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Materials science and engineering aims at understanding the relationship between structure, processing and properties of materials to optimize their performance. In this course we attempt to establish this connection to interpret the macroscopic behavior of materials (e.g., why does rubber deform easier than steel) by penetrating different length scales (atomistic, mesoscopic) and identifying the critical characteristics and the pertinent mechanisms. We will examine the role of structure or the absence thereof in determining material properties, as well as how these properties depend on the operating conditions (e.g., why does the stiffness of amorphous polymers fall so drastically beyond a critical temperature). The course emphasises on mechanical properties and to a lesser degree on thermal properties. (Optical, electrical and magnetic properties could only be included on a rudimentary level and are excluded in favor of a more thorough understanding of the former.)

The concept of continuous medium. Introduction to tensor calculus and basic theorems of vector analysis. The Kinematics of continuous medium. Material derivative. Speed ​​and acceleration. The function of the deformation and the tensor of committees. Laws Balance. The principle of conservation of energy. The theorem transport. The power in the continuum and the tensor voltage Cauchy. The type of Cauchy. The balance of momentum equation of Euler. The balance of angular momentum and the symmetry of the tensor voltage. The balance of power. Constitutive relations. The elasticity and the law of Hooke. Constitutive behavior of fluids. Boundary value problems of elasticity and fluid mechanics.