Viscoelasticity is the property of a material that exhibits some combination of both elastic or spring-like and viscous or flow-like behavior.
Dynamic mechanical analysis is carried out by applying a sinusoidally varying force to a test specimen and measuring the resulting strain response. By analyzing the material response over one cycle, its elastic-spring-like storage modulus and its viscous or flow-like loss (imaginary) modulus can be determined. Complex modulus is the vector sum of the storage and loss (imaginary) modulus and is used to characterize viscoelastic materials. Because modulus values can be computed for each cycle, DMA is a highly efficient method for measuring viscoelastic material behavior over a range of temperatures and frequencies.
Viscoelasticity and Medical Applications
Like plastics, human biologic materials exhibit viscoelastic behavior. As a result, dynamic mechanical analysis can be used to measure the viscoelasticity of tendons, tissue, medical devices and more. Furthermore, because the modulus values for healthy and diseased tissue vary, doctors and scientists have begun using DMA as a diagnostic tool to detect cancer. For the vast majority of medical applications, DMA is being performed outside the body on a bench. As more sophisticated instruments are developed, however, DMA may become an effective diagnostic tool that can be deployed in-situ.
Characterizing Material Behavior
The relationship between stress and strain can vary over time for different classes of materials under different loading conditions. If the relationship between stress and strain is linear and time independent, then the material is elastic and Hooke’s law describes its behavior.
Hooke’s Law: F = Kx
Where, F = Applied Force, K = Spring Constant, and x = Resulting Displacement.
Metals as long as they are not loaded beyond their yield point or exposed to elevated temperatures exhibit hookean behavior. The majority of materials, however, exhibit complex behavior dependent on their loading conditions. Because of this, their response is deconstructed into easily understood idealized behaviors to simplify their analysis.
Elastic Behavior – Most materials behave elastically or nearly so when a small stress is applied. As shown in the figure below, an immediate elastic strain response, e, is obtained for a small stress, S. The strain remains fixed as long as the stress remains fixed and drops to zero immediately upon removal of the force. Most elastic materials are linearly elastic, thus, the stress-strain behavior is proportional.
Viscoelastic Behavior – Some materials exhibit elastic behavior upon rapid loading followed by a slow and continuous increase of strain at a decreasing rate. When the stress is removed, a continuously decreasing strain follows an initial elastic recovery as shown below.
Materials that exhibit viscoelastic behavior are significantly influenced by the rate of applied stress or strain. The slower the stress rate the greater the corresponding strain. Conversely, the slower the strain rate the lower the corresponding stress, as shown below.
Materials Exhibiting Viscoelastic Behavior
Dynamic Mechanical Analysis
Dynamic mechanical analysis is performed by applying an oscillating stress at varying frequencies to a sample and analyzing the strain response to the applied stress. Figure below depicts the applied sinusoidal stress waveform and the responding strain waveform of a polypropylene sample loaded in tension only. The time lag or phase shift of the strain response is used to quantify its viscous behavior; the slope of the stress-strain response relates to its elastic behavior. These properties are often described as the ability to lose energy as heat and the ability to recover from deformation (elasticity).
For purely elastic or hookean materials, the phase shift, θ=0 and
nd
Where E = Modulus of Elasticity. For purely viscous materials the phase shift, θ = ϖ /2 and the Modulus of Elasticity is undefined. Eq. 2 represents the elastic strain response to the sinusoidally varying stress. The phase angle, θ, between two sinewaves of equal period, T, is given by:Where, dt=time shift between the stress-time and strain-time waveforms and T = period of oscillation.
And the in-phase elastic strain is given by:
And the out of phase imaginary viscous strain is given by:
The vector sum of the in-phase and out-of-phase strains results in a complex strain, e*.
To summarize dynamic mechanical analysis, a sample is subjected to a sinusoidally varying stress of amplitude, So, and frequency, f, or period, T (1/f), and the amplitude, eo, and time shift, dt, of the resulting strain waveform is measured. From this, the phase lag or loss angle, θ, is calculated from Eq. 4 and the elastic or storage modulus, Eʹ, is given by:
The amount of energy lost due to friction and internal motions, called the loss modulus, E˝, is given by:
The tangent of the phase lag or loss angle, tan(θ), is called the loss tangent or damping factor and provides a measure of how much energy is lost due to the viscous nature of the material. We can determine the following viscoelastic properties of the polypropylene sample.