact, transitional interlayer with graded properties is often observed between distinct layers in natural laminated biomaterials. Such gradient interlayer has been demonstrated to play an important role in mitigating the stress and strain concentration at the interface1,18. The effect of gradient transition layer on the CMM is studied by using finite element analysis (Supplementary Information). Fig. 7 shows the calculated fracture mode maps for the cases with gradient interlayer of thickness tgrad in comparison to those without interlayer. It can be seen that the radial cracking regime shrinks and the CMM increases after introducing the gradient interlayer between the coating and substrate. The thicker the interlayer, the higher the CMM. For the teeth of Mylopharyngodon piceus, the reduced modulus obtained by nano-indentation exhibits gradient in the vicinity of the enameloid/dentine interface19. Assuming that the thickness of the gradient interlayer is equal to the coating (enameloid layer) thickness, Fig. 7 implies that the CMM could rise up to 3.5, which agrees well with its measured value.
From the perspective of ensuring ring cracking as the initial fracture mode, soft coating in combination with hard substrate seems more preferable. But why do natural materials barely adopt such kind of design? A conceivable answer to this question is because fracture mode may not be the only issue that biomaterials should tackle. Consideration of other issues such as strength, toughness, wear resistance and economics of construction and maintenance32 may raise different and even competing requirements for the stiffness layout in different layers. The modulus mismatch in the existing biomaterials is most likely a consequence of optimization of diverse design requirements including fracture mode control.
Inspired by the inclination to ring cracking observed in most natural biomaterials, in this paper we theoretically explored the factors determining the emergence of radial cracking and ring cracking in coating/substrate systems. It was revealed that the fracture mode of the coating depends on the coating/substrate modulus mismatch and indenter size. There exists a critical modulus mismatch, CMM, below which emergence of ring cracking always precedes that of radical cracking irrespective of the indenter size. For structural materials, radial cracking is much more catastrophic in comparison to the ring one. Our results imply a strategy to inhibit catastrophic damage by controlling the modulus mismatch. For structural biomaterials in nature, the CMM was estimated to be in the range from 1.0 to 3.3, consistent with the values found in many existing structural biomaterials. Recalling the strengthening and toughening mechanisms discovered in biomaterials, it can be seen that structural biomaterials in nature utilize synergic strategies to mitigate damage due to external mechanical loadings at various intensities and length scales. If the load is relatively low, the intrinsic carrying capacity with the aid of diverse strengthening mechanisms prevents the onset of fracture. If the load exceeds the fracture strength and hence causes crack initiation, various toughening mechanisms operate and resist the subsequent growth of cracks. If indeed overwhelming load is encountered and partial or even whole structural damage is unavoidable, as the last resort, fracture mode may be controlled to inhibit or defer the catastrophic failure. It is the synergy of strengthening, toughening and fracture mode controlling that ensures higher survival probability of the structural biomaterials and their associated species in the intensive biological competitions. In summary, prevention of catastrophic structural failure is the most important goal of structural material design. Reducing the extent of overall structure damage caused by fracture is as important as strength and toughness to the safety and integrity of structures. Fracture mode control is one key strategy that we learned from natural biomaterials to combat catastrophic damage. Nevertheless, the existence of other mechanisms is expected and deserves further investigations.
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Acknowledgements
Supports for this work from the Early Career Scheme (ECS) of Hong Kong RGC (Grant No. 533312), the Departmental General Research Funds and Internal Competitive Research Grants (4-ZZA8, A-PM24, G-UA20) from the Hong Kong Polytechnic University are acknowledged.
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H.Y. developed the concept, conceived the study and conducted the theoretical analysis. Z.X. performed the finite element simulations. Z.X. and C.H. carried out indentation test. H.Y. and M.D. discussed the results and wrote the manuscript. H.Y. supervised the work.
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Fracture mode control: a bio-inspired strategy to combat catastrophic damage
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Yao, H., Xie, Z., He, C. et al. Fracture mode control: a bio-inspired strategy to combat catastrophic damage. Sci Rep 5, 8011 (2015). https://doi.org/10.1038/srep08011
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DOI: https://doi.org/10.1038/srep08011
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