A model attempts to capture the underlying principles and mechanisms that govern a system behaviour through mathematical equations and is normally based on certain simplifying assumptions of the component behaviour. A model can typically be used to simulate the material as well as the system under different conditions, so as to predict their behaviour in situations where experimental observations are difficult. It is worth noting that in practice, we may have models that have a mathematical form without an understanding of physics, or models that describe the physics of the system, but may not be expressed in a specific mathematical form.

In what follows, we will outline the complexity of material and its response in engineering. Several modelling approaches, which attempt to understand and predict the material response, are also discussed briefly. In this overview, we will recollect many popular terms that are used in material modelling. These terms are italicized, without a definition at this stage. However, they will be defined more precisely in later chapters, along with concepts related to them.

We will now outline few specific materials and their responses. Polymeric membranes, fiber reinforced composites are known to be anisotropic in their mechanical response. Many materials like polymers are ‘viscoelastic’ in nature and exhibit a definite time dependent mechanical response. The same polymers show a time independent, large deformational response when they are deformed at temperatures above their ‘glass transition temperature’. We also know of the existence of special metals such as ‘shape memory alloys’, which show drastic changes in their mechanical response when they are heated by about 50°C, causing a phase transition within the material. There are ‘piezoelectric materials’ which are able to convert electrical energy to mechanical energy and vice-versa. Further, their electromechanical response is a function of the state of stress and the frequency of loading. Many engineering fluids show a ‘linear stress-strain rate’ response, which is characterized by a parameter called as ‘viscosity’. However, there are other materials such as grease and paint, whose viscosity is dependent upon the state of stress at which the flow occurs. Blood clotting is a phenomenon where the material changes from a fluid to a solid. Mechanical response of blood during clotting can be understood only if biochemical reactions are also included in the model. The reasons for such complex material behaviour is also emphasized by analyzing multiple time scales of response and multiple length scales of response. The complexity of loadings, material make-up and its response is captured schematically in Fig. 1.1.

It is always desirable to capture all the features that are observations of material response through a mathematical model. Clearly, a mathematical model for any material that can accurately capture the response observed in experiments for any of the materials listed above, is quite complex. The mathematical model that we operate with, should reflect our own understanding of the material response. For example, we know from history of strength of materials that earlier attempts were made to correlate the load applied on any solid to the elongation experienced by it. It took about hundred years of evolution to prove that this attempt is faulty and correlations should really be found between a concept called stress which is defined as load per unit area and a concept called strain, which is the deformation per unit length. A further evolution led to the visualization of stresses and strains as second order tensors. An assumption that these two tensors are linearly related, led to a formulation that is popularly known as linear elasticity. Experimental observations on materials like rubber, proved that load measures like stress and the deformation measures like strain will not always be related to each other linearly. The mechanical response of materials like rubber emphasized the need to introduce a configurational (deformation) dependence of stresses and the need for alternate deformational measures like deformation gradients. A redefinition of the kinetic (load related) measures and kinematic (deformation dependent) measures and their relationships are the main considerations in continuum mechanics. This framework is common to materials all classes of materials such as solidlike, fluidlike or gases.

It is worth noting that materials like metals and ceramics are clearly known to be solids and materials like water and oil are known to be fluids. Popularly, the response of solids has been considered through material model of linear elasticity. Similarly, the response of fluids has been considered through models of Newtonian or inviscid fluid. This in highlighted in Fig. 1.2. in the form of most widely used material models. On the other hand, polymers and granular materials are known to exhibit features of both solids and fluids. Hence, the use of terms such as solidlike and fluidlike is necessary to describe the response of materials.

Mathematical framework for the description of the state of a material is formulated based on abstract notions and quantities. Abstract quantities such as force, velocity, stress and strain are used to define the state of a material. These quantities are visualized to be either scalars, vectors or tensors, having multiple components at any given point. However, experimental observations that can characterize the material, to the same detail as the mathematical framework, are generally not possible. For example, the only mechanical quantities that are measured for any material point are displacements and the time of observation. All other abstract quantities such as strains, velocities, accelerations, forces etc. are inferred from these basic observations. Consider, for example, experimental characterization of a piezo-electric material such as poly vinylidene flouride (PVDF). This material is primarily available and used in the form of thin sheets (25 – 100 mm). Testing of PVDF films in all the prescribed directions is not easy. Hence, often experimentalists perform some controlled experiments such as a uniaxial tension tests which provide data of load vs. longitudinal / transverse displacement. The constants that are demanded by a mathematical framework are often interpreted from the basic data collected from these simple tests. The interpretation of constants does lead a certain degree of uncertainty, since the interpretation of the same constant, for the same material, from two different tests may not always match with each other.

The mathematical models for any material can be assessed through comparisons with experimental observations. As mentioned above, these experimental observations are limited in nature. Hence, it is possible that there may be different mathematical models that are ‘equally’ successful in capturing the experimental observations. While it is necessary for a mathematical model to capture an experimentally observed phenomenon, this ability alone is not sufficient for the general applicability of the model in diverse situations. It is useful to classify different modelling approaches that are used in engineering practice. These are outlined in the next section.

Let us continue with our example and compare the response of the polymer in stress relaxation with other well known materials, such as steel or water. An observation can be made that the polymer response is in some way a combination of the responses of these two types of responses, namely elastic and viscous. Therefore, one can make hypothesis about material being viscoelastic and construct mathematical model, which in certain limits reduces to elastic or viscous behaviour. Such models will be called phenomenological models, because the overall material response serves as a guide in building of the models. An example of such model is Maxwell model, which predicts that stress will decrease exponentially in a stress relaxation experiment. The constants used in the exponential form can be called material constants of Maxwell model, as they will be different for different materials.

With increasing theoretical development at the microscopic scale and computational resources, we can talk of another set of models, i.e., micromechanical models. Such a model draws recourse to the make-up of material in its more elementary forms such as atoms, molecules, agglomerates, networks, phases etc. In our example of stress relaxation in a plastic, polymer would be considered as a collection of molecular segments. A hypothesis can be made about the mechanical response of a segment. The response of bulk polymer can be obtained if we are able to develop a mathematical model for a collection of polymer segments. Of course, such a model will also lead to decreasing stress at the bulk scale and material constants at the bulk scale.

More often than not, it is a combination of these approaches, empirical, phenomenological and microscopic, that is used by engineers to understand and predict material behaviour. Each of them is useful in a specific context. In the following discussion, we outline their strengths and limitations.