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Metamorphism. Rocks need to be partially plastic from heat and pressure in order to fold rather than fault.
When energy is removed from a gas it will undergo mutation.
Determine the minimum diameter a steel wire can have if it is to support a 70 kg person. without exceeding the elastic limit of steel which is 5 x 108 Pa. a lim= F/A = 5 × 108 Pa A = F/a lim but F = W = mg and A = pi r 2 = pi (d/2)2 d = sqr[(4/pi) × (m g / a B)] d = sqr[(4/pi) × (70 kg × 9.81 m/s2 /5 × 10^8 Pa)] = 1.3 × 10^-3 m = 1.3 mm
A moving body must undergo a change of position.
Ooooh, tricky question. You said that each object "lost" the same amount of weight in water, and that means that the two objects were the same size (i.e., they displaced the same amount of water when submersed, therefore the same weight loss), but it does not mean they weighed the same to start with. Regardless of their intitial weights, they will lose an amount equal to the weight of water they displace. So, no, the two objects do not necessarily weigh the same in air, but they might. There is no information here to tell you whether they do or do not. Ray
Copper wire will undergo plastic deformation even though it does not break like steel wire.
In the crust, within a few kilometers of the surface
Elastic deformation occurs when an opposing force is applied to the drug after particle rearrangement (i.e. the initial repacking of the particles). If the force is released before the yield point is reached, the particles of the drug will return to their original shape. However, if the force goes beyond the yield point, the powder will undergo plastic deformation or brittle fracture.
In an elastic deformation, the object will return to its original shape afterwards (like tapping your arm softly with a needle, without piercing the skin). In a plastic deformation the object will first undergo elastic deformation, but then undergo a deformation that changes the shape of the material. (like tapping your arm with a needle that pierces through the skin and leaves a small wound).
When a large force is being applied to the particles, deformation becomes irreversible. The applied force will cause the particles to change shape leading to void spaces being filled. Examples of excipients which are known to undergo plastic deformation when a force is applied to them include microcrystalline celluose and LHPC.
brittle. ceramics are generally brittle.
You usually say that the member fractures or fails at its ultimate stressDepending on the properties of the material, as stress increases, a typical metal will undergo elastic deformation, then a region of (nearly) constant plastic deformation, then strain hardening, a period of necking and then fracture.
More flexible than thermosetting plastics: they can undergo both elastic and plastic deformation without too much trouble. They can also be reformed and remoulded when reheated however they cannot withstand temperatures as high as thermosetting plastics.
A body of rock affected by tensile stress will likely undergo stretching. This happens during the asymmetric deformation of a rock mass.
No, he did not. He didn't want to.
No, they don't
Predominantly due to friction. Major earthquakes (the ones you hear about on the news) occur at collision (where two tectonic plates are smashing together) and conservative (where two plates slide side-by-side) boundaries. Rocks (which obviously make up tectonic plates) can undergo two types of deformation, ductile (or plastic) and brittle. When you put stress on these rocks, which happens when they rub against each other, they will usually undergo ductile deformation providing the stress is constant and fairly low. If you've ever been to a big mountain range like the Himalaya, you'll see folds in the rocks. This is ductile deformation. Earthquakes occur when the stress reaches a point called the rupture point. When this point is reached, the rocks will not fold and twist, they'll simply break and energy is released, an earthquake. In plate tectonics, this happens in the Wadati-Benioff Zone (in collision boundaries). The best illustration for this ductile/brittle deformation process is using one of those plastic rulers found in schools around the world (Staedtler type). You can bend the ruler and it will actually bend quite a long way. However, it will reach a critical point where it will stop bending and just snap, releasing energy in the process. This energy is effectively the same as seismic waves in earthquakes (albeit on a much smaller scale) that will cause material around it to vibrate. Big enough vibrations = buildings collapse. Source: geography teacher and geology graduate.