<script>on mouseUpput the short name of this card into xTempput char 2 to 6 of xTemp & ".mov" into Movie--put Movieif Movie is not empty then-- put "Animations:" & Movie into pMovieplayMovie Movie,"Animations:"end ifend mouseUp</script>
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<text><span class="style10">orces affecting Solids and Fluids (7 of 9)Elasticity</span><span class="style7">Elasticity deals with deformations that disappear when the external applied forces are removed. Most bodies may be deformed by the action of external forces and behave elastically for small deformations.</span><span class="style26">Strain</span><span class="style7"> is a measure of the amount of deformation. </span><span class="style26">Stress</span><span class="style7"> is a quantity proportional to the force causing the deformation. Its value at any point is given by the magnitude of the force acting at that point divided by the area over which it acts.It is found that for small stresses the stress is proportional to the strain. The constant of proportionality is called the </span><span class="style26">elastic modulus</span><span class="style7"> and it varies according to the material and the type of deformation. </span><span class="style26">Young's modulus</span><span class="style7"> refers to changes in length of a material under the action of an applied force. The </span><span class="style26">shear modulus</span><span class="style7"> relates to another type of deformation - that of planes in a solid sliding past each other. The third modulus is called the </span><span class="style26">bulk modulus</span><span class="style7"> and characterizes the behavior of a substance subject to a uniform volume comparison.A special example of deformation is the extension or elongation of a spring by an applied force. </span><span class="style26">Hooke's law</span><span class="style7">, formulated by the English scientist Robert Hooke (1635-1703), states that, for small forces, the extension is proportional to the applied force. Thus a spring balance will have a uniform scale for the measurement of various weights. In scientific terms, spring steel - which returns to its initial state readily - is almost </span><span class="style26">perfectly elastic</span><span class="style7">. In contrast, a soft rubber ball dropped on hard ground bounces to only about half its initial height, demonstrating </span><span class="style26">imperfect elasticity</span><span class="style7">.Some bodies behave elastically for low values of stress, but above a critical level they behave in a perfectly viscous manner and `flow' like thick treacle, with irreversible deformation. This is called </span><span class="style26">plastic flow</span><span class="style7">.</span></text>
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<text><span class="style10">. Elasticity and plastic flow</span><span class="style7">. Some bodies behave elastically when small forces are applied, but above a critical point they experience plastic flow, i.e. they are irreversibly extended. </span></text>
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<text>ΓÇó MOTION AND FORCEΓÇó THERMODYNAMICSΓÇó HOW CARS WORK</text>
