CNR NANO - Istituto Nanoscienze Consiglio Nazionale delle Ricerche

02.12.2021NANO COLLOQUIA S3 Avinash Vikatakavi

Date and Time: December 2, 2021 - 15.00 ONLINE

25.11.2021Producing electricity from heat losses: engineered in Pisa the first device capable of achieving it in a controlled manner

It is now possible to create a new generation of “smart” thermoelectric systems to generate clea...

23.11.2021il progetto RIMMEL @ MECSPE - Bologna 2021

Si svolgerà martedì 23 novembre, dalle 16.45 alle 17.45 (Sala Concerto c/o Centro Servizi – Bolo...

19.11.2021Graphene as a solid lubricant becomes super-slippery

Cnr Nano researchers in collaboration with Sussex University and Rice University studied the frictio...

17.11.2021International Workshop on Advanced Materials-to-Device Solutions for Synaptic Electronics

CNR Nano and ICN2 organized the

03.11.2021The RIMMEL Project @ l'Europa è qui 2021 – VOTE THE VIDEO ONLINE

The RIMMEL project enters the “Europe is here ...

11.10.2021Quantum computers become an experimental physics laboratory

A quantum computer is a machine designed to do calculations. Now a group of physicists from CnrNano,...

05.10.20212021 Nobel Prize for the discoveries on TRPV1 and PIEZO receptors

The seminal discoveries by this year’s Nobel Laureates have explained how heat, cold and touch can...

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Foto: Foto: Francesco Rossella [courtesy of NEST Laboratory, Scuola Normale Superiore and Istituto Nanoscienze-CNR, Italy)		- 17.02.2020 - S3 SEMINAR Francesco Rossella Date and Time: Monday February 17, 2020 - 12:00 Venue: S3 Seminar Room, Third Floor, Physics Building, FIM Department Speaker: Francesco Rossella NEST Laboratory, Scuola Normale Superiore and Istituto Nanoscienze-CNR (IT) Title: Engineering electronic functionalities in nanowire-based devices: advantages from heterostructuring and electrostatic doping Abstract: Semiconductor nanowires and nanowire heterostructures provide a formidable playground for nanoscience and nanotechnology at large, allowing to enable unprecedented device functionalities, that find countless applications spanning from quantum computation-technologies and sensing to energy harvesting and machine learning. We build on the epitaxial growth of III-V semiconductor nanowires, and demonstrate prototypical nanowire-based devices that use different strategies for the electrostatic doping of the nanostructures. Electronic confinement in InP-InAs nanowire quantum dots is exploited for thermoelectric conversion [1] and to enable single electron transistors coupled to microwaves [2]. Broken-gap InAs-GaSb core-shell nanowires allow to implement Esaki tunnel diodes [3] and open new perspectives for studying the physics of interacting electrons and holes at the nanoscale. Electric double layer transistors based on InAs nanowires gated by ionic liquids [4] enable the simultaneous gate-control of electrical conductivity and measurement of thermal conductivity in device architectures with suspended nanostructures [5]. References: [1] D. Prete, et al., Thermoelectric response at high temperature in nanowire quantum dots, Nano Lett. 19, 3033?3039 (2019) [2] S. Cornia, et al., Microwave Assisted Tunneling in Hard-Wall InAs/InP Nanowire Quantum Dots, Scientific Report, 19523 (2019) [3] M. Rocci, et al., Tunable Esaki effect in catalyst-free InAs/GaSb core-shell nanowires, Nano Letters 16, 7950–7955 (2016) [4] J. Lieb, et al., Ionic liquid gating of InAs nanowire-based field effect transistors, Adv. Funct. Mater. 1804378 (2019) [5] M. Rocci, et al, Suspended nanowire devices for thermal conductivity measurements using the 3?-method, J. Mater. Eng. Perform. 27, 6299–6305 (2018) Host: Marco Affronte, email: marco.affronte@unimore.it