Maria Fyta
| Office: | 203 |
|---|---|
| Phone: | +49 711 685-63935 |
| Fax: | +49 711 685-63658 |
| Email: | mfyta _at_ icp.uni-stuttgart.de |
| Address: | Junior Prof Maria Fyta Institute for Computational Physics Universität Stuttgart Allmandring 3 70569 Stuttgart Germany |
Open positions
There is an opening for a PhD student working on the multiscale modeling of biologically modified materials, as well as a position for a student (studentische Hilfskraft) (more details).
Research interests
Our work is based on a variety of computational tools, ranging from classical (Monte-Carlo schemes within empirical potential approaches, Molecular Dynamics), semi-empirical (parametrized tight-binding schemes), quantum mechanical (implementations of the density functional theory), and multiscale methodologies (coupled Langevin molecular-dynamics and lattice-Boltzmann method for modeling molecular motion in a fluid solvent).
Integration of biomolecules and materials
Computational modeling can provide an additional view into biophysical systems and processes studied als o through experiments. These often provide insight into time and length scales not easily accessible by experimental setups. Such an insight would be essential when integrating biomolecules and materials to m ake biofunctional materials. These have a high potential to lead to a variety of innovative biotechnolog ical applications, ranging from bio-sensors to templates for programmable self-assembly. Biofunctionaliz ed electrodes are expected to be essential also in the field of ultra-fast sequencing DNA through buffer s which are able to electrophoretically translocate polyelectrolytes. Apart from their bionanotechnologi cal interest, an in depth understanding of the complex behavior of biopolymers on materials and its conn ection to the biomaterial's properties is lacking. In order to unravel the mechanisms that underlie the se complex materials, resort to a theoretical investigation based on sequential and concurrent atomistic
and coarse-grained simulations scannning a wide range of spatial and temporal scales will be attempted. The focus of the proposed research are biomolecules (from a single nucleotide to a short sequence of do
uble-stranded and single-stranded DNA, and short peptides) grafted on surfaces, metallic or semiconducti ng. A comparative study of these materials will unravel those, which have the higher potential to be use d in future relevant applications. For these, the effect of factors, like mechanical or thermal deforma tions occurring on the biomolecule or the surface, as well as the effect of the surrounding fluid solven t and ionic concentration will be studied. The aim is not only to computationally shed light into the un derstanding of the structure and properties of biofunctionalized surfaces, but potentially also guide th e experiments towards their search for potential biotechnological applicati
DNA translocation through narrow pores
Optoelectronic and mechanical properties of carbon nanostructures
Ionic solutions in water
[More details will come soon...]
Publications
[Selected publications]
M. Fyta, Structural and technical details of the Kirkwood-Buff integrals from the optimization of ionic force fields: focus on fluorides, Europ. J. Phys. E. 35, 21 (2012).
M. Fyta and R.R. Netz, Ionic force field optimization based on single-ion and ion-pair solvation properties: going beyond standard mixing rules, J. Chem. Phys. 136(12), 124103 (2012).
M.Fyta, S. Melchionna, and S. Succi,Translocation of biomolecules through solid-state nanopores: theory meets experiments, J. Polym. Sci. B, 49, 985 (2011).
M. Fyta, I. Kalcher, L. Vrbka, J. Dzubiella, and R.R. Netz, Force field optimization of electrolyte solutions based on their thermodynamic properties , J. Chem. Phys, 132, 024911 (2010).
S. Melchionna, M. Bernaschi, M. Fyta, E. Kaxiras, and S. Succi, Quantized biopolymer translocation through nanopores: departure from simple scaling, Phys. Rev. E, 79 030901(R) (2009).
M. Fyta, Simone Melchionna, Efthimios Kaxiras, and Sauro Succi, Multiscale Simulation of Nanobiological flows, Computing in Science and Engineering, 10 10 (2008).
R. L. Barnett, P. Maragakis, A. Turner, M. Fyta, and E. Kaxiras, Multiscale model of electronic behavior and localization in stretched dry DNA, J. Mater. Sci., 42 8894 (2007).
M.G. Fyta, S. Melchionna, E. Kaxiras, and S. Succi, Multiscale coupling of molecular dynamics and hydrodynamics: application to DNA translocation through a nanopore, Multiscale Modeling and Simulation, 5, 1156 (2006).
M. G. Fyta, I. N. Remediakis, P. C. Kelires, and D. A. Papaconstantopoulos, Insights into the strength and fracture mechanisms of amorphous and nanocomposite carbon, Phys. Rev. Lett. 96, 185503 (2006).
M. G. Fyta and P. C. Kelires, Simulations of composite carbon films with nanotube inclusions, Appl. Phys. Lett. 86, 191916 (2005),
M. G. Fyta, I. N. Remediakis and P. C. Kelires, Energetics and stability of nanostructured amorphous carbon, Phys. Rev. B 67, 035423 (2003).