HOOKE'S LAW

In physics, 'Hooke's law' of elasticity is an approximation that states that the amount by which a material body is deformed (the strain) is linearly related to the force causing the deformation (the stress). Materials for which Hooke's law is a useful approximation are known as linear-elastic or "Hookean" materials.
Hooke's law is named after the 17^th century British physicist Robert Hooke. He first stated this law in 1676 as an anagram, then in 1678 in Latin as ''Ut tensio, sic vis'', which means:
For systems that obey Hooke's law, the extension produced is directly proportional to the load:
:$overrightarrow\{F\}=-koverrightarrow\{x\}$
where
: ''x'' is the distance by which the material is elongated [usually in meters],
: ''F'' is the restoring force exerted by the material [usually in newtons], and
: ''k'' is the 'force constant' (or 'spring constant'). The constant has units of force per unit length [usually in newtons per meter].
When this holds, we say that the behavior is linear. If shown on a graph, the line should show a direct variation.
Hooke's law mathematically follows from the fact that a solid is just a collection of atoms in equilibrium with each other (thus having minimal potential energy). Potential energy curves near minima (and maxima) are dominated by quadratic term (=have nearly parabolic shape). Thus the restoring force being the derivative of this energy (''F'' = -d''U''/d''r'') must be directly proportional to small displacement from equilibrium dr (with the minus sign for minima and plus for maxima of potential energy curve).

Contents

Elastic materials

The spring equation

Multiple springs

Derivation

Tensor expression of Hooke's Law

Isotropic materials

Zero-length springs

See also

References

External links

Elastic materials

Objects that quickly regain their original shape after being deformed by a stress, with the molecules or atoms of their material returning to the initial state of stable equilibrium, often obey Hooke's law.
We may view a rod of any elastic material as a linear spring. The rod has length ''L'' and cross-sectional area ''A''. Its extension (strain) is linearly proportional to its tensile stress, ''σ'' by a constant factor, the inverse of its modulus of elasticity, ''E'', hence,
:
or
:
Hooke's law only holds for some materials under certain loading conditions. Steel exhibits linear-elastic behavior in most engineering applications; Hooke's law is valid for it throughout its 'elastic range' (i.e., for stresses below the yield strength). For some other materials, such as aluminium, Hooke's law is only valid for a portion of the elastic range. For these materials a proportional limit stress is defined, below which the errors associated with the linear approximation are negligible.
Rubber is generally regarded as a "non-hookean" material because its elasticity is stress dependent and sensitive to temperature and loading rate.
Applications of the law include spring operated weighing machines, stress analysis and modeling of materials.

The spring equation

The most commonly encountered form of Hooke's law is probably the 'spring equation', which relates the force exerted by a spring to the distance it is stretched by a 'spring constant', ''k'', measured in force per length.
:$F=-kx,$
The negative sign indicates that the force exerted by the spring is in direct opposition to the direction of displacement. It is called a "restoring force", as it tends to restore the system to equilibrium.
The potential energy stored in a spring is given by
:$U=\{1over2\}kx^2$
which comes from adding up the energy it takes to incrementally compress the spring. That is, the integral of force over distance. (Note that potential energy of a spring is always positive.)
This potential can be visualized as a parabola on the ''U''-''x'' plane. As the spring is stretched in the positive x-direction, the potential energy increases (the same thing happens as the spring is compressed). The corresponding point on the potential energy curve is higher than that corresponding to the equilibrium position (''x'' = 0). The tendency for the spring is to therefore decrease its potential energy by returning to its equilibrium (unstretched) position, just as a ball rolls downhill to decrease its gravitational potential energy.
If a mass is attached to the end of such a spring the system becomes a harmonic oscillator, it will oscillate with a 'natural frequency' given as either:
:$omega\; =\; sqrt\{k\; over\; m\}$ radians per second (angular frequency)
or
:$f\; =\; \{1\; over\; 2\; pi\}\; sqrt\{k\; over\; m\}$ hertz (cycles per second)
since
:$omega\; =\; \{2\; pi\; f\}$

Multiple springs

When two springs are attached to a mass and compressed, the following table compares values of the springs.
{| border="1" cellpadding="5" cellspacing="0" align="center"
! style="background:#ffdead;" | Comparison
! style="background:#ffdead;" | In Series
! style="background:#ffdead;" | In Parallel
|-
|
| align="center" |
| align="center" |
|-
| align="center" | Equivalent
spring constant
| align="center" |
| align="center" | $k\_\{eq\}\; =\; k\_1\; +\; k\_2\; ,$
|-
| align="center" | Compressed
distance
| align="center" |
| align="center" | $x\_1\; =\; x\_2\; ,$
|-
| align="center" | Energy
stored
| align="center" |
| align="center" |
|}

Derivation

Equivalent Spring Constant (Series)

Deriving $k\_\{eq\}$ in the series case is a little trickier than in the parallel case. Defining the equilibrium position of the block to be $x\_2$, we'll be looking for equation for the force on the block that looks like:
::$F\_b\; =\; -k\_\{eq\}\; x\_2\; .,$
To begin, we'll also define the equilibrium position of the point between the two springs to be $x\_1$.
The force on the block is
::$F\_b\; =\; -\; k\_2\; left(\; x\_2\; -\; x\_1$
ight). quad quad quad (1) ,
Meanwhile, the force on the point between the two springs is
::$F\_s\; =\; -\; k\_1\; x\_1\; +\; k\_2\; (x\_2\; -\; x\_1).\; ,$
Now, when the block is pushed so the springs are compressed and the system is allowed to come to equilibrium, the force between the strings must sum to zero, so with $F\_s\; =0$ we can solve for $x\_1\; ,$:
::$-\; k\_1\; x\_1\; +\; k\_2\; (x\_2\; -\; x\_1)\; =\; 0\; ,$
::$-\; k\_1\; x\_1\; -\; k\_2\; x\_1\; =\; -k\_2\; x\_2\; ,$
::$left(k\_1\; +\; k\_2$
ight) x_1 = k_2 x_2 ,
so
::
Now we just plug this back into (1):
::{|
|$F\_b\; ,$
|$=\; -k\_2\; x\_2\; +\; k\_2\; x\_1\; ,$
|-
|
|
ight) ,
|-
|
|
ight) + rac{k_2^2}{k_1 + k_2} x_2 ,
|-
|
|
|}
Finally, the force on the block has been found:
::
ight) x_2 .,
So we can define everything in the parenthesis to be
::
Which can also be written:
::



Equivalent Spring Constant (Parallel)

Both springs are touching the block in this case, and whatever distance spring 1 is compressed has to be the same amount spring 2 is compressed.
The force on the block is then:
::{|
|$F\_b\; ,$
|$=\; F\_1\; +\; F\_2\; ,$
|-
|
|$=\; -k\_1\; x\; -\; k\_2\; x\; ,$
|}
So the force on the block is
::$F\_b\; =\; -\; (k\_1\; +\; k\_2)\; x.\; ,$
Which is why we can define the equivalent spring constant as
::$k\_\{eq\}\; =\; k\_1\; +\; k\_2\; .\; ,$



Compressed Distance

In the case where two springs are in series, the magnitude of the force of the springs on each other are equal:
::{|
|$|F\_1|\; =\; |F\_2|\; ,$
|-
|$k\_1\; x\_1\; =\; k\_2\; left(x\_2\; -x\_1$
ight). ,
|}
For spring 1, x₁ is the distance from equilibrium length, and for spring 2, x₂ - x₁ is the distance from its equilibrium length. So we can define
::$a\_1\; =\; x\_1\; ,$
::$a\_2\; =\; x\_2\; -\; x\_1.\; ,$
Plug these definitions into the force equation, and we'll get a relationship between the compresed distances for the 'in series' case:
::



Energy Stored

For the 'series' case, the ratio of energy stored in springs is:
::
but a there is a relationship between a₁ and a₂ derived earlier, so we can plug that in:
::
ight)^2 = rac{k_2}{k_1} . ,
For the 'parallel' case,
::
because the compressed distance of the springs is the same, this simplifies to
::

Tensor expression of Hooke's Law

When working with a three-dimensional stress state, a 4^th order tensor (''c_ijkl'') containing 81 elastic coefficients must be defined to link the stress tensor (σ_''ij'') and the strain tensor (or Green tensor) (ε_''kl'').
:
Due to the symmetry of the stress tensor, strain tensor, and stiffness tensor, only 21 elastic coefficients are independent.
As stress is measured in units of pressure and strain is dimensionless, the entries of ''c_ijkl'' are also in units of pressure.
Generalization for the case of large deformations is provided by models of neo-Hookean solids and Mooney-Rivlin solids.

Isotropic materials

(see viscosity for an analogous development for viscous fluids.)
Isotropic materials are characterized by properties which are independent of direction in space. Physical equations involving isotropic materials must therefore be independent of the coordinate system chosen to represent them. The strain tensor is a symmetric tensor. Since the trace of any tensor is independent of coordinate system, the most complete coordinate-free decomposition of a symmetric tensor is to represent it as the sum of a constant tensor and a traceless symmetric tensor. Thus:
:
ight) +left(arepsilon_{ij}-rac{1}{3}arepsilon_{kk}delta_{ij}
ight)
where $delta\_\{ij\}$ is the Kronecker delta. The first term on the right is the constant tensor, also known as the pressure, and the second term is the traceless symmetric tensor, also known as the shear tensor.
The most general form of Hooke's law for isotropic materials may now be written as a linear combination of these two tensors:
:
ight)
+2Gleft(arepsilon_{ij}-rac{1}{3}arepsilon_{kk}delta_{ij}
ight),
where ''K'' is the bulk modulus and ''G'' is the shear modulus.
Using the relationships between the elastic moduli, these equations may also be expressed in various other ways. For example, the strain may be expressed in terms of the stress tensor as:
:
u(sigma_{22}+sigma_{33})
ight)
:
u(sigma_{11}+sigma_{33})
ight)
:
u(sigma_{11}+sigma_{22})
ight)
:
:
:
where ''Y'' is the modulus of elasticity and $$
u is Poisson's ratio. (See 3-D elasticity).

Derivation of Hooke's law in 3D

The 3-D form of Hooke's law can be derived using Poisson's ratio and the 1-D form of Hooke's law as follows.
Consider the strain and stress relation as a superposition of two effects: stretching in direction of the load (1) and shrinking (caused by the load) in perpendicular directions (2 and 3),
:,
:
uarepsilon_1,
:
uarepsilon_1,
where $$
u is the Poisson's ratio and $E$ the Young Modulus.
We get similar equations to the loads in directions 2 and 3,
:
uarepsilon_2,
:,
:
uarepsilon_2,
and
:
uarepsilon_3,
:
uarepsilon_3,
:.
Summing the three cases together () we get
:
u(sigma_2+sigma_3))
:
u(sigma_1+sigma_3))
:
u(sigma_1+sigma_2))
or by adding and subtracting one $$
usigma
:
u)sigma_1-
u(sigma_1+sigma_2+sigma_3))
:
u)sigma_2-
u(sigma_1+sigma_2+sigma_3))
:
u)sigma_3-
u(sigma_1+sigma_2+sigma_3))
and further we get by solving $sigma\_1$
:
u}arepsilon_1 + rac{
u}{1+
u}(sigma_1+sigma_2+sigma_3).
Calculating the sum
:
u)sum_{i=1,2,3}sigma_i - 3
u(sum_{i=1,2,3}sigma_i)) = rac{1-2
u}{E}sum_{i=1,2,3}sigma_i
:
u}(arepsilon_1 + arepsilon_2 +arepsilon_3)
and substituting it to the equation solved for $sigma\_1$ gives
:
u}arepsilon_1 + rac{E
u}{(1+
u)(1-2
u)}(arepsilon_1 + arepsilon_2 +arepsilon_3),
:,
where $mu$ and $lambda$ are the Lamé parameters.
Similar treatment of directions 2 and 3 gives the Hooke's law in three dimensions.

Zero-length springs

"Zero-length spring" is the standard but misleading term for a "constant force spring." Hooke's law does not apply in some special physical conditions. In 1932 Lucien LaCoste invented the zero-length spring. A zero-length spring has a physical length equal to its stretched length. Its force is proportional to its entire length, not just the stretched length, and its force is therefore constant over the range of flexures in which the spring is elastic (that is, it does not follow Hooke's Law).
Theoretically, with infinite mass, a pendulum using such a spring (or almost any other spring, as well) as a return can have an infinite natural period. Long-period pendulums enable seismometers to sense the slowest, most penetrating waves of distant earthquakes. Zero-length springs also find use in gravimeters, which need them to have linear sense-pendulums. Some door springs, especially for screen doors, are zero-length springs to reduce the energy of a slammed door. Zero-length springs sometimes smooth auto suspensions.
Physically, one common form of a practical zero-length spring is a leaf-spring curled almost in a circle, with the ends mounted to flexible restraints. A convenient form is a helical spring whose wire is twisted while it is being wound (common in screen-door springs). Another common design is a torque-spring or bar. Zero-length springs usually require special compliant mountings, sometimes require precise adjustments to enter zero-length mode, and often have a limited range of motion.

See also

★ Elastic limit

★ Elastic potential energy

★ Scientific laws named after people

★ Solid mechanics

References

★ A.C. Ugural, S.K. Fenster, ''Advanced Strength and Applied Elasticity'', 4th ed

External links

★ A Biography of Lucien LaCoste, inventor of the zero-length spring

★ Zero Length Springs in Seismometers

★ Hooke's law on PlanetPhysics

★ Mechanics, Symon, Keith, , , Addison-Wesley, Reading, MA, 1971, ISBN 0-201-07392-7

★ Video Lecture on Hooke's Law by MIT Physics Professor Walter Lewin