CNR NANO - Istituto Nanoscienze Consiglio Nazionale delle Ricerche

02.12.2021NANO COLLOQUIA S3 Avinash Vikatakavi

Date and Time: December 2, 2021 - 15.00 ONLINE

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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

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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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July 2021

2021-07-14

FIM-S3 SEMINAR - Dr. Stefano Bosco

16:00 - 17:00

Date and Time:Wednesday July 14th, 16:00 (SHARP)

LINK (Google Meet): https://meet.google.com/urn-vauy-ecv?hs=122&authuser=0

Speaker: Dr. Stefano Bosco - University of Basel, Switzerland

Title: Hole spin qubits in Si and Ge quantum dots: Ultrafast gates and noise resilient qubits

Abstract: Hole spin qubits in Si and Ge quantum dots are frontrunner platforms for scalable quantum computers [1,2]. In these systems, the spin-orbit interactions permit efficient and ultrafast all-electric qubit control [3,4], but at the same time enhance the susceptibility of the qubit to charge noise. We show that these interactions can be fully tuned by the design of the quantum dot and by external electric fields [5], resulting in sweet spots where charge noise is removed [6]. Remarkably, at these sweet spots also the noise caused by the hyperfine interactions with nuclear spins -another leading source of decoherence in spin qubits- can be suppressed [7], greatly enhancing the coherence of these qubits.

[1] R. Maurand et al., A CMOS silicon spin qubit. Nat. Commun. 7, 13575 (2016).
[2] G. Scappucci et al., The germanium quantum information route. Nat. Rev. Mater. (2020).
[3] F. N. M. Froning et al., Ultrafast hole spin qubit with gate-tunable spin–orbit switch functionality. Nat. Nanotechnol. 16, 308–312 (2021).
[4] Camenzind et al., A spin qubit in a fin field-effect transistor. arXiv:2103.07369 (2021).
[5] S. Bosco, M. Benito, C. Adelsberger, D. Loss, Squeezed hole spin qubits in Ge quantum dots with ultrafast gates at low power. arXiv:2103.16724 (2021).
[6] S. Bosco and D. Loss, Hole spin qubits in Si finFETs with fully tunable spin-orbit coupling and sweet spots for charge noise. PRX Quantum 2, 010348 (2021).
[7] S. Bosco and D. Loss, Fully tunable hyperfine interactions of hole spin qubits in Si and Ge quantum dots. arXiv:2106.13744 (2021).

Host: Marco Gibertini (FIM, UNIMORE) and Claudia Cardoso (S3, CNR-NANO)

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