Shock Damage Research Articles

Reliability Modeling and Analysis of Competing Failure Systems With Damage Evolution Effect

ABSTRACTIn practical industrial engineering, systems with dependent and competing failure modes, such as aerospace systems and civil engineering structures, are ubiquitous. These systems usually simultaneously experience two failure modes: gradual internal degradation and external shock. The ultimate failure of the system results from the competition between the soft failure processes and the hard failure processes. With the wide application of intelligent management and artificial intelligence systems, this paper particularly focuses on the damage evolution processes of a system with intelligent characteristics, such as the damage self‐healing processes. By combining the cumulative shock model with the shock model to create a mixed shock model, we analyze the evolution processes of internal performance degradation and external shock damage induced by the self‐healing mechanism. We propose a novel system reliability model with dependent and competing failure processes that has practical significance for improving the accuracy of competing failure systems reliability assessments. Finally, to verify the practicability and validity of the model, empirical studies were conducted using examples of the corrosion process and prestressed strength of concrete degradation of reinforcement concrete (RC) pillar pier of sea bridges with pre‐mixed self‐healing capsules.

A Novel Silver-Ruthenium-Based Antimicrobial Kills Gram-Negative Bacteria Through Oxidative Stress-Induced Macromolecular Damage.

Amplified by the decline in antibiotic discovery, the rise of antibiotic resistance has become a significant global challenge in infectious disease control. Extraintestinal Escherichia coli (ExPEC), known to be the most common instigators of urinary tract infections (UTIs), represent such global threat. Novel strategies for more efficient treatments are therefore desperately needed. These include silver nanoparticles, which have been used as antimicrobial surface-coatings on catheters to eliminate biofilm-forming uropathogens and reduce the risk of nosocomial infections. AGXX® is a promising silver coating that presumably kills bacteria through the generation of reactive oxygen species (ROS) but is more potent than silver. However, neither is AGXX®'s mode of action fully understood, nor have its effects on Gram-negative bacteria or bacterial response and defense mechanisms towards AGXX® been studied in detail. Here, we report that the bactericidal effects of AGXX® are primarily based on ROS formation, as supplementation of the media with a ROS scavenger completely abolished AGXX®-induced killing. We further show that AGXX® impairs the integrity of the bacterial cell envelope and causes substantial protein aggregation and DNA damage already at sublethal concentrations. ExPEC strains appear to be more resistant to the proteotoxic effects of AGXX® compared to non-pathogenic E. coli, indicating improved defense capabilities of the uropathogen. Global transcriptomic studies of AGXX®-stressed ExPEC revealed a strong oxidative stress response, perturbations in metal homeostasis, as well as the activation of heat shock and DNA damage responses. Finally, we present evidence that ExPEC counter AGXX® damage through the production of the chaperone polyphosphate.

Complex Limb Injuries: Limb Salvage Versus Amputation—A Mini Review and Meta‐Analysis

Introduction: The management of complex limb injuries can be very challenging, and it demands a multidisciplinary approach to treatment. Amputation and limb reconstruction are the two options that clinicians must choose. This study aims to comprehensively synthesize existing tools and resources from the literature that can assist clinicians in the decision‐making process.Evaluation: The initial resuscitation and the prehospital care are the first important steps in the management of these injuries, while the immediate transfer to trauma centers is recommended for complex cases. After the stabilization of the patient, a thorough clinical examination of the limb is necessary with emphasis on the degree of soft tissue damage. Blunt trauma in the lower limb is associated with a higher risk of early amputation. Polytrauma patients with complex limb injuries require a holistic approach, with Damage Control Orthopedics (DCO) principles. Traumatic bleeding significantly increases mortality rates, necessitating prompt control using pressure bandages or tourniquets. Computed tomography angiography (CTA) is necessary in order to assess the viability of the limb.Management: Scoring systems can be used as a tool in the management of complex lower and upper limb injuries. Mangled Extremity Severity Score (MESS) calculates ischemia, shock, bone and soft tissue damage, and patient characteristics. The Narakawa Index (NISSSA score) constitutes an alteration of MESS with the implementation of a nerve injury element. The Musculoskeletal Score for Severity of Injury (MESI score) estimates the risk of limb amputation by evaluating injury, neurovascular damage, type of fracture, patient characteristics, and the period from the occurrence of trauma to the definitive treatment. Further interventions and patient preferences should be incorporated into the decision‐making process.Outcome: The outcomes of limb salvage versus amputation for complex limb injuries encompass various factors, including patient’s preinjury health status, psychological well‐being, functional outcomes, and economic impact. While some studies suggest better psychological outcomes with limb reconstruction and others find similar functional outcomes between the two approaches, economic considerations play a significant role in decision‐making.Conclusion: Managing complex limb injuries effectively necessitates a comprehensive approach involving thorough assessment, multidisciplinary collaboration, and patient‐centered care. Given the diverse factors influencing management and long‐term outcomes, it is crucial to integrate medical expertise with patient preferences and expectations.

Effects of Orifices on the Damage Characteristics of an Arch Dam Subjected to Underwater Contact Explosion

Orifices designed into an arch dam for flood discharge significantly reduce the ability of the dam to resist an explosion, especially when an explosive charge is detonated close to an orifice, and the dam may suffer considerable damage in consequence. We created a fully coupled model to represent the dynamic interactions between reservoir water, explosive, arch dam and abutments. Shock wave propagation and damage initiation and propagation were compared between arch dams with and without orifices. The effects of orifices on damage modes and the spatial distribution of damage were investigated. Damage characteristics of the top and middle orifices subjected to explosive loads were also analyzed. Results showed that the top and middle orifices designed into an arch dam have an important effect on the impact resistance of arch dams, especially when an explosive is detonated at an orifice inlet. At a certain mass of explosive, complete failure of the dam wall at the adjacent sluice piers of the top orifices can occur, and penetration failure may also occur at the middle orifice.

Thermal Shock Damage and Failure Mechanism of 2D Laminated SiC/SiC with Barium‐Strontium Aluminosilicate‐Based Environmental Barrier Coating

Thermal shock damage is a key issue for the stable service of SiC/SiC with environmental barrier coating (EBC) in aero‐engines. The thermal shock damage behavior of SiC/SiC with barium‐strontium aluminosilicate (BSAS)‐based EBC in an air atmosphere quenched by air and water media between RT and 1200 °C is systematically investigated. After 600 thermal shock cycles, cracks form in the EBC due to a sharp increase in the internal thermal stresses, and a SiO2 TGO layer is formed on the Si bonding coat. Based on the TGO thickness, damage within BSAS/mullite coatings is quantified by the oxygen permeability (2.541 × 10−11 mol·(atm cm s)−1), which is increased by 2.5 times compared to static oxidation. Despite cracking damage occurring in the SiC matrix of SiC/SiC substrates, the load‐bearing capability of SiC fibers is improved due to the modulus matching of the fiber/matrix. Oxidation damage is dominated the degradation of the performance of SiC/SiC substrates, whose flexural strength is decreased by 15% after 600 cycles. In the thermal shock test quenched by water media, the strength retention of SiC/SiC‐EBC is below 60%, and an increase in internal defects and even delamination of the SiC/SiC substrate are the main reasons for the thermal shock failure of SiC/SiC‐EBC.

An innovative approach to study the influence of microstructure on thermal shock resistance of porous ceramics

AbstractPorosity is a critical microstructural factor in ceramic materials, influencing their mechanical and thermal properties. However, the detailed mechanisms through which porosity, grain size, and grain boundary fracture energy affect the thermal shock resistance of porous ceramics are still not fully understood. This study introduces a dual‐scale model that integrates these microstructural parameters to predict fracture toughness and thermal shock resistance. Using the single‐edge V‐notch fracture toughness testing principle, we calculate the thermal stress intensity factor and establish its relationship with temperature differentials. The critical temperature differential, which marks the onset of thermal shock damage, is determined when the thermal stress intensity factor reaches the fracture toughness threshold. The model reveals a significant interplay between porosity, grain size, and grain boundary fracture energy, with fine‐grained ceramics (grain size < 10 µm) showing a sharp decrease in fracture toughness as porosity increases, while coarser‐grained ceramics are less affected by porosity. These findings provide a deeper understanding of the microstructural optimization needed to enhance the thermal shock resistance of high‐performance porous ceramics.

Spatial variability and quantitative characterization of thermal shock damage in sandstone under different cooling temperatures

This research employs micro-CT scanning technology to analyze the porosity, pore fractal dimension, and spatial variability of sandstone preheated to 600 °C and subsequently cooled in water at varying temperatures (20 °C, 60 °C, 100 °C). The study investigates the mechanisms by which various factors influence thermal shock damage, focusing on the effects of cooling water temperature and the boiling phase transition. The objective is to develop a method for characterizing thermal shock damage that considers spatial variability. The findings indicate that thermal shock damage is limited to a shallow depth beneath the surface, with increased severity near the surface. The boiling phase transition significantly enhances the convective heat transfer coefficient, resulting in substantially higher thermal shock damage when cooled with 100 °C boiling water compared to 20 °C and 60 °C water. Furthermore, for the entire specimen, heating damage exceeds thermal shock damage, and the influence of thermal shock diminishes as specimen size increases. This study addresses the limitations of traditional methods for assessing thermal shock damage that disregard spatial variability and provides practical guidance for engineering projects to manage thermal shock damage more effectively.

Experimental and modeling investigation of the thermal shock behavior of TiC-based self-healing coatings on AISI 321 stainless steel

The AISI 321 steels of structural components serviced at high temperature are usually subjected to oxidation and thermal shock damage during service. Therefore, to improve their high-temperature oxidation and thermal shock resistance, the self-healing coating consisting of Al2O3-13 %TiO2 layer, TiC layer and NiCrAlY layer was prepared for 321 steels in this work. The experimental and microstructural characterization results showed that the thermal shock resistance of such self-healing coating was remarkably improved as compared to the counterpart double-AT13 coating. This is because the volume increment resulting from the oxidation reaction between the TiC and oxygen decreased the porosity of the self-healing coating and retarded crack growth, which also led to the improved high-temperature oxidation resistance. Further, a thermal shock life model based on the crack growth model of Paris formula were developed. The modeling results not only agreed well with the experimental results but also indicated that thickening of thermal grown oxide (TGO) is the main cause of crack initiation and growth.

Grain-based coupled thermo-mechanical modeling for stressed heterogeneous granite under thermal shock

Microscopic damage and macroscopic mechanical properties of granite under the coupling effect of thermal load and initial stress are crucial considerations for the safe construction of underground geo-energy engineering. However, visualizing real-time micro-crack processes in rocks under high-temperature and high-pressure conditions using the current experimental techniques remains challenging. In this study, a numerical method is developed to analyze the thermally induced damage in heterogeneous granite under the coupled influence of initial stress and thermal loading. A biaxial thermo-mechanical grain-based model considering real mineral distribution is established based on digital image processing technology, the grain-based modeling method, and heat conduction theory. The microscopic parameters are calibrated and the effectiveness of the model is verified based on thermal shock and uniaxial compression experiments. The thermal destruction mechanism of granite under initial stress from a microscopic perspective was unveiled for the first time. During the thermal shock process, the stress within the rock does not remain constant at the initial stress value. Instead, it changes continuously with the progression of heat conduction. The impact of the initial stress on the thermally induced cracks is relatively minor. Cooling causes more damage to the rock than heating during thermal shock. The intragranular cracks of quartz consistently outnumber other intragranular or intergranular cracks during thermal shock. The initial stress and thermal shock damage enhance and weaken the biaxial peak strength of granite, respectively. The weakening effect of thermal shock on the peak strength becomes more pronounced at a higher initial stress. These research findings and proposed research techniques contribute to the management and optimization of underground geo-energy engineering.

Boar Sperm Performance in Polystyrene Transport Cool Box Under Various Storage Conditions and Holding Times

When transporting highly valuable boar semen samples over long distances, it is crucial to ensure that boar semen is stored ideally at approximately 15 – 17°C to minimize the impact of cold shock and oxidative damage on sperm quality. This study evaluated the performance of a commercially available semen and embryo polystyrene transport cool box, BotuFLEX®, in preserving the quality of extended boar semen under different storage conditions and holding times. Boar ejaculates were extended at 1:1 or 1:3 using a commercial mid-term extender, stored in a BotuFLEX® semen cool box, and examined 24 vs. 48 h thereafter (Experiment 1; n = 12), or 24 h after storage in air-conditioned room vs. ambient room (Experiment 2; n = 9) conditions. Comprehensive sperm motility using the Sperm Class Analyzer® CASA system revealed no significant difference in either total and progressively motile sperm, and the combined progressivity and velocity characteristics across different treatments. Almost similar results were observed on sperm vitality using the standard supravital staining technique except that percent live spermatozoa were higher at 24 h of storage using the 1:1 dilution.

Thermophysical-mechanical behaviors of hot dry granite subjected to thermal shock cycles and dynamic loadings

Exploring dynamic mechanical responses and failure behaviors of hot dry rock (HDR) is significant for geothermal exploitation and stability assessment. In this study, via the split Hopkinson pressure bar (SHPB) system, a series of dynamic compression tests were conducted on granite treated by cyclic thermal shocks at different temperatures. We analyzed the effects of cyclic thermal shock on the thermal-related physical and dynamic mechanical behaviors of granite. Specifically, the P-wave velocity, dynamic strength, and elastic modulus of the tested granite decrease with increasing temperature and cycle number, while porosity and peak strain increase. The degradation law of dynamic mechanical properties could be described by a cubic polynomial. Cyclic thermal shock promotes shear cracks propagation, causing dynamic failure mode of granite to transition from splitting to tensile-shear composite failure, accompanied by surface spalling and debris splashing. Moreover, the thermal shock damage evolution and coupled failure mechanism of tested granite are discussed. The evolution of thermal shock damage with thermal shock cycle numbers shows an obvious S-shaped surface, featured by an exponential correlation with dynamic mechanical parameters. In addition, with increasing thermal shock temperature and cycles, granite mineral species barely change, but the length and width of thermal cracks increase significantly. The non-uniform expansion of minerals, thermal shock-induced cracking, and water-rock interaction are primary factors for deteriorating dynamic mechanical properties of granite under cyclic thermal shock.

Damage characterization and discrimination in laser-shocked carbon fiber reinforced polymer laminates: A mass-spring-damping model approach

Laser bond inspection (LBI) plays a crucial role in the assessment of interfacial bond strength. However, the development of damage by laser parameters influences the detection and identification of damage. To overcome this challenge, this paper develops a “mass-spring-damping” response model for laser-shocked CFRP laminates and proposes a new damage characterization parameter “ R”. The effects of laser parameters on damage are investigated in the range of 20∼300 ns laser pulse width, 2 and 5 mm laser spot diameters and 0∼6 J laser energy on a 1.5 mm thick T300/AK8210 CFRP laminate. And by combining the parameter “ R” with the laser parameters, the corresponding damage pattern curves can be obtained and the internal damage can be characterized by dividing the four damage stages by the extreme points. Based on the pattern curve, a new analysis method is proposed and a laser shock damage discrimination model is constructed. The model can get the damage pattern curve of this specimen under 5 mm spot diameter and any pulse width within 20∼300 ns, so as to achieve the damage characterization and damage prediction. Relative error between predicted and true results within 9%.

Reliability analysis of multi-component systems subjected to dependent degradation processes and random shocks in dynamic environments

This article presents reliability models for multi-component systems subjected to multiple internally dependent degradation processes and external shocks in dynamic environments. We use the homogeneous semi-Markov process (HSMP) to describe the evolution of the environment state and the non-homogeneous Poisson process (NHPP) to model the arrival of shocks. The degradation processes of the system components are modeled using either general path models (GPM) or stochastic processes. The models highlight the shock-induced degradation acceleration, the degradation-shock dependence, and the influence of dynamic environments on the degradation processes and shock damage. The integrated process evolution (i.e., system degradations, shock arrivals, and environment shifts) follows a non-homogeneous Markov renewal process (NHMRP) in a multidimensional space. The NHMRP semi-Markov kernel and theoretical formulation for system reliability are derived. We provide a simulation algorithm to estimate system reliability. Finally, we demonstrate the theoretical correctness and applicability of the model using a micro-electro-mechanical system (MEMS).

A modular model for reliability analysis model of PMS with multiple K/N subsystems and mixed shocks

AbstractIn this article, a modular model is proposed for the reliability modeling of phased mission systems (PMSs) with complicated system behaviors. By the modular method, the system is divided into several levels: system, subsystem, and components. At the component level, the shock effect, including self‐degradation, additional wear and damage caused by shocks, is considered and the component reliability is evaluated. Then, the reliability modeling method of the K/N system consisting of multiple K/N subsystems is proposed, by a mathematics reasoning method. The correctness of the proposed method is also verified by a Monte Carlo (MC) simulation procedure. At last, the modular method is applied at the system level, and the reliability of a practical engineering case, the attitude and orbit control system (AOCS), is evaluated for illustration. Meanwhile, the parameter sensitivity analysis is also carried out for implementation.

The use of X-Ray computed tomography for the diagnosis of composite structures in the energy sector

RELEVANCE In modern Russia, an important condition for the development of the Far North and Far Eastern regions is to provide these regions with electricity. In remote areas with increased wind potential, the use of wind power plants, the main structural elements of which are made of polymer composite materials (PCM), is promising. The most dangerous operational defect of the PCM is shock damage: due to hail strikes or pieces of ice that broke off during heating of the blades, as well as lightning strikes. Such defects, which are difficult to detect during visual inspection, can significantly reduce the strength and service life of the structure. At the stages of technology development and design certification, the use of modern methods of non-destructive testing is required.PURPOSE. To evaluate the possibilities of X-ray computed tomography for the diagnosis of structural elements made of PCM with impact damage.METHODS. After applying a low-speed impact to fragments of the blades of the wind turbine, a visual inspection and measurement of the size of internal injuries are carried out on a Phoenix V |Tome|X X-ray computed tomograph.RESULTS The nature of the damage inflicted with different impact energies on the most critical areas of fragments of the airfoil blades and the stringer panel is investigated. The depth and area of damage have been determined. The nature and size of internal injuries were studied using an X-rayCOMPUTED tomograph. conclusion. The results obtained allow us to estimate with high accuracy the size and location of impact damage, which can be used in strength calculations.

Abstract 3093: Can Inhibiting Ferroptosis And Subsequent Endothelial Glycocalyx Shedding Reduce The Morbidity And Mortality Of Hemorrhagic Shock?

Background: Trauma patients with hemorrhagic shock accounts for 40% of preventable death. Shock-induced endotheliopathy has garnered interest recently and one aspect of this, endothelial glycocalyx shedding, has shown to promote coagulopathy following hemorrhage. Ferroptosis is an iron dependent, non-apoptotic form of controlled cell death triggered by the oxidation of membrane phospholipids. Liproxstatin-1 (LPX1) is an inhibitor of this process and can protect against oxidative damage to the endothelial cell membrane and subsequent shedding of glycocalyx. We hypothesized that LPX1 would reduce endothelial glycocalyx damage in hemorrhagic shock. Methods: A rat model of hemorrhagic shock and resuscitation was used to assess glycocalyx disruption in the lungs via fluorescent-labeled wheat germ agglutinin staining in frozen tissue and by Syndecan-1 ELISA on plasma samples. A control group (n=5) resuscitated only with Lactated Ringer’s solution, following hemorrhage and resuscitation (H/R) was compared against an experimental group (n=5) that received LPX1 following hemorrhage and before resuscitation. Results: Glycocalyx shedding (assessed by an increase in plasma Syndecan-1 levels) was prevented in the LPX1 treated group compared to control group. Lung tissue staining of the glycocalyx also showed a greater glycocalyx level in the LPX1 group than in the control (40.4 vs 36.3 arbitrary units). Additionally, LPX1 treated animals were able to sustain a higher mean arterial pressure (82 vs 45mmHg), and oxygen saturation throughout the resuscitation period measured at 15 and 30 minutes following LPX1 infusion (98.4% SpO2 vs. 99.0% SpO2 at 30 minutes resuscitation). Conclusions: Ferroptosis inhibitor LPX1 can reduce morbidity acutely during hemorrhagic shock and can protect the endothelial cell glycocalyx from oxidative damage due to its ability to slow the generation of reactive oxygen species and lipid hydroperoxides.

An integrative warning-protection shear thickened composite sponge towards sensing performance and impact resistance with excellent flame retardant

The mechanical shock and thermal damage generally exist together in hazardous environment, whereas traditional single protective materials are difficult to achieve all-round protection under extreme environment. Herein, to realize the integration of multifunctional abilities about impact resistance, flame-retardant and sensing performance, a “solid-liquid host-guest” structural shear thickened composite sponge is proposed, which flame-retardant shear thickening fluids with an extraordinary thickening ratio of 2183.95 % continuously disperse in 3D sponge matrix. The resulting composite sponge effectively attenuates the impact force by nearly 80 % with the thickness of only 4 mm via a cooperation between the effect of shear hardening and structure densification. Meanwhile, after burning on the alcohol flame for 12 s, the composite sponge with 7 wt.% fire-retardant additive maintains a complete morphology and realizes self-extinguishing with a reliable flame-retardant ability. Attributed to the good electrical conductivity of shear thickening fluid, the composite sponge serves favorably in human body monitoring, impact sensing and fire warning. In a word, this multifunctional lightweight composite sponge is expected to realize the integration of early warning and protection, which is a competitive candidate material for the intelligent protection in complex environments.

Our Experience in Using Extracorporeal Membrane Oxygenation in Patients with Refractory Cardiogenic Shock

Background Veno-arterial extracorporeal membrane oxygenation (VA ECMO) is a critical care treatment option for patients with refractory cardiogenic shock. This method of temporary support of the cardiorespiratory system gives us and the patient time to restore organ function or is a «bridge» to other methods of treatment. Nevertheless, the issue of identifying the optimal time for VA ECMO implantation in patients with acute myocardial infarction complicated by refractory cardiogenic shock remains relevant.Aim To evaluate the efficiency of extracorporeal membrane oxygenation in various clinical situations in patients with acute myocardial infarction complicated by refractory cardiogenic shock and post-infarction damage to the valves of the heart.Material and method We present 3 patients with acute coronary syndrome complicated by refractory cardiogenic shock, of different age groups and comorbidities, who underwent veno-arterial extracorporeal oxygenation in various SCAI shock stages, and mechanical complications associated with acute myocardial infarction.Results In all the cases, stabilization of hemodynamics and heart function was achieved, and there were no hypoxic disorders of organs. In one case, a hemorrhagic complication associated with the VA ECMO procedure was noted. In one case, VA ECMO was performed as an intermediate stage for the correction of post-infarction mitral valve injury.Conclusion These clinical cases demonstrate the efficiency of the timely start of VA ECMO before the development of organ dysfunction, which allows restoring myocardial function, and helps maintain hemodynamic normalization before the cardiac surgical stage of treatment.

Mechanism and Prevention of Main Roadway Roof Shock in Strong-Bump Coal Seam with Asymmetric Goaf

In response to the increasingly severe situation of main roadway shock in coal seams, with a focus on the strong-bump coal seam in main roadways under an asymmetric goaf in a certain mine, theoretical analysis, numerical simulation, and engineering practices were employed. This study investigated factors influencing main roadway roof shock damage, changes in roof stress, and characteristics of overlying strata movement. This research unveiled the mechanism and prevention of roof shock in main roadways of strong-bump coal seams in an asymmetric goaf. The research results indicate that the influencing factors of main roadway roof shock damage can be divided into two categories: “strata-support” structure strength and surrounding rock stress. For the determination of the “strata-support” structure, in the case of strong bumps in coal seam roadways influenced by the asymmetric goaf, the key factors contributing to shock damage are the side abutment pressure on the coal pillar in the goaf and the activity level of the roof strata. The distribution of roof stress in the main roadway undergoes continuous changes as district faces are sequentially mined. When the goaf area on the west side gradually increases towards the south, the roof stress in the main roadway consistently rises, and the stress increment follows a pattern of initial increase followed by a decrease. The strata structure of the main roadway roof gradually transforms from an “asymmetric T” shape to a “symmetric T” shape in the transverse profile, and with the evolution of the roof rock layer structure, the mutual feedback effect of strata activity on both sides of the roadway gradually strengthens. Affected by the asymmetric goaf, the main roadway in the district undergoes three different stages: one side of subcritical mining influence → both sides of subcritical mining influence → one side of subcritical mining and one side of critical mining influence. In addition, comprehensively considering the impact of various factors in different stages, the theoretical criteria for roof shock failure in the main roadway are determined. The formulation of an optimized position for the main roadway and a scheme for depressurization through deep-hole blasting in the roof reduce the stress level in the surrounding rock of the main roadway, effectively preventing the occurrence of roof shock in the asymmetric goaf of the coal seam main roadway.

Microstructure, mechanical properties and thermal shock behavior of 2.5D oxide fiber preform reinforced oxide matrix composites

The 2.5D oxide/oxide composites become attractive for their excellent integrity and mechanical properties. The thermal shock resistance performance of the material is very important in the actual high temperature application. In this work, the evolution of microstructure and mechanical behavior of the 2.5D oxide/oxide composites from thermal shock at different temperatures and cycles was investigated experimentally mainly by optical microscope, X-ray computed tomography and macro-mechanical tests. The thermal shock resistance mechanism of oxide/oxide composites was qualitatively explored. The results showed that cracks propagation was the main manifestation of thermal shock damage in composites. Compared with 2D composites, 2.5D composites exhibited the finite domain effect on crack propagation due to its reinforcement had certain fibers in Z-direction. This directly caused the critical thermal shock temperature difference of the 2.5D composites (∼900 °C) was more than twice that of the 2D oxide/oxide composites (∼400 °C). In addition, the finite domain effect also significantly reduced the damage growth rate of the 2.5D composites from cyclic thermal shock, highlighting its excellent thermal shock damage resistance.