Abstract
Apart from not having crystallized, supercooled liquids can be considered as being properly equilibrated and thus can be described by a few thermodynamic control variables. In contrast, glasses and other amorphous solids can be arbitrarily far away from equilibrium and require a description of the history of the conditions under which they formed. In this paper we describe how the locality of interactions intrinsic to finite-dimensional systems affects the stability of amorphous solids far off equilibrium. Our analysis encompasses both structural glasses formed by cooling and colloidal assemblies formed by compression. A diagram outlining regions of marginal stability can be adduced which bears some resemblance to the quasi-equilibrium replica meanfield theory phase diagram of hard sphere glasses in high dimensions but is distinct from that construct in that the diagram describes not true phase transitions but kinetic transitions that depend on the preparation protocol. The diagram exhibits two distinct sectors. One sector corresponds to amorphous states with relatively open structures, the other to high density, more closely packed ones. The former transform rapidly owing to there being motions with no free energy barriers; these motions are string-like locally. In the dense region, amorphous systems age via compact activated reconfigurations. The two regimes correspond, in equilibrium, to the collisional or uniform liquid and the so-called landscape regime, respectively. These are separated by a spinodal line of dynamical crossovers. Owing to the rigidity of the surrounding matrix in the landscape, high-density part of the diagram, a sufficiently rapid pressure quench adds compressive energy which also leads to an instability toward string-like motions with near vanishing barriers. Conversely, a dilute collection of rigid particles, such as a colloidal suspension leads, when compressed, to a spatially heterogeneous structure with percolated mechanically stable regions. This jamming corresponds to the onset of activation when the spinodal line is traversed from the low density side. We argue that a stable glass made of sufficiently rigid particles can also be viewed as exhibiting sporadic and localized buckling instabilities that result in local jammed structures. The lines of instability we discuss resemble the Gardner transition of meanfield systems but, in contrast, do not result in true criticality owing to being short-circuited by activated events. The locally marginally stable modes of motion in amorphous solids correspond to secondary relaxation processes in structural glasses. Their relevance to the low temperature anomalies in glasses is also discussed.
Highlights
Motto of Paris, FranceRigidity can emerge, seemingly miraculously, from the interaction of many pieces that are loosely connected: Tents, arches, and domes are among the earliest inventions of humans
An apparently distinct view of the emergence of rigidity in amorphous solids more suited to the molecular scale has emerged, based on the notions of aperiodic crystals and the complexity of the free energy landscapes of disordered systems that have a thermodynamically large number of aperiodic minima. This view comes to terms with the fact that the molecular constituents of amorphous solids are in a state of cease-less atomic motion
We have analyzed the activated events and instabilities in the amorphous solids in an approximation that accounts for the exponential multiplicity of glassy aperiodic crystals but that neglects the fluctuations in specific volume, energy, and configurational entropy that inevitably arise from this diversity
Summary
Seemingly miraculously, from the interaction of many pieces that are loosely connected: Tents, arches, and domes are among the earliest inventions of humans. No thermodynamic quantities experience a singularity at ρA in the meanfield theory nor at ρcr in the finite-dimensional analysis This has been made clear by using the replica symmetry breaking formalism.[49] At temperatures below Tcr the aperiodic structure represented by {ri} persists locally for long times compared to vibrational times but eventually transforms in an activated fashion so that the liquid can flow. It is not difficult to convince oneself that such a solution to the nonlinear elastic balance always exists, as is explicitly illustrated in Figure 4 for hard spheres: As a practical matter, it is most convenient to first find and plot the sets of quenched states (φ, p) that would relax locally into a particular equilibrated state (φeq, peq), because the equilibrium EOS has a discontinuity in slope at the Kauzmann state (φK, pK). A larger region is only metastable on the time scale defined by the barrier from eq
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