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Bulk Modulus - presentation
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BULK MODULUS:BULK MODULUS:
Volume elasticityVolume elasticity
Bulk modulus- The bulk modulus (K) of a substance measures the substance's resistance to
uniform compression. It is defined as the pressure increase needed to cause a given relative decrease in volume. Its base unit is the Pascal. Its the ratio of the stress on the body to the body's
fractional decrease in volume.
The modulus of elasticity for a material subjected to compression
on all surfaces—that is, volume stress.Bulk modulus is the relationship of
volume stress to volume strain, expressed as the ratio between F/A
and dV/Vo, where dV is the change in volume and Vo is the original volume.
Definition
The bulk modulus K can be formally defined by the equation:
K= -V ∂P/∂V where P is pressure, V is volume, and
∂P/∂V denotes the partial derivative of pressure with respect to volume. The inverse of the bulk
modulus gives a substance's compressibility. Other moduli describe the material's response (strain) to other kinds of stress: the shear modulus describes
the response to shear, and Young's modulus describes the response to linear strain. For a fluid, only the bulk modulus is meaningful. For an anisotropic solid such as wood or paper,
these three moduli do not contain enough information to describe its behavior, and one must
use the full generalized Hooke's law.
When forces are applied to each surface of a cube, the cube experiences a strain
on its volume.The volume will be reduced. In this case
the volume stress is force per unit area (F/A). The volume strain is change in
volume per unit volume ( V/V) K=volume stress/volume strainB= F/A / V/V
Volume elasticity applies both to liquids and solids .
Gases are easily compressed and have very small coefficients and vary with
pressure and temperature.
Characteristics of materials which are closely related to the elastic properties
are ductility, malleability, compressibility and hardness.
Ductility Ductility is a mechanical property that
describes the extent in which solid materials can be plastically deformed without fracture.
Ductility is especially important in metalworking, as materials that crack or break under stress cannot be manipulated using metal forming processes, such as hammering, rolling, and drawing.
Example picture :
Malleability Malleability, a similar concept, refers
to a material's ability to deform under compressive stress; this is often characterized by the material's ability to form a thin sheet by hammering or rolling .
Example picture :
Compressibility
Compressibility is a measure of the relative volume change of a fluid or solid as a response to a pressure (or mean ”stress”) change.
Example picture :
Hardness
Hardness is dependent on ductility, elasticity, plasticity, strain, strength, toughness, viscoelasticity, and viscosity.
Common examples of hard matter are ceramics, concrete, certain metals, and super hard materials, which can be contrasted with soft matter.
Example picture :
![Earthquake-induced deformation analyses of the Upper San ...5] BKP P m = ′ ba m a σ where B is the bulk modulus, Kg is the shear modulus con-stant, n is the shear modulus exponent](https://img.pdfslide.us/doc/110x75/5ecc9e3b3fff8c554e0e2d22/earthquake-induced-deformation-analyses-of-the-upper-san-5-bkp-p-m-a-ba.jpg)
![Pressure Derivatives of Bulk Modulus, Thermal Expansivity ... · has large bulk modulus, less compressibility and high melting temperature [9, 10]. MgO remains stable in the rock](https://img.pdfslide.us/doc/110x75/6062334e70cf1b4132608fe7/pressure-derivatives-of-bulk-modulus-thermal-expansivity-has-large-bulk-modulus.jpg)
![Bulk Account Creation [ppt]](https://img.pdfslide.us/doc/110x75/5491c22cac795949288b45fa/bulk-account-creation-ppt.jpg)
