Eugene Guth and
Hubert M. James proposed the entropic origins of rubber elasticity in 1941.
Thermodynamics Temperature affects the elasticity of elastomers in an unusual way. When the elastomer is assumed to be in a stretched state, heating causes them to contract. Vice versa, cooling can cause expansion. This can be observed with an ordinary rubber band. Stretching a rubber band will cause it to release heat, while releasing it after it has been stretched will lead it to absorb heat, causing its surroundings to become cooler. This phenomenon can be explained with the
Gibbs free energy. Rearranging Δ
G=Δ
H−
TΔ
S, where
G is the free energy,
H is the
enthalpy, and
S is the entropy, we obtain . Since stretching is nonspontaneous, as it requires external work,
TΔ
S must be negative. Since
T is always positive (it can never reach
absolute zero), the Δ
S must be negative, implying that the rubber in its natural state is more entangled (with more
microstates) than when it is under tension. Thus, when the tension is removed, the reaction is spontaneous, leading Δ
G to be negative. Consequently, the cooling effect must result in a positive ΔH, so Δ
S will be positive there. The result is that an elastomer behaves somewhat like an ideal
monatomic gas, inasmuch as (to good approximation) elastic polymers do
not store any potential energy in stretched chemical bonds or elastic work done in stretching molecules, when work is done upon them. Instead, all work done on the rubber is "released" (not stored) and appears immediately in the polymer as thermal energy. In the same way, all work that the elastic does on the surroundings results in the disappearance of thermal energy in order to do the work (the elastic band grows cooler, like an expanding gas). This last phenomenon is the critical clue that the ability of an elastomer to do work depends (as with an
ideal gas) only on entropy-change considerations, and not on any stored (i.e. potential) energy within the polymer bonds. Instead, the energy to do work comes entirely from thermal energy, and (as in the case of an expanding ideal gas) only the positive entropy change of the polymer allows its internal thermal energy to be converted efficiently into work.
Polymer chain theories Invoking the theory of rubber elasticity, a polymer chain in a cross-linked network may be seen as an
entropic spring. When the chain is stretched, the entropy is reduced by a large margin because there are fewer conformations available. As such there is a restoring force which causes the polymer chain to return to its equilibrium or unstretched state, such as a high entropy
random coil configuration, once the external force is removed. This is the reason why rubber bands return to their original state. Two common models for rubber elasticity are the freely-jointed chain model and the worm-like chain model.
Freely-jointed chain model The freely joined chain, also called an ideal chain, follows the random walk model. Microscopically, the 3D random walk of a polymer chain assumes the overall end-to-end distance is expressed in terms of the x, y and z directions: \vec{R} = R_x\hat{x} + R_y\hat{y} + R_z\hat{z} In the model, b is the length of a rigid segment, N is the number of segments of length b , R is the distance between the fixed and free ends, and L_\text{c} is the "contour length" or Nb. Above the
glass transition temperature, the polymer chain oscillates and r changes over time. The probability distribution of the chain is the product of the probability distributions of the individual components, given by the following Gaussian distribution: P(\vec{R}) = P(R_x) P(R_y) P(R_z) = \left( \frac{2 n b^2 \pi}{3}\right)^{-{3}/{2}} \exp \left( \frac{-3R^2}{2Nb^2} \right) Therefore, the ensemble average end-to-end distance is simply the standard integral of the probability distribution over all space. Note that the movement could be backwards or forwards, so the net average \langle R\rangle will be zero. However, the root mean square can be a useful measure of the distance. \begin{align} \langle R\rangle &= 0 \\ \langle R^2\rangle &= \int_0^\infty R^24\pi R^2 P(\vec{R})dR = Nb^2 \\ \langle R^2\rangle^\frac{1}{2} &= \sqrt{N} b \end{align} The Flory theory of rubber elasticity suggests that rubber elasticity has primarily entropic origins. By using the following basic equations for
Helmholtz free energy and its discussion about entropy, the force generated from the deformation of a rubber chain from its original unstretched conformation can be derived. The \Omega is the number of conformations of the polymer chain. Since the deformation does not involve enthalpy change, the change in free energy can simply be calculated as the change in entropy-T\Delta S. Note that the force equation resembles the behaviour of a spring and follows
Hooke's law: F = kx, where
F is the force,
k is the spring constant and
x is the distance. Usually, the
neo-Hookean model can be used on cross-linked polymers to predict their stress-strain relations: \Omega = C \exp \left ( \frac{-3\vec{R}^2}{2Nb^2} \right ) S = k_\text{B} \ln \Omega \, \approx \frac{-3k_\text{B} \vec{R}^2}{2Nb^2} \Delta F(\vec{R}) \approx -T\Delta S_d(\vec{R}^2) = C+\frac{3 k_\text{B} T}{N b^2} \vec{R}^2 f =\frac{dF(\vec{R})}{d\vec{R}} = \frac{d}{d\vec{R}}\left(\frac{3k_\text{B}T\vec{R}^2}{2Nb^2}\right) = \frac{3k_\text{B}T}{Nb^2} \vec{R} Note that the elastic coefficient 3 k_\text{B} T/N b is temperature dependent. If rubber temperature increases, the elastic coefficient increases as well. This is the reason why rubber under constant stress shrinks when its temperature increases. We can further expand the Flory theory into a macroscopic view, where bulk rubber material is discussed. Assume the original dimension of the rubber material is L_x, L_y and L_z, a deformed shape can then be expressed by applying an individual extension ratio \lambda_i to the length (\lambda_x L_x, \lambda_y L_y, \lambda_z L_z). So microscopically, the deformed polymer chain can also be expressed with the extension ratio: \lambda_x R_x, \lambda_y R_y, \lambda_z R_z. The free energy change due to deformation can then be expressed as follows: \begin{align} \Delta F_\text{def} (\vec{R}) &= - \frac{3k_\text{B}T\vec{R}^2}{2Nb^2} = -\frac{3k_\text{B}T\left(\left(R_x^2-R_{x0}^2\right)+\left(R_y^2-R_{y0}^2\right)+\left(R_z^2-R_{z0}^2\right)\right)} {2Nb^2}\\ &=-\frac{3k_\text{B} T\left(\left(\lambda_x^2-1\right) R_{x0}^2 + \left(\lambda_y^2-1\right) R_{y0}^2 + \left(\lambda_z^2-1\right) R_{z0}^2\right)}{2Nb^2} \end{align} Assume that the rubber is cross-linked and isotropic, the random walk model gives R_x, R_y and R_z are distributed according to a normal distribution. Therefore, they are equal in space, and all of them are 1/3 of the overall end-to-end distance of the chain: \langle R_{x0}^2 \rangle=\langle R_{y0}^2 \rangle = \langle R_{z0}^2 \rangle = \langle R^2 \rangle/3. Plugging in the change of free energy equation above, it is easy to get: \begin{align} \Delta F_\text{def} (\vec{R})&=-\frac{k_\text{B} T n_s \langle R^2 \rangle \left(\lambda_x^2 + \lambda_y^2 + \lambda_z^2 - 3\right)} {2Nb^2}\\ &=-\frac{k_\text{B}T n_s \langle R^2 \rangle \left(\lambda_x^2+\lambda_y^2+\lambda_z^2-3\right)}{2R_0^2} \end{align} The free energy change per volume is just: \Delta f_\text{def} = \frac{\Delta F_\text{def}(\vec{R})}{V} = -\frac{k_\text{B}T v_s \beta \left(\lambda_x^2 + \lambda_y^2 + \lambda_z^2 - 3\right)}{2} where n_s is the number of strands in network, the subscript "def" means "deformation", v_s = n_s / V, which is the
number density per volume of polymer chains, \beta = \langle R^2\rangle / R_0^2 which is the ratio between the end-to-end distance of the chain and the theoretical distance that obey random walk statistics. If we assume incompressibility, the product of extension ratios is 1, implying no change in the volume: \lambda_x \lambda_y \lambda_z = 1. Case study: Uniaxial deformation: In a uniaxial deformed rubber, because \lambda_x \lambda_y \lambda_z = 1 it is assumed that \lambda_x = \lambda_y = \lambda_z^{-1/2}. So the previous free energy per volume equation is: \Delta f_\text{def} = \frac{\Delta F_\text{def}(\vec{R})}{V} = -\frac{k_\text{B}T v_s \beta \left(\lambda_x^2 + \lambda_y^2 + \lambda_z^2 - 3\right)}{2} = \frac{k_\text{B}T v_s\beta}{2} \left(\lambda_z^2 + \frac{2}{\lambda_z}-3\right) The
engineering stress (by definition) is the first derivative of the energy in terms of the extension ratio, which is equivalent to the concept of strain: \sigma_\text{eng}=\frac{d(\Delta f_\text{def})}{\lambda_z} = k_\text{B}T v_s \beta\left(\lambda_z-\frac{1}{\lambda_z^2}\right) and the
Young's Modulus E is defined as derivative of the stress with respect to strain, which measures the
stiffness of the rubber in laboratory experiments. E=\frac{d(\sigma_\text{eng})}{d\lambda_z}=k_\text{B}T v_s \beta \left.\left(1+ \frac{2}{\lambda_z^3}\right)\right|_{\lambda_z=1} = 3 k_\text{B}T v_s\beta = \frac{3\rho \beta RT}{M_s} where v_s = \rho N_a / M_s, \rho is the mass density of the chain, M_s is the number average molecular weight of a network strand between crosslinks. Here, this type of analysis links the thermodynamic theory of rubber elasticity to experimentally measurable parameters. In addition, it gives insights into the cross-linking condition of the materials.
Worm-like chain model The worm-like chain model (WLC) takes the energy required to bend a molecule into account. The variables are the same except that L_\text{p}, the persistence length, replaces b . Then, the force follows this equation: F \approx \frac{k_\text{B} T}{L_\text{p}} \left ( \frac{1}{4 \left( 1- \frac{r}{L_{\rm c}} \right )^2} - \frac{1}{4} + \frac{r}{L_\text{c}} \right ) Therefore, when there is no distance between chain ends (
r=0), the force required to do so is zero, and to fully extend the polymer chain ( r = L_\text{c} ), an infinite force is required, which is intuitive. Graphically, the force begins at the origin and initially increases linearly with r. The force then plateaus but eventually increases again and approaches infinity as the chain length approaches L_\text{c}. ==See also==