Multiscale Modelling Made Simple – “NanoBridge"
A Computational Platform for Next-Gen Simulations of Novel Devices incorporating 2D materials
The demand for electronics is exponentially increasing, electronic devices continue to shrink in size-while at same time are required to deliver better performance and expanding functionality, furthermore, these devices also require exponentially more power to operate.
Incorporating the use of novel 2D materials with unprecedented properties could provide a response to this challenge.
When numerically studying the performance of devices incorporating 2D materials, the primary hurdle lies in addressing the extreme geometrical aspect-ratio between nanostructured materials and device environments, the low dimensionality of the materials and the coexistence of multi-physics phenomena involving electromagnetism (EM), charge propagation, heat transfer, amongst others.
The use of this multi-physics (multiscale) toolkit provides high predictive capabilities and is a source of helpful information to manage and direct the design and manufacturing phase of the devices
Read More: Multi-Scale Modeling of 2D Materials a Computational Platform
The Concept
NANO-EH has the ambition of creating a multi-source energy harvester technological platform by translating forefront knowledge in novel smart nanomaterials and nanomaterial systems/structures into advanced engineering that enables efficient manufacturing processes.
NANO-EH has the ambition to open the pathway towards large scale implementation of these battery-free technologies in a wide range of commercial IoTs and wireless network of sensors (WSNs) applications. In order to achieve its goal NANO-EH exploit four classes of smart nanomaterials that are lead- and rare earth-free materials and will demonstrate their recyclability potential at module level.
Concept
PIERS 2021 Conference
Harvesting of energy with nanomaterials
IEEE Nanotechnology Materials and Devices Conference (IEEE NMDC 2021), Vancouver-Canada
AICIng 2021
PIERS 2021 Conference
AICIng 2021
IEEE Nanotechnology Materials and Devices Conference (IEEE NMDC 2021), Vancouver-Canada
NANO-EH Training
The Rise of Ferroelectricity at Nanoscale - Nanoelectronics is rediscovering the ferroelectricity
M. Dragoman, M. Aldrigo, D. Dragoman, S. Iordanescu, A. Dinescu, and M. Modreanu
DOI: 10.1109/MNANO.2021.3098217
Microwave Detection Using 2-Atom-Thick Heterojunction Diodes
M. Aldrigo, D. Dragoman, D. Vasillache, S. Iordanescu, A. Dinescu, G. Biagetti, L. Pierantoni and D. Mencarelli
DOI: 10.1109/IMS19712.2021.9574815
Geometric diode modeling for energy harvesting applications
N. Pelagalli, M. Aldrigo, M. Dragoman, M. Modreanu, D. Mencarelli and L. Pierantoni
Phase properties of different HfO2 polymorphs: a DFT-based study
E. Laudadio, P. Stipa, L. Pierantoni, D. Mencarelli
Microwave Detection Using 2-Atom-Thick Self-Switching Diodes based on Quantum Simulations and Advanced Circuit Models
M. Aldrigo, M. Dragoman, N. Pelagalli, E. Laudadio, L. Zappelli, S. Iordanescu, D. Vasillache, A. Dinescu, L. Pierantoni, P. Stipa and D. Mencarelli
DOI: 10.1109/TMTT.2021.3129520
HfO2-Based Ferroelectrics Applications in Nanoelectronics
M. Dragoman, M. Aldrigo, D. Dragoman, S. Iordanescu, A. Dinescu and M. Modreanu
DOI: 10.1109/pssr.202000521
The microwave properties of tin sulfide thin films prepared by RF magnetron sputtering techniques
M. Dragoman, M. Aldrigo, A. Dinescu, S. Iordanescu, C. Romanitan, S. Vulpe, D. Dragoman, T. Braniste, V. Suman, E. Rusu and L. Tiginyanu
DOI: 10.1088/1361-6528/ac59e3
Oxygen-vacancy induced ferroelectricity in nitrogen-doped nickel oxide
M. Dragoman, S. Vulpe, E. Aperathithis, C. Aivalioti, C. Romanitan, A. Dinescu, D. Dragoman, M. Aldrigo, N. Djourelov, M. Modreanu and A. Moldovan
DOI: 10.1063/5.0075568