Awarded Projects

This project addresses the fundamental problem of combustion noise in hydrogen flames. To reduce CO2 emissions and reach the targets of the European Green Deal agreements, hydrogen combustion is gaining momentum in the aviation and power generation industries.

The project aims to to obtain ab-initio information about these simpler quantities through our lattice simulations which are now feasible due to the existence of pre exascale computers.

P-type ATPase ion pumps transport ions uphill against their chemical potential to maintain the transmembrane (TM) electrochemical potential in cells which powers vital biological functions such as neuronal signaling, energy transduction and stomach acidification.

Pushing the limits of computational chemistry: the phase diagram of water

Hydrogen-based compounds have been in the spotlight of the condensed matter community since the discovery of high-temperature superconductivity in sulfur hydride under high pressure.

Two-dimensional (2D) materials have already revolutionized science, and have the potential to revolutionize technology due to their unique properties [1–7]. Their electronic properties range from metallic to insulating.

We propose to investigate, with unprecedented accuracy and abundant statistics, the critical phase of the quantum spin glass in two dimensions.

In this proposal, the decay rate of a number of processes mediated by charged and neutral flavor changing currents will be computed.

Integrity of our genomic material is critical for cell survival and faithful inheritance. The newly identified Rahman syndrome (RS) is a rare genetic disease linked to frameshift mutations in the linker-histone H1.4, a critical structural constituent of chromatin, our genomic material.