Giuliana Beretta scite author profile

Giuliana Beretta

5Publications

6Citation Statements Received

36Citation Statements Given

How they've been cited

How they cite others

139

Affiliations

Polytechnic University of Turin, Institute of Electronics, Computer and Telecommunication Engineering

Publications

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Impact of Molecular Electrostatics on Field-Coupled Nanocomputing and Quantum-Dot Cellular Automata Circuits

et al. 2022

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The molecular Field-Coupled Nanocomputing (FCN) is a promising implementation of the Quantum-dot Cellular Automata (QCA) paradigm for future low-power digital electronics. However, most of the literature assumes all the QCA devices as possible molecular FCN devices, ignoring the molecular physics. Indeed, the electrostatic molecular characteristics play a relevant role in the interaction and consequently influence the functioning of the circuits. In this work, by considering three reference molecular species, namely neutral, oxidized, and zwitterionic, we analyze the fundamental devices, aiming to clarify how molecule physics impacts architectural behavior. We thus examine through energy analysis the fundamental cell-to-cell interactions involved in the layouts. Additionally, we simulate a set of circuits using two available simulators: SCERPA and QCADesigner. In fact, ignoring the molecular characteristics and assuming the molecules copying the QCA behavior lead to controversial molecular circuit proposals. This work demonstrates the importance of considering the molecular type during the design process, thus declaring the simulators working scope and facilitating the assessment of molecular FCN as a possible candidate for future digital electronics.

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Multi-Molecule Field-Coupled Nanocomputing for the Implementation of a Neuron

Beretta

Ardesi

Graziano

et al. 2022

IEEE Trans. Nanotechnology

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Ab initio Molecular Dynamics Simulations of Field-Coupled Nanocomputing Molecules

Ardesi

Gaeta

Beretta

et al. 2021

JICS

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Molecular Field-Coupled Nanocomputing (FCN) represents one of the most promising solutions to overcome the issues introduced by CMOS scaling. It encodes the information in the molecule charge distribution and propagates it through electrostatic intermolecular interaction. The need for charge transport is overcome, hugely reducing power dissipation.At the current state-of-the-art, the analysis of molecular FCN is mostly based on quantum mechanics techniques, or ab initio evaluated transcharacteristics. In all the cases, studies mainly consider the position of charges/atoms to be fixed. In a realistic situation, the position of atoms, thus the geometry, is subjected to molecular vibrations. In this work, we analyse the impact of molecular vibrations on the charge distribution of the 1,4-diallyl butane. We employ Ab Initio Molecular Dynamics to provide qualitative and quantitative results which describe the effects of temperature and electric fields on molecule charge distribution, taking into account the effects of molecular vibrations. The molecules are studied at near-absolute zero, cryogenic and ambient temperature conditions, showing promising results which proceed towards the assessment of the molecular FCN technology as a possible candidate for future low-power digital electronics. From a modelling perspective, the diallyl butane demonstrates good robustness against molecular vibrations, further confirming the possibility to use static transcharacteristics to analyse molecular circuits.

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A Reconfigurable Field-Coupled Nanocomputing Paradigm on Uniform Molecular Monolayers

Ardesi

Beretta

Fabiano

et al. 2021

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Taming Molecular Field-Coupling for Nanocomputing Design

Ardesi

Garlando

Riente

et al. 2022

J. Emerg. Technol. Comput. Syst.

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Molecular Field-Coupling Nanocomputing (FCN) is one of the most promising technology for overcoming the CMOS scaling issues. It encodes the information in the charge distribution of nanometric molecules and propagates it through local electrostatic intermolecular interaction. This technology promises very high speed at ambient temperature with minimal power dissipation. The main research focus on Molecular FCN is either on the single-molecule low-level analysis or circuits design based on naive assumptions. We aim to fill this gap, assessing the potential and feasibility of FCN. We present a bottom-up analysis&design framework that starts from the physical characterization of molecular and technological parameters and enables physical-aware FCN designs. The framework explicitly considers molecular physics, allowing the designer to tame the molecular interaction to ensure the computational capabilities of the final device. The framework permits studying possible physical effects that create cross-implications and correlations among physical and system-level layers considering possible behaviour variability. We characterize and verify the molecular propagation in increasingly structured layouts to design complex arithmetic circuits. The results highlight molecular FCN advantages, especially in area occupation, and provide valuable quantitative feedback to designers and technologists to support the assessment of molecular FCN and the realization of an eventual prototype.

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