Young’s modulus is an essential mechanical property for engineers in creating materials that resist stress and damage, showing how much force is necessary to break a material while also serving as an indicator of its strength.
This research investigates the effect of porosity on Young’s modulus for sintered alumina. Utilizing an innovative synthesis technique, this study doubled Young’s modulus.
It is a measure of the material’s strength
Young’s modulus measures the elastic force that materials exert when subjected to specific strain. It is an isotropic material’s property and applies only under uniaxial stress (tensile or compressive). We can use Young’s modulus to predict how much a sample will extend under tension or compress under compression, and also determine its elasticity structure; this information can be invaluable in predicting deflection for statically determinate beams, as well as creating structures which withstand large forces without cracking under compression or tension.
Mechanical properties of g-alumina were evaluated through Hertzian indentation tests and finite element modelling (FEM). Stress-strain curves were plotted, with Young’s modulus E being determined by slope of linear portion of curve. Yield stress (Y) and strain-hardening parameter n were estimated by correlating FEM results with experimental curves.
Alumina’s primary advantage lies in its plasticity, which enables it to deform without breaking, making it ideal for applications requiring high dimensional stability. Unfortunately, as temperature rises the Young’s modulus decreases with increasing temperatures – an effect which may be partially explained by thermal expansion and particle dislocations.
Poisson’s ratio of alumina can also help measure its toughness; this property measures the material’s ability to absorb energy under cyclic loading and is an integral part of material design and manufacture for applications involving large tensile or compressive loads, as well as fatigue testing of materials.
Poisson’s ratio can be calculated from its Young’s modulus and other materials’ Poisson’s ratios; however, its morphology is complex, and requires extensive knowledge of porosity and grain size for accurate calculations. Therefore, we employed a novel synthetic technique to synthesize g-alumina granules with defined pore sizes and shapes and studied their morphologies by scanning electron microscopy and field-emission scanning electron microscopy; their relationships between Young’s modulus modulus Poisson’s ratio, and pore size were analysed using Finite Element Method (FEM); overall this doubled Young’s modulus thus increasing overall strength overall.
It is a measure of its stiffness
Young’s modulus of alumina is an indicator of stiffness that measures material resistance to deformation. It is measured by applying force (load) to a small sample of material and its displacement (displacement/force ratio). Young’s modulus can differ depending on temperature, alloy composition, crystal structure and manufacturing processes as well as its geometry; its behaviour also being affected by different orientation of granules within it and by porosity within the material itself.
Contrary to most metals and ceramics, alumina is anisotropic; meaning its mechanical properties vary depending on the direction in which a force is applied. You can make it more isotropic by treating it with certain impurities or mechanically working it; however, doing so will result in decreased strength and toughness.
Nanoindentation can be used to accurately determine Young’s modulus of alumina as well as its stiffness, hardness and elastic resilience. The force versus deflection curve of samples makes the method more accurate than standard tensile tests while smaller samples reduce risk and produce regular distribution curves.
Young’s Modulus of alumina depends on its production process and has been observed to vary non-linearly with load. This phenomenon may be explained by changes in interatomic bonding caused by temperature variations; fitting and theory have enabled prediction of this phenomena.
Alumina’s high Young’s Modulus makes it an extremely stiff material that resists deformation, yet its brittle nature precludes its use for applications that require plasticity such as structural components and cutting tools. Furthermore, without a yield point it will break under compressive or tensile loads almost instantly rather than gradually over time.
Young’s modulus of alumina changes asymmetrically under load, with its shape determined by its granule geometry. This occurs because individual alumina granules may be at various angles to each other and to the indenter; this results in non-monotonic dependencies between its modulus of elasticity and hardness of material.
It is a measure of its hardness
Mechanical properties of alumina are integral to many applications, from abrasion resistance and wear resistance to antimicrobial protection. Accurate measurement of these properties is critical, especially when exposed to elevated temperatures that compromise structural integrity of materials such as Young’s modulus testing methods – nondestructive testing techniques provide an effective means of accomplishing this objective.
Impulse excitation indentation tests are an ideal method for estimating Young’s modulus of alumina. These tests create a stress-strain curve which is used to calculate elastic modulus of material; its value corresponds with yield strength. Furthermore, slope of curve also helps determine strain hardening characteristics; results from indentation tests may be compared with predictions made using finite element modeling (FEM).
In this study, impulse excitation and FEA were employed to measure the Young’s modulus of g-alumina with various diameters using Impulse Excitation Method and to perform Young’s Modulus Measurements of different diameters of Alumina material. Alumina’s Young’s modulus can vary widely; thus it is essential that one fully understands its specific properties prior to selecting or using any material in an application.
Alumina is one of the most widely-used technical oxide ceramics, boasting superior levels of strength, hardness, corrosion and wear resistance as well as low thermal expansion rate, good conductivity, chemical inertness and low thermal expansion rate for use in harsh environments. Furthermore, due to its high Young’s modulus and low density characteristics it makes an excellent material choice for electrical applications due to its excellent Young’s modulus performance and low density density properties.
This research applies a novel synthesis method to create granular g-alumina with enhanced mechanical properties. Produced via a new sintering process, the resultant material features higher Young’s modulus than other samples with similar diameter. Furthermore, hardness measurements show increased durability.
Monitors have studied the dynamic Young’s modulus of partially sintered alumina at temperatures ranging from 1200-1600 degC. At room temperature, its Young’s modulus decreases linearly as temperature rises; however, at 1600 degC its Young’s modulus begins to sharply increase as densification takes place – in accordance with its master curve for alumina.
It is a measure of its density
Alumina boasts the highest Young’s modulus rating among ceramic materials, making it ideal for applications that demand strength. Engineers rely on this value to assess how much stress a material can withstand before deforming permanently or breaking. The higher its Young’s modulus rating is, the stiffer its characteristics are.
Alumina’s microstructure and chemistry play an integral part in its properties. Alumina’s atomic configuration is defined by pair radial distribution functions and bond angle distributions, while density estimates can be made using simplex statistics.
Simulations of amorphous alumina reveal its tetrahedral structure with an interstitial space, linking together its atoms through oxygen bonds and creating perfect tetrahedra (PTEs) with an average density of 2.84 g cm-3. Furthermore, these PTEs may link with one another through common oxygen to form large poly-PTEs with a density of 3.81 g cm-3.
Young’s modulus for alumina depends on its purity; higher purity means greater Young’s modulus due to reduced impurities and lower self-diffusion coefficient. Unfortunately, producing pure alumina with the desired purity can be challenging due to low melting and boiling points; one solution could be adding carbon to increase purity further and significantly raise Young’s modulus.
Young’s modulus of alumina also depends on its temperature. As it heats, its elastic properties disintegrate; upon reaching its original firing temperature it begins to sinter (densify), increasing Young’s modulus drastically.
Three and four point bending tests provide engineers with a means of characterizing the elastic properties of alumina, enabling them to measure its bending capacity under compressive and tensile stresses. As shown by these results, 12.6 GPa was determined as its intrinsic elastic modulus value – consistent with theoretical predictions and useful for predicting its flexural properties in various applications – an important step toward creating nonferrous alloys containing this element.