Current research areas

Our research is of theoretical and computational nature, and focuses on nonequilibrium phenomena in extended systems, and in applications of Statistical Mechanics to problems in Biophysics or Biomaterials. In the former case, we aim at understanding the mechanisms underlying the formation and evolution of spatio temporal patterns in systems driven outside of thermodynamic equilibrium, including the transition to spatio temporal chaos in extended systems. We focus on prototypical systems and related experimental configurations in which to address fundamental issues of nonlinear phenomena, as well as on configurations of interest because of their applications in soft matter, materials science, and engineering. In the latter case, we are developing a coarse grained description of biomolecules, including reduced models of a protein that can provide high throughput and moderate resolution models of its structure, extending this description to include solvent mediated interactions, and applying them to ongoing protein engineering efforts.

Block copolymers as a structured material

Block copolymers are being extensively investigated as nanoscale templates for a wide variety of applications that include nanolithography, photonic components, or high density storage systems. However, given the small wavelength of the microphases (tens or hundreds of Angstroms), macroscopic size samples do not completely order through spontaneous self assembly. Instead, oscillatory shears are commonly introduced in order to accelerate long range order development over the required distances. A mesoscopic model of a diblock copolymer is used to study the formation, stability, and coarsening of lamellar phases, including their hydrodynamic response to applied external shears. The focus of our research is on mechanisms controlling long ranged orientational order, including the motion of grain boundaries or other topological defects, and the introduction of a mesoscopic theory of viscoelasticity that can describe the stability and response of these materials to shears, and account for the selection of particular orientations depending on the architecture of the block and the parameters of the shear.

Topological defect motion in modulated phases

Modulated phases are ubiquitous in Nature generally resulting in systems with competing attractive interactions at short distances, and long range repulsion. They are generally characterized by some degree of broken symmetry that is intermediate between fully ordered crystals and completely disordered fluids. We consider general order parameter models that are appropriate for a coarse grained description of modulated phases to address a number of generic non equilibrium features, including slow relaxation accompanying topological defect motion, the breakdown of continuum laws of defect motion and the formation of structural glasses, and their dependence on the symmetry of the phases. We are currently investigating non potential effects, according to which the evolution of the system is not simply determined by the minimization of an appropriate free energy. In particular, we address the consequences of this assumption on extended defect motion, and the possible transition to persistent dynamics and spatio temporal chaos.

Protein-protein interactions

Sequencing of the genomes of several species (including humans) opens the door to a new understanding of biological function, as well as to the possible elucidation of the genetic mechanisms of many diseases, and perhaps to their cure through genetic manipulation. This research aims at improving current computational methods that predict the three dimensional structure of proteins and of protein-protein interactions from the knowledge of their amino acid sequence. Protein function is more closely related to structure than to sequence, and hence methodologies that can produce large scale predictions of protein structure are essential in this post-genomic era. Reduced, lattice based models of proteins, and Monte Carlo simulation methods are used to analyze the relationship between sequence and characteristic structural motifs of the folded protein. Statistical methods are being develop to increase sensitivity in the detection of functional sites and to calculate the thermodynamics parameters that describe protein-protein interactions (formation of dimers, trimers, etc.). The image shows the dimer of GCN4, currently being studied by replica Monte Carlo.

Faraday waves

Parametrically driven surface waves (also known as Faraday waves) can be excited on the free surface of a fluid layer that is periodically vibrated in the direction normal to the surface at rest if the amplitude of the driving acceleration is large enough to overcome the dissipative effect of fluid viscosity. Despite the simplicity of the configuration, this system displays a large number of features that are characteristic of strong nonlinearity, and serves as a prototype of many nonlinear phenomena that are currently under active investigation. Among them we mention the discovery of stationary quasi-periodic patterns of surface standing waves (shown in the figure. This pattern is the analog of a quasi-crystal in solid state physics), the transition to spatio temporal chaos, super-lattice patterns in systems vibrated with two frequency components, coexistence of chaotic and regular regions in extended systems, serving as a laboratory for detailed studies of turbulence, or its analysis in unconventional systems such as viscoelastic fluids or granular materials.