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can rarely be tested on a large scale, but attempts have been made to monitor known landslide sites or earthquake source sites, or to conduct large liquefaction experiments.

      Physically, instability may mean many things depending on the type of material and on the geometrical scale of consideration. In the plainest case, a macroscopically homogeneous material element in a laboratory under sufficiently low stress deforms in a homogeneous manner when a uniform traction is applied at its boundary. However, for unspecified physical reasons, at a certain stress level it responds with an unconstrained strain to, for example, a small stress perturbation. Often, the homogeneous strain is associated with a diffuse dilatancy (increased volume). This is a classical representation of instability. The key point is the homogeneity of the response maintained during the unstable phase.

      Alternatively, we perceive as critical a loss of uniqueness of response, which means that a repetition of what is theoretically the same experiment would yield a different, still homogeneous, response. An additional option is to treat as unstable a response in which the increase in internal energy over a virtual displacement is less than the work of the external forces. Each of the above critical conditions, in principle, leads to a different criterion, both locally and globally.

      A mathematical representation of the physics above is equally complex. Often, Lyapunov-type instability (defined as an unconstrained response to a limited perturbation) is implied to result from the solution of a system of differential equations describing the nonlinear material behavior. The instability consists of bifurcation of the solution of the system of equations, which clearly implies that the solution is not unique.

      The criteria for exclusion of instability may be local (or for uniformly deformed systems) or global for a piece of continuum. There are several different criteria, expressing very similar, but not identical conditions.

      To start with we will limit ourselves to considering exclusively incipient elastoplastic straining at small strains. At the moment, we will not deal with materials that exhibit strong viscous effects.

      That implies that variables such as temperature, chemical mass removal (accretion) and ion concentration of pore fluid essentially affect the geomaterial strength, apparent preconsolidation pressure and elasto-plastic stiffness.

      As is customary in inelasticity theories, the deformation can only be uniquely determined for an incremental stress, rather than total stress, as in elasticity. Therefore, the plastic strain rate is defined as

is the yield locus gradient, but for a number of reasons it is often seen as convenient to ignore the difference.

      Non-associativity, i.e. when PijQij (for instance via an elasto-plastic coupling), or any other forms of irreversible (not necessarily mechanical) straining leading to a non-symmetrical stress–strain incremental relationship, are notorious for inducing a premature loss of stability and/or strain localization.

      Among several