HYDROTRONICS | Hydrodynamic electronics

Summary
Advances in fabrication of ultra-pure low-dimensional materials have led in recent years to the emergence of a new area of research -- hydrodynamic electronics. Modern technologies allow for routine manufacturing of ultra-clean samples where observable physical properties are dominated by electron-electron collisions. Electrons in such systems obey the laws of hydrodynamics, which manifests itself in non-local, superballistic, and turbulent transport of energy and electric charge. Following the immense success of graphene research, many novel two-dimensional materials are currently being investigated aiming at potential applications in nanoelectronics, as well as energy conversion and storage. Last years have seen an explosion of interest, both experimental and theoretical, in the hydrodynamic effects in interacting electron systems in ultra-pure materials. The principle aims of HYDROTRONICS are (i) to build a framework to describe hydrodynamic charge and energy transport fine-tuned to the material properties and sample geometry, and (ii) to investigate the physics of novel materials that can be uncovered by transport measurements. Combining the microscopic and macroscopic methods to interacting electronic systems will allow for a unique perspective and yield a powerful approach to transport phenomena that can be easily adapted to new materials and experimental settings, as they become accessible in the course of rapid technological progress. Strong collaboration between the groups involved in the project and its overall synergy will allow novel ideas to flourish, promoting a fertile environment in which early-stage researchers can develop their own paths and resolve the biggest issues in the field. Another important goal is a closer integration between the experimental, theoretical, and computational (software development) parts of the network, which will be an important element exposing practitioners in each area to cutting edge progress in the others.
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Web resources: https://cordis.europa.eu/project/id/873028
Start date: 01-12-2019
End date: 31-05-2025
Total budget - Public funding: 524 400,00 Euro - 506 000,00 Euro
Cordis data

Original description

Advances in fabrication of ultra-pure low-dimensional materials have led in recent years to the emergence of a new area of research -- hydrodynamic electronics. Modern technologies allow for routine manufacturing of ultra-clean samples where observable physical properties are dominated by electron-electron collisions. Electrons in such systems obey the laws of hydrodynamics, which manifests itself in non-local, superballistic, and turbulent transport of energy and electric charge. Following the immense success of graphene research, many novel two-dimensional materials are currently being investigated aiming at potential applications in nanoelectronics, as well as energy conversion and storage. Last years have seen an explosion of interest, both experimental and theoretical, in the hydrodynamic effects in interacting electron systems in ultra-pure materials. The principle aims of HYDROTRONICS are (i) to build a framework to describe hydrodynamic charge and energy transport fine-tuned to the material properties and sample geometry, and (ii) to investigate the physics of novel materials that can be uncovered by transport measurements. Combining the microscopic and macroscopic methods to interacting electronic systems will allow for a unique perspective and yield a powerful approach to transport phenomena that can be easily adapted to new materials and experimental settings, as they become accessible in the course of rapid technological progress. Strong collaboration between the groups involved in the project and its overall synergy will allow novel ideas to flourish, promoting a fertile environment in which early-stage researchers can develop their own paths and resolve the biggest issues in the field. Another important goal is a closer integration between the experimental, theoretical, and computational (software development) parts of the network, which will be an important element exposing practitioners in each area to cutting edge progress in the others.

Status

SIGNED

Call topic

MSCA-RISE-2019

Update Date

28-04-2024
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Horizon 2020
H2020-EU.1. EXCELLENT SCIENCE
H2020-EU.1.3. EXCELLENT SCIENCE - Marie Skłodowska-Curie Actions (MSCA)
H2020-EU.1.3.3. Stimulating innovation by means of cross-fertilisation of knowledge
H2020-MSCA-RISE-2019
MSCA-RISE-2019