Anelasticity is a property of materials that describes their behaviour when undergoing deformation. Its formal definition does not include the physical or atomistic mechanisms but still interprets the anelastic behaviour as a manifestation of internal relaxation processes. It is a behaviour differing (usually very slightly) from elastic behaviour.
\sigma
\epsilon
\sigma=M\epsilon
\epsilon=J\sigma
M=
| 1 | |
| J |
The constant
M
J
There are three postulates that define the ideal elastic behaviour:
These conditions may be lifted in various combinations to describe different types of behaviour, summarized in the following table:
| Unique equilibrium relationship (complete recoverability) | Instantaneous | Linear | ||
| Ideal elasticity | Yes | Yes | Yes | |
| Nonlinear elasticity | Yes | Yes | No | |
| Instantaneous plasticity | No | Yes | No | |
| Anelasticity | Yes | No | Yes | |
| Linear viscoelasticity | No | No | Yes |
The formal definition of linearity is: "If a given stress history
\sigma1(t)
\epsilon1(t)
\sigma2(t)
\epsilon2(t)
\sigma1(t)+\sigma2(t)
\epsilon1(t)+\epsilon2(t)
In general, the change of an external variable of a thermodynamic system causes a response from the system called thermal relaxation that leads it to a new equilibrium state. In the case of mechanical changes, the response is known as anelastic relaxation, and in the same formal way can be also described for example dielectric or magnetic relaxation. The internal values are coupled to stress and strain through kinetic processes such as diffusion. So that the external manifestation of the internal relaxation behaviours is the stress strain relation, which in this case is time dependant.
Experiments can be made where either the stress or strain is held constant for a certain time. These are called quasi-static, and in this case, anelastic materials exhibit creep, elastic aftereffect, and stress relaxation.
In these experiments a stress applied and held constant while the strain is observed as a function of time. This response function is called creep defined by
J(t)\equiv\epsilon(t)/\sigma0
J(t)
JR
\deltaJ
After a creep experiment has been run for a while, when stress is released the elastic spring-back is in general followed by a time dependent decay of the strain. This effect is called the elastic aftereffect or “creep recovery”. The ideal elastic solid returns to zero strain immediately, without any after-effect, while in the case of anelasticity total recovery takes time, and that is the aftereffect. The linear viscoelastic solid only recovers partially, because the viscous contribution to strain cannot be recovered.
In a stress relaxation experiment the stress σ is observed as a function of time while keeping a constant strain
\epsilon0
M(t)\equiv\sigma(t)/\epsilon0
At equilibrium,
MR=1/JR
MU=1/JU
To get information about the behaviour of a material over short periods of time dynamic experiments are needed. In this kind of experiment a periodic stress (or strain) is imposed on the system, and the phase lag of the strain (or stress) is determined.
\sigma=\sigma0ai\omega
\sigma0
\omega
\epsilon=\epsilon0ai(\omega
\epsilon0
\varphi
\varphi=0
\varphi
\epsilon/\sigma
J\star(\omega)
| ||||
| J |
=|J|(\omega)e-i\phi(\omega)
|J|(\omega)
J\star
\epsilon0/\sigma0
This way two real dynamic response functions are defined,
|J|(\omega)
\varphi(\omega)
| *(\omega)=J | |
| J | |
| 1(\omega)-iJ |
2(\omega)
J1 and J2 being called "storage compliance" and "loss compliance" respectively is significant, because calculating the energy stored and the energy dissipated in a cycle of vibration gives following equations:
\DeltaW=\oint\sigmad\epsilon=\piJ2
| 2 | |
| \sigma | |
| 0 |
\DeltaW
W
W
| \pi/2 | |
| =\int | |
| \omegat=0 |
\sigmad\epsilon=
| 1 | |
| 2 |
J1
| 2 | |
| \sigma | |
| 0 |
The ratio of the energy dissipated to the maximum stored energy is called the "specific damping capacity”. This ratio can be written as a function of the loss angle by
\DeltaW/W=2\pi\tan\phi
This shows that the loss angle
\varphi
The dynamic response functions can only be measured in an experiment at frequencies below any resonance of the system used. While theoretically easy to do, in practice the angle
\varphi(\omega)
The response of a system in a forced-vibration experiment with a periodic force has a maximum of the displacement
x0
\omegar
\phi\ll1
| 2 | |
| x | |
| 0 |
\omega1
\omega2
| 2 | |
| x | |
| 0 |
| \omega2-\omega1 | |
| \omegar |
=Q-1=\phi
The loss angle that measures the internal friction can be obtained directly from the plot, since it is the width of the resonance peak at half-maximum. With this and the resonant frequency it is then possible to obtain the primary response functions. By changing the inertia of the sample the resonant frequency changes, and so can the response functions at different frequencies can be obtained.
The more common way of obtaining the anelastic response is measuring the damping of the free vibrations of a sample. Solving the equation of motion for this case includes the constant
\delta
\delta\simeq\pi\phi
| \delta=ln\left( | An |
| An+1 |
\right)
It is a convenient and direct way of measuring the damping, as it is directly related to the internal friction.
Wave propagation methods utilize a wave traveling down the specimen in one direction at a time to avoid any interference effects. If the specimen is long enough and the damping high enough, this can be done by continuous wave propagation. More commonly, for crystalline materials with low damping, a pulse propagation method is used. This method employs a wave packet whose length is small compared to the specimen. The pulse is produced by a transducer at one end of the sample, and the velocity of the pulse is determined either by the time it takes to reach the end of the sample, or the time it takes to come back after a reflection at the end. The attenuation of the pulse is determined by the decrease in amplitude after successive reflections.
Each response function constitutes a complete representation of the anelastic properties of the solid. Therefore, any one of the response functions can be used to completely describe the anelastic behaviour of the solid, and every other response function can be derived from the chosen one.
The Boltzmann superposition principle states that every stress applied at a different time deforms the material as it if were the only one. This can be written generally for a series of stresses
\sigmai(i=1,2,...,m)
t1',t2',...,tm'
| m\sigma | |
| \epsilon(t)=\sum | |
| iJ(t-t |
i')
| t | ||
| \epsilon(t)=\int | J(t-t') | |
| -infin |
| d\sigma(t') | |
| dt' |
dt'
The controlled variable can always be changed, expressing the stress as a function of time in a similar way:
| t | ||
| \sigma(t)=\int | M(t-t') | |
| -infin |
| d\epsilon(t') | |
| dt' |
dt'
These integral expressions are a generalization of Hooke's law in the case of anelasticity, and they show that material acts almost as they have a memory of their history of stress and strain. These two of equations imply that there is a relation between the J(t) and M(t). To obtain it the method of Laplace transforms can be used, or they can be related implicitly by:
1=MUJ(t)+\int
| t | |
| 0 |
J(t-t'){d\sigma(t')\overdt'}dt'
In this way though they are correlated in a complicated manner and it is not easy to evaluate one of these functions knowing the other. Hover it is still possible in principle to derive the stress relaxation function from the creep function and vice versa thanks to the Boltzamann principle.
It is possible to describe anelastic behaviour considering a set of parameters of the material. Since the definition of anelasticity includes linearity and a time dependant stress–strain relation, it can be described by using a differential equation with terms including stress, strain, and their derivatives.
To better visualize the anelastic behaviour appropriate mechanical models can be used. The simplest one contains three elements (two springs and a dashpot) since that is the least number of parameters necessary for a stress–strain equation describing a simple anelastic solid. This specific basic behaviour is of such importance that a material that exhibits it is called standard anelastic solid.
Since from the definition of anelasticity linearity is required, all differential stress–strain equations of anelasticity must be of first degree. These equations can contain many different constants to the describe the specific solid. The most general one can be written as:
a0\sigma+a
|
+a2\ddot{\sigma}+ ⋅ ⋅ ⋅ =b0\epsilon+b
|
+b2\ddot{\epsilon}+ ⋅ ⋅ ⋅
For the specific case of anelasticity, which requires the existence of an equilibrium relation, additional restrictions must be placed on this equation.
Each stress–strain equation can be accompanied by a mechanical model to help visualizing the behaviour of materials.
In the case where only the constants
a0
b0
To add internal friction to a model, the Newtonian dashpot is used, represented by a piston moving in an ideally viscous liquid. Its velocity is proportional to the applied force, therefore entirely dissipating work as heat.
These two mechanical elements can be combined in series or in parallel. In a series combination the stresses are equal, while the strains are additive. Similarly, for a parallel combination of the same elements the strains are equal and the stresses additive. Having said that, the two simplest models that combine more than one element are the following:
The Voigt model, described by the equation
| J\sigma=\epsilon+\tau\epsilon |
The generalized stress–strain equation for the Maxwell model is
| \tau\sigma+\sigma=\tau | M |
| \epsilon |
Considering the Voigt model, what it lacks is the instantaneous elastic response, characteristic of crystals. To obtain this missing feature, a spring is attached in series with the Voigt model. This is called the Voigt unit. A spring in series with a Voigt unit shows all the characteristics of an anelastic material despite its simplicity. It is differential stress–strain equation it therefore interesting, and can be calculated to be:
JR\sigma+\tau\sigma
| J | |||
|
\sigma
| \epsilon |
The solid whose properties are defined by this equation is called the standard anelastic solid. The solution of this equation for the creep function is:
| J(t)= | \epsilon(t) |
| \sigma0 |
=JR-(JR-J
| ||||
| U)e |
=JU+\delta
| ||||
| (1-e |
),
\tau\sigma
To describe the stress relaxation behaviour, one can also consider another three-parameter model more suited to the stress relaxation experiment, consisting of a Maxwell unit placed in parallel with a spring. Its differential stress–strain equation is the same as the other model considered, therefore the two models are equivalent. The Voigt-type is more convenient in the analysis of creep, while the Maxwell-type for the stress relaxation.
The dynamic response functions
J1
J2
J1(\omega)=J
|
J2(\omega)=\deltaJ
| \omega\tau\sigma | ||||||
|
These are often called the Debye equations since were first derived by P. Debye for the case of dielectric relaxation phenomena. The width of the peak at half maximum value for
J2
\Delta(log10\omega\tau)=1.144
The equation for the internal friction
\phi
\deltaJ\llJU
\phi\cong\Delta
| \omega\tau | |
| 1+\omega2\tau2 |
The relaxation strength
\Delta
\tau
The dynamic properties plotted as function of
\omega\tau
\tau
\omega
\tau
\omega
The basis of why this is possible is that in many cases the relaxation rate
\tau-1
\tau-1
| -Q/kT | |
| =v | |
| 0e |
T
vo
Q
k
Therefore, where this equation applies, the quantity
\tau
The next level of complexity in the description of an anelastic solid is a model containing n Voigt units in series with each other and with a spring. This corresponds to a differential stress–strain equation which contains all terms up to order n in both the stress and the strain. Similarly, a model containing n Maxwell units all in parallel with each other and with a spring is also equivalent to a differential stress–strain equation of the same form.
In order to have both elastic and anelastic behaviour, the differential stress–strain equation must be of the same order in the stress and strain and must start from terms of order zero.
A solid described by such function shows a “discrete spectrum” of relaxation processes, or simply a "discrete relaxation spectrum". Each "line" of the spectrum is characterized by a relaxation time
| (i) | |
| \tau | |
| \sigma |
\delta
| (i) | |
| J | |
| \sigma |
A technique that measures internal friction and modulus of elasticity is called Mechanical Spectroscopy. It is extremely sensitive and can give information not attainable with other experimental methodologies.
Despite being historically uncommon, it has some great utility in solving practical problems regarding industrial production where knowledge and control of the microscopic structure of materials is becoming more and more important. Some of these applications are the following.
Unlike other chemical methods of analysis, mechanical spectroscopy is the only technique that can determine the quantity of interstitial elements in a solid solution.
In body centered cubic structures, like iron's, interstitial atoms position themselves in octahedral sites. In an undeformed lattice all octahedral positions are the same, having the same probability of being occupied. Applying a certain tensile stress in one direction parallel to a side of the cube dilates the side while compressing other orthogonal ones. Because of this, the octahedral positions stop being equivalent, and the larger ones will be occupied instead of the smallest ones, making the interstitial atom jump from one to the other. Inverting the direction of the stress has obviously the opposite effect. By applying an alternating stress, the interstitial atom will keep jumping from one site to the other, in a reversible way, causing dissipation of energy and a producing a so-called Snoek peak. The more atoms take part in this process the more the Snoek peak will be intense. Knowing the energy dissipation of a single event and the height of the Snoek peak can make possible to determine the concentration of atoms involved in the process.
Grain boundaries in nanocrystalline materials form are significant enough to be responsible for some specific properties of these types of materials. Both their size and structure are important to determine the mechanical effects they have. High resolution microscopy show that material put under severe plastic deformation are characterized by significant distortions and dislocations over and near the grain boundaries.
Using mechanical spectroscopy techniques one can determine whether nanocrystalline metals under thermal treatments change their mechanical behaviour by changing their grain boundaries structure. One example is nanocrystalline aluminium.
Mechanical spectroscopy allows to determine the critical points martensite start
Ms
Mf
Ms
Ferromagnetic materials have specific anelastic effects that influence internal friction and dynamic modulus.
A non-magnetized ferromagnetic material forms Weiss domains, each one possessing a spontaneous and randomly directed magnetization. The boundary zones, called Bloch walls, are about one hundred atoms long, and here the orientation of one domain gradually changes into the one of the adjacent one. Applying an external magnetic field makes domains with the same orientations increase in size, until all Bloch walls are removed, and the material is magnetized.
Crystalline defects tend to anchor the domains, opposing their movement. So, materials can be divided into magnetically soft or hard based on how much the walls are strongly anchored.
In these kind of materials magnetic and elastic phenomena are correlated, like in the case of magnetostriction, that is the propriety of changing size when under a magnetic field, or the opposite case, changing magnetic properties when a mechanical stress is applied. These effects are dependent on the Weiss domains and their ability to re-orient.
When a magnetoelastic material is put under stress, the deformation is caused by the sum of the elastic and magnetoelastic ones. The presence of this last one changes the internal friction, by adding an additional dissipation mechanism.