Irreversible Fracture Research Articles

Predicting Fatigue Damage in Hydrogels Through Force-Induced Luminescence Enhancement.

Fatigue damage of polymers occurs under long-term load cycling, resulting in irreversible fracture failure, which is difficult to predict. The real-time monitoring of material fatigue damage is of great significance. Here, tough hydrogels are prepared with force-induced confined luminescence enhancement of carbonated polymer quantum dot(CPD) clusters to realize the visualization of fracture process and the monitoring of fatigue damage. The enhanced interactions induced by force between the clusters and the polymer in the confined space inhibit the non-radiative leaps and promote the radiative leaps to quantify the fatigue damage into optical signals. Rigid CPDs with abundant active sites on the surface can form dynamic reversible bonds with polymer and dissipate stress concentration, which significantly enhances the crack propagation strain (8000%) and fracture energy (26.4kJ m-2) of hydrogels. CPDhydrogelshave a wide range of applications in novel information encryption and luminescent robotics.

What is the physical origin of the gradient flow structure of variational fracture models?

We investigate a physical characterization of the gradient flow structure of variational fracture models for brittle materials: a Griffith-type fracture model and an irreversible fracture phase field model. We derive the Griffith-type fracture model by assuming that the fracture energy in Griffith's theory is an increasing function of the crack tip velocity. Such a velocity dependence of the fracture energy is typically observed in polymers. We also prove an energy dissipation identity of the Griffith-type fracture model, in other words, its gradient flow structure. On the other hand, the irreversible fracture phase field model is derived as a unidirectional gradient flow of a regularized total energy. We have considered the time relaxation parameter a mathematical approximation parameter, which we should choose as small as possible. In this research, however, we reveal the physical origin of the gradient flow structure of the fracture phase field model (F-PFM) and show that the small time relaxation parameter is characterized as the rate of velocity dependence of the fracture energy. It is verified by comparing the energy dissipation properties of those two models and by analysing a travelling wave solution of the irreversible F-PFM. This article is part of the theme issue 'Non-smooth variational problems with applications in mechanics'.

Engineering Reversible Lattice Structure for High-Capacity Co-Free Li-Rich Cathodes with Negligible Capacity Degradation.

Co-free Li-rich Mn-based cathode materials are garnering great interest because of high capacity and low cost. However, their practical application is seriously hampered by the irreversible oxygen escape and the poor cycling stability. Herein, a reversible lattice adjustment strategy is proposed by integrating O vacancies and B doping. B incorporation increases TM─O (TM: transition metal) bonding orbitals whereas decreases the antibonding orbitals. Moreover, B doping and O vacancies synergistically increase the crystal orbital bond index values enhancing the overall covalent bonding strength, which makes TM─O octahedron more resistant to damage and enables the lattice to better accommodate the deformation and reaction without irreversible fracture. Furthermore, Mott-Hubbard splitting energy is decreased due to O vacancies, facilitating electron leaps, and enhancing the lattice reactivity and capacity. Such a reversible lattice, more amenable to deformation and forestalling fracturing, markedly improves the reversibility of lattice reactions and mitigates TM migration and the irreversible oxygen redox which enables the high cycling stability and high rate capability. The modified cathode demonstrates a specific capacity of 200 mAh g-1 at 1C, amazingly sustaining the capacity for 200 cycles without capacity degradation. This finding presents a promising avenue for solving the long-term cycling issue of Li-rich cathode.

Weak boundary enabled tensile ductility in dealloyed porous Fe alloy

Dealloying has emerged as a new route to the synthesis of porous or nanoporous materials for a variety of novel structural/functional applications. However, dealloyed (nano-)porous metals are notoriously brittle and often fracture catastrophically in bending or tension, which is detrimental to their applications. In this paper, we report that under tension, the irreversible fracture strain (εi) of a macroscopic porous Fe(MnCr) alloy prepared by liquid metal dealloying can be enhanced from nearly zero to 4.1 % by introducing weak domain boundaries, while previous samples with homogeneous (nano-)porous structure usually fracture at εi below 1.0 %. Tensile ductility is enhanced only if the mean domain size (D¯) is not too much larger than mean ligament diameter (L¯), evidenced by the dramatic increase in εi as D¯/L¯ decreases from ∼24 to ∼7. The “ductile” deformation of these materials is associated with the diffuse failure under tension, arising from the promoted nucleation of micro-cracks and the crack deflection or branching along weak domain boundaries at lower D¯/L¯. This strategy might also apply to other (nano-)porous materials self-organized in dealloying or fabricated by other methods.

Application of Configuration Force to Dynamic Crack of Shale under Hydration

The natural microdefects of shale and the expansion of microcracks under hydration and overlying rock loadings are important for the wellbore stability. According to the conservation of energy, the force of the microdefects and microcracks under finite deformation is studied by the method of configuration force through the migrating control volume in the spatial observer. Under the hydration stress and rock pressure, the equation of hydration stress and its work in reference configuration has been obtained, and the equations of configuration forces and configuration moment have been established as a consequence of invariance under changes. The relationship between the configuration and deformation forces is determined by the second law. The energy dissipation equation of the crack tip has been deduced, which shows that the projection of the concentrated internal configuration body force at the crack tip in the opposite direction of the crack is equal to the energy dissipation of the crack tip per unit length. The inertial and internal parts of the concentrated configuration body force at the crack tip have been derived; it is indicated that the internal configuration force plays a leading role in the irreversible fracture process. Moreover, the energy release rate of shale under hydration is proved to depend on constitutive responses and hydration stress. In the theoretical system of configuration force, the migrating control volume at the crack tip contains inclusions, microcracks, microvoids, and heterogeneity of the rock itself. We use the configuration force theory to solve the problem of rock crack propagation and rock fracture. The factors considered are more comprehensive, which can better reflect the actual situation and provide a theoretical basis for the study of wellbore stability.

3D probabilistic cellular automation modeling of transition to fracture in rocks under loading

The three-dimensional model of the probabilistic cellular automaton, which has previously been constructed on the basis of the kinetic theory of strength, is studied in this paper. It describes the process of rock damage accumulation and formation of a damage cluster structure. Comparing the kinetic curves of damage accumulation and correlation functions of the model experiments, it is found that, depending on the sprouting probability of the damage cluster perimeter, which simulates the rate of material fracture under the action of local overstresses near the existing damage clusters, two qualitatively different modes of damage accumulation are observed in the 3D model. For the sprouting probabilities of the cluster perimeter higher than 0.2, the process of transition to irreversible fracture is significantly accelerated and becomes strongly correlated. Along with this, the best agreement of correlation functions in the model and in the physical experiments is observed for the sprouting perimeter probability values smaller than 0.2.

Ambient seismic vibrations in steep bedrock permafrost used to infer variations of ice-fill in fractures

The behavior of ice in frozen rock masses is an important control on rock slope stability but the knowledge of the formation, extent and evolution of ice-filled fractures in steep bedrock permafrost is limited. Therefore, this study aims at characterizing the site specific ambient seismic vibration recorded at the Matterhorn Hörnligrat fieldsite over the course of more than three years. The observed normal mode resonance frequencies vary seasonally with four distinct phases: persistent decrease during summer (phase I), rapid increase during freezing (phase II), trough-shaped pattern in winter (phase III) and a sharp peak with a rapid decay during the melting/thawing season (phase IV). The relation between resonance frequency and rock temperature exhibits an annually repeated pattern with hysteretic behavior. The link between resonance frequency, fracture width and rock temperature indicates that irreversible fracture displacement is dominant in summer periods with low resonance frequency. These findings suggest that the temporal variations in resonance frequencies are linked to the formation and melt of ice-fill in bedrock fractures.

(Invited) Distinctive Characteristics of Internal Fracture in Tough Double Network Hydrogels Revealed By Various Modes of Stretching

(Invited) Distinctive Characteristics of Internal Fracture in Tough Double Network Hydrogels Revealed By Various Modes of Stretching

均質等方性線型弾性体の非可逆的破壊発生条件に関する熱力学的考察

In this paper， we gave a consideration of Griffith’s theory and fracture of a homogeneous isotropic linear elastic body by thermodynamics． From the results， the condition of fracture occurrence by Griffith’s theory is only applied to reversible fracture and it is not able to be the condition of irreversible fracture． But by the theory which surface formation is the change of constitutive equation of the surface area and the generation of strain energy in the surface area， the fracture above mentioned is irreversible and the condition of fracture occurrence by Griffith’s theory can be applied to irreversible fracture.

Elastoplastic models to describe experimental data on the spallation fracture under impact of plates

The processes of irreversible dynamic deformation and spallation fracture under plane impact of plates are numerically studied. The following two models for the behavior of the materials of the plates are used: a model of a damageable elastoplastic medium and a dislocation model. The computations were performed with the use of the TIS-1D software complex based on the method of separation into physical processes, the finite volume method, and moving Eulerian grids.

Maximum bubble pressure rheology of low molecular mass organogels.

Maximum bubble pressure rheology is used to characterize organogels of 0.25 wt % 12-hydroxystearic acid (12-HSA) in mineral oil, 3 wt % (1,3:2,4) dibenzylidene sorbitol (DBS) in poly(ethylene glycol), and 1 wt % 1,3:2,4-bis(3,4-dimethylbenzylidene) sorbitol (DMDBS) in poly(ethylene glycol). The maximum pressure required to inflate a bubble at the end of capillary inserted in a gel is measured. This pressure is related to the gel modulus in the case of elastic cavitation and the gel modulus and toughness in the case of irreversible fracture. The 12-HSA/mineral oil gels are used to demonstrate that this is a facile technique useful for studying time-dependent gel formation and aging and the thermal transition from a gel to a solution. Comparison is made to both qualitative gel tilting measurements and quantitative oscillatory shear rheology to highlight the utility of this measurement and its complementary nature to oscillatory shear rheology. The DBS and DMDBS demonstrate the generality of this measurement to measure gel transition temperatures.

Numerical modeling of irreversible dynamic deformation and fracture of an axisymmetric two-layer container filled with liquid on impact with a rigid obstacle

The results of numerical solution of the two-dimensional problem on the collision of an axisymmetric structure (a two-layer container filled with a liquid) and an absolutely rigid obstacle at various impact velocities are analyzed.

Deep heterogeneity of the stress state in the horizontal shear zones

The formation structures of brittle destruction in a rock layer above an active strike-slip fault in the crystalline basement is studied. The problem is analyzed from the standpoint of loading history, when after the stage of pure gravitational loading, an additional strain state of uniform horizontal shear of both the layer and underlying basement develops, which is further followed by a vertically nonuniform shear caused by the activation of the deep fault. For the studied object, irreversible fracture deformations on macro- and microlevels arise as early as the initial stage of loading under the action of gravitational stresses. These deformations continue evolving on the megascopic level in the course of horizontal shearing that is quasi-uniform both along the depth and laterally. The final formation of the structural ensemble occurs after a long stage of horizontal displacement of the blocks of the crystalline basement—the stage of localized shear. The theoretical analysis of the evolution of the stress state and morphology of the failure structures established the presence of numerous fractures with the normal dip-slip components in the intermediate-depth part of the rock mass, which are formed at the stages of uniform and localized horizontal shearing. The fractures with a strike-slip component mainly arise in the upper and near-axial deep parts of the section.

Coupled continuum modeling of fracture reactivation and induced seismicity during enhanced geothermal operations

We constructed a coupled model to obtain a better understanding of the role of pore pressure changes in causing fracture reactivation and seismicity during enhanced geothermal systems operation (EGS). We implemented constitutive models for fractures in a continuum approach, which is advantageous because of the ease of integration in existing geomechanical codes (FLAC3D), the speed of the calculations and the flexibility of the fracture representation. For modeling the mechanical behavior of the fracture zone the softening ubiquitous joints model was used with random strength properties for the fracture zone. We implemented a hyperbolic deformation with effective stress for the reversible tensile fracture opening (used for fracture permeability), and a linear relationship between plastic shear strain and irreversible fracture opening. The effective permeability of the fracture network was described by a cubic dependence on the fracture aperture. Seismic events were simulated using a dynamic friction angle smaller than the static friction angle, and healing to the static friction angle was allowed after completion of a seismic event. We created a model inspired on the Soultz-sous-Forêts GPK3 injection well, where the granite rock mass is intersected by a dominant fracture zone. The model reproduced reactivation of the fracture zone due to injection of water and we observed the growth of a zone with large directional permeability. The model was used to perform a sensitivity analysis on parameters like in situ stress regime, fracture strength, and frictional weakening. This allowed us to evaluate the trends of their impact on fracture reactivation, including reactivated area, seismic moment and moment magnitudes. A comparison with a Block–Spring model as reported by Baisch et al. (2010) yielded similar results.The models were applied on the GPK3 stimulation case that was performed in Soultz in 2003. The basic features of the observed seismicity were reproduced. The 3D implementation and the Block–Spring model showed their specific advantages: the Block–Spring model, if calibrated, establishes a fast modeling tool for sensitivity analyses; the FLAC3D implementation allows better understanding as it is based on actual physics.

Implications of thermally-induced fracture slip and permeability change on the long-term performance of a deep geological repository

This paper addresses thermally-induced shear slip, i.e., thermoshearing, and changes in permeability of a deep geological repository in large scale. We present a systematic examination of the thermal stress expected to be generated in the far-field around the repository. The main mechanisms for generation of thermal stress that can affect permeability are; comparatively high horizontal compressive thermal stress at the repository level, vertical tensile thermal stress right above the repository and horizontal tensile stress near the surface, and shear stress at the corners of the repository. Based on thermal loading history, probabilistic shear slip analysis was conducted to investigate the possibility of thermoshearing. Higher probability of shear slip is expected with higher differential thermal stress, and this was highly affected by fracture orientations. Stress paths obtained from the thermo-mechanical analysis were used as stress boundary conditions for Discrete Fracture Network-Discrete Element Method (DFN-DEM) Analysis to investigate the effect of stress changes on permeability. In four out of the six DFN models, normal deformation dominated the closure and opening of fractures, with shear dilation being the dominant factor in the other two models. Changes in permeability caused by shear dilation were not reversed after the repository cooled, which is explained by the irreversible fracture shear deformation after shear slip. This study was conducted on data from the Forsmark site in Sweden, and this analysis has implications for sites that have comparatively large horizontal in-situ stresses and relatively few fractures.

Coupled seismo-hydromechanical monitoring of inelastic effects on injection-induced fracture permeability

We present in situ measurements of fluid pressure, deformation and seismicity in natural fractures together with coupled hydromechanical simulations. We conducted a step-rate water injection (~3.5MPa and 1200 s) to induce the local pressurization of a critically stressed fractured carbonate reservoir layer located at 250m-depth in the Low Noise Underground Laboratory (LSBB), southern France. An observed factor-of-3 increase in the fracture permeability was associated with the injection-induced fluid pressure increase and about 100 triggered seismic events. Both normal opening (a few microns) of the fluid-injected fracture and the associated tilt (<1 micro-radian) of the fracture near field displayed inelastic behavior highlighting an irreversible fracture shear and dilatant failure, amounting to about 1/3–1/2 of the maximum measured deformations.Using a plane-strain finite-difference coupled hydromechanical model, our calculation shows that tensile failure first occurred in the injection zone and then shear failure spread along fractures into the surrounding unsaturated rock through stress transfer from the injection zone. The most striking result of these model simulations is that the mechanical weakening of the fractures in the near field induced a 2–5×105Pa release of the normal stress across the fluid-injected fracture that provoked fracture slip and increase in permeability. A geological exploration of the fracture zone after the experiment showed that no major failure had occurred, and we therefore relate these strength and permeability variations to the slight reactivation (~microns) of pre-existing fractures.

Cavitation rheology as a potential method for in vivo assessment of skin biomechanics.

Evaluation of the biomechanical properties of skin is essential for characterization of wound healing kinetics and cutaneous diseases. Available techniques require tissue excision and preclude serial tissue assessment, which limit in vivo monitoring of biomechanical changes. Cavitation rheology (CR) is a method for focal assessment of the mechanical properties of materials.(1) An air cavity is created at the tip of a needle inserted into a material and pressurized until the material yields by rapid elastic deformation (cavitation) or irreversible fracture. An incisional wound model was utilized to determine if this technique could discern differences in the mechanical responses of skin in various states. In accordance with our Institutional Animal Care and Use Committee guidelines, a full-thickness incision was created in the dorsal midline of six Sprague-Dawley rats (The Jackson Laboratory, Bar Harbor, ME) and then closed with a subcuticular suture (4-0 Monocryl, Ethicon, Somerville, NJ). Rats were euthanized 28 days post-wounding and skin was harvested. Cavitation was achieved with a 34-gauge needle (PY2-72-0081, Harvard Apparatus, Holliston, MA) connected to a syringe pump (Nexus 6000, Chemyx, Stafford, TX) and real-time pressure sensor (Cajon Transducer 300psi, Swagelok, Solon, OH). (Figure 1) Air was injected in multiple incisional and surrounding unwounded areas and yielding pressures were recorded. The preferred pathway for yield is a product of material properties and length scale, which can be determined as previously described.(1) Cavitated tissues were excised and stained with hematoxylin and eosin in standard fashion. Statistical comparison of yielding pressures was made using a two-tailed t-test. Statistical significance was assumed when p < 0.05. Figure 1 A schematic representation of the experimental apparatus used for CR. The inset demonstrates the expanding cavity of air (blue circle) within the dermis. The deformational force generated by this cavity (blue arrows) is opposed by the intrinsic elastic ... Incisional skin yielded at a lower pressure than unwounded skin (Figure 2). Sampled sites (n=36, 18 incisional and 18 unwounded) demonstrated a significant difference (p<0.01) in the mean yielding pressure of 69 kPa and 79 kPa for incisional and unwounded skin, respectively. Histological analysis demonstrated a reliable cavitation plane at the dermal-subcutaneous junction, consistent with the realtime observation of maintenance in skin integrity. Figure 2 Box plot demonstrating yielding pressures for incisional (left) and unwounded (right) rat skin 28 days post-wounding. Error bars represent ± standard deviation. Non-destructive methods previously developed to measure cutaneous biomechanical properties have not achieved widespread application.(2, 3) The gold standard of tensiometry has several limitations.(3) Tissue must be excised and sectioned leading to shear stress on samples. Accurate measurements may also be confounded by tissue slippage in tensiometer clamps and imprecise timing of wound breakage. Additionally, methods that rely upon stretch cannot isolate individual layers of cutaneous tissues and their different biomechanical properties. CR has been used to describe the ex vivo biomechanical properties of other animal tissues.(4) We have demonstrated the ability to reproducibly measure the biomechanical properties of skin in various states, with results consistent with previous findings.(5) Ex vivo measurements of the biomechanical properties of skin may not accurately reflect in vivo properties,(3) and our future studies will use in vivo models to compare the ex vivo and in vivo biomechanical properties of skin as assessed by CR. We propose CR as a non-destructive method to assess cutaneous biomechanical properties. CR may provide accurate in vivo evaluation of biomechanical changes during cutaneous wound healing or disease evolution.

Fiber-reinforced Resin Coating for Endocrown Preparations: A Technical Report

Coronal rehabilitation of endodontically treated posterior teeth is still a controversial issue. Although the use of classical crowns supported by radicular metal posts remains widespread in dentistry, their invasiveness has been largely criticized. New materials and therapeutic options based entirely on adhesion are available nowadays, from direct composite resins to indirect endocrowns. They allow for a more conservative, faster, and less expensive dental treatment. However, the absence of a metal or high-strength ceramic substructure as in full-crown restorations can expose this kind of restoration to a higher risk of irreversible fracture in case of crack propagation. The aim of this case report is to present a technique to reinforce the cavity of an endodontically treated tooth by incorporating a fiber-reinforced composite (FRC) layer into the resin coating of the tooth preparation, before the final impressions of the cavity. This technique allows the use of FRCs in combination with any kind of restorative material for an adhesive overlay/endocrown.

An experimental investigation of fracture by cavitation of model elastomeric networks

AbstractA new methodology to investigate the failure of elastomers in a confined geometry has been developed and applied to model end‐linked polyurethane elastomers. The experimental in situ observations show that the elastomers fail by the growth of a single cavity nucleated in the region of maximum hydrostatic stress. Tests carried out at different temperatures for the same elastomer show that the critical stress at which this crack grows is not proportional to the Young's modulus E but depends mainly on the ratio between the mode I fracture energy GIC and E. A reasonable fit of the data can be obtained with a model of cavity expansion by irreversible fracture calculating the energy release rate by finite elements with a strain hardening constitutive equation. Comparison between different elastomers shows that the material containing both entanglements and crosslinks is both tougher in mode I and more resistant to cavitation relative to its elastic modulus. © 2010 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 48:1409–1422, 2010

Cavitation and fracture behavior of polyacrylamide hydrogels

The mechanical properties of gels present qualitatively contradictory behavior; they are commonly soft but also notoriously brittle. We investigate the elasticity and fracture behavior of swollen polymer networks using a simple experimental method to induce cavitation within a gel and adapt scaling theories to capture the observed transition from reversible to irreversible deformations as a function of polymer volume fraction. It is shown quantitatively that the transition from reversible cavitation to irreversible fracture depends on the polymer volume fraction and an initial defect length scale. The use of cavitation experiments permits characterization of network properties across length scales ranging from µm to mm. We anticipate that these results may significantly enhance the understanding of mechanical properties of soft materials, both synthetic and biological.