Unlock the Mystery of Hooke's Law: Stress Proportional to Strain

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SUMMARY

Hooke's Law states that stress is proportional to strain within the elastic limit, indicating a direct relationship between load and deformation. The mathematical explanation involves a Taylor series expansion, where generalized displacement is proportional to generalized force for small displacements. Physically, this proportionality arises from the stretching of atomic bonds, which induces a restoring force that returns atoms to their equilibrium spacing. In elastomers, this restoring force is entropic, particularly relevant for polymer chains.

PREREQUISITES
  • Understanding of Hooke's Law
  • Basic knowledge of stress and strain concepts
  • Familiarity with Taylor series expansion
  • Insight into atomic bonding and polymer behavior
NEXT STEPS
  • Study the mathematical derivation of Hooke's Law using Taylor series
  • Explore atomic bonding and its role in material elasticity
  • Investigate the behavior of elastomers and entropic forces
  • Learn about applications of Hooke's Law in engineering and materials science
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Students of physics, materials scientists, and engineers interested in the principles of elasticity and the behavior of materials under stress.

koolraj09
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Hi guys.
Hooke's Law is stated as: Stress is proportional to strain within elastic limit (or load proportional to deformation).
But I can't really figure out why this happens. I mean what is the cause of this proportionality?
 
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I'm not sure whether you're interested in the math reason or the physical reason. Math reason: every generalized "displacement" (e.g., distance or strain) is proportional to generalized "force" (e.g., load or stress) for small displacements, as can be shown by a Taylor series expansion,

f(x_0+\Delta x)\approx f(x_0)+f^\prime(x_0)\Delta x

where the first term is zero because x_0 is the equilibrium position.

Physical reason: pulling on something stretches atomic bonds* and induces a restoring force so that the atoms can go back to their equilibrium spacing.

*Or straightens polymer chains, in elastomers, where the restoring force is entropic. (This is a more advanced topic.)
 
Mapes said:
Physical reason: pulling on something stretches atomic bonds* and induces a restoring force so that the atoms can go back to their equilibrium spacing.

*Or straightens polymer chains, in elastomers, where the restoring force is entropic. (This is a more advanced topic.)

I think he were looking for this answer! Great explanation.
 

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