Periodic Reporting for period 1 - MEHYB (Many-body effects in hybrid quantum systems)
Período documentado: 2015-04-01 hasta 2017-03-31
In the current project we have theoretically analyzed a set of hybrid quantum systems involving superconducting circuits, electronic spins in solids and tiny mechanical resonators. The original objective was to investigate, how the combined functionalities of these system can be used for enhancing magnetometry applications and for realizing new types of quantum simulators for unconventional many-body interactions. In this context we have specifically investigated new efficient schemes for coupling a single electronic spin to the quantized motion of a mechanical nanoresonator. This interface constitutes a basic building block for hybrid quantum systems, where, for example, quantum information is stored in the spin-quantum memory, while the mechanical system is used as an interconnection to superconducting circuits or optical photons. We further showed, how superconducting circuits can be used to simulate light-matter interactions in the so-called ultrastrong coupling regime, which is not accessible with real atoms and photons. In this work we discovered a new quantum many-body effect, which was overlooked in related studies before and can be used as a natural entanglement resource. Finally, we found an unexpected noise-evasion mechanism for quantum communication schemes, which enables a faithful transmission of quantum information through noisy channels. This mechanism makes quantum communication over electric microwave channels possible, where otherwise the weak quantum signal would be washed out by an unavoidable background of thermal microwave photons.
In conclusion, in this project several important results for the further development of hybrid quantum systems and quantum technologies based on superconducting quantum circuits have been obtained. This concerns, in particular, our quantum communication protocol for noisy channels, which enables a completely approach for intra-city quantum networks based on microwave technology only.
In summary the main outcomes of the project are as follows:
1) In close collaboration with our colleagues in China and Japan, we have proposed and analyzed two different schemes for efficiently interfacing a single electronic spin with a macroscopic mechanical resonator. In the first study, which was published in Physical Review Applied [Phys. Rev. Applied 4, 044003, (2015)], we analyzed a hybrid device, where a microscale diamond beam with a single embedded spin qubit is coupled to a superconducting microwave cavity. In the second study published in Physical Review Letters [Phys. Rev. Lett. 117, 015502, (2016)] and selected as an Editor's suggestion, we showed, how spin qubits in diamond can be efficiently coupled to a suspended carbon nanotube via DC currents
2) We have analyzed the ground state of a superconducting circuit QED system in the ultrastrong coupling regime. In this work we could clarify a longstanding debate about the existence or non-existence of a superradiant phase and identified a new type of entanglement mechanism. This work has been published in Physical Review A [Phys. Rev. A 94, 033850, (2016)].
3) We have proposed and analyzed a general scheme for transferring quantum information through a noisy channel. Specifically, we described the application of this principle for the implementation of intra-city quantum networks based on microwave technologies only. This work was published in Physical Review X [Phys. Rev. X 7, 011035, (2017)] and highlighted by a parallel popular science article in the journal ""Physics"". For this work a press release was made, which appeared on the webpage of the TU Wien and in the science section of several Austrian and international newspapers and websites.
Open access versions of all the publications are available on the preprint server arXiv.
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The expected impact of this project is primary on the level of basic research, where it will contribute to a better understanding superconducting quantum circuits and a further advancement of hybrid quantum systems. On the long run, i.e. when quantum communication and quantum information processing schemes become available for the general public, this research can also have a direct impact our society. In particular, our work on intracity quantum networks based on microwave photons might have a strong influence on future quantum communication strategies.