Home > Publications database > Modeling an efficient singlet-triplet-spin-qubit-to-photon interface assisted by a photonic crystal cavity
 
Journal Article FZJ-2025-01147
http://join2-wiki.gsi.de/foswiki/pub/Main/Artwork/join2_logo100x88.png
Modeling an efficient singlet-triplet-spin-qubit-to-photon interface assisted by a photonic crystal cavity

 ;  ;  ;  ;  ;  ;  ;  ;  ;

2024
American Physical Society College Park, Md. [u.a.]

Physical review applied 21(5), 054052 () [10.1103/PhysRevApplied.21.054052]

This record in other databases:    

Please use a persistent id in citations: doi:  doi:

Abstract: Efficient interconnection between distant semiconductor spin qubits with the help of photonic qubits offers exciting new prospects for future quantum communication applications. In this paper, we optimize the extraction efficiency of a novel interface between a singlet-triplet-spin-qubit and a photonic-qubit. The interface is based on a 220-nm-thick Ga⁢As/(Al,Ga)⁢As heterostructure membrane and consists of a gate-defined double quantum dot (GDQD) supporting a singlet-triplet qubit, an optically active quantum dot (OAQD) consisting of a gate-defined exciton trap, a photonic crystal cavity providing in-plane optical confinement, efficient outcoupling to an ideal free-space Gaussian beam while accommodating the gate wiring of the GDQD and OAQD, and a bottom gold reflector to recycle photons and increase the optical extraction efficiency. All the essential components can be lithographically defined and deterministically fabricated on the Ga⁢As/(Al,Ga)⁢As heterostructure membrane, which greatly increases the scalability of on-chip integration. According to our simulations, the interface provides an overall coupling efficiency of 28.7% into a free-space Gaussian beam, assuming a Si⁢O2 interlayer fills the space between the reflector and the membrane. The performance can be further increased by undercutting this Si⁢O2 interlayer below the photonic crystal. In this case, the overall efficiency is calculated to be 48.5%.

Classification:
Contributing Institute(s):
  1. Halbleiter-Nanoelektronik (PGI-9)
  2. JARA-FIT (JARA-FIT)
Research Program(s):
  1. 5224 - Quantum Networking (POF4-522) (POF4-522)

Appears in the scientific report 2024
Database coverage:
Medline ; American Physical Society Transfer of Copyright Agreement ; OpenAccess ; Clarivate Analytics Master Journal List ; Current Contents - Physical, Chemical and Earth Sciences ; Essential Science Indicators ; IF < 5 ; JCR ; SCOPUS ; Science Citation Index Expanded ; Web of Science Core Collection
Click to display QR Code for this record

The record appears in these collections:
Document types > Articles > Journal Article
JARA > JARA > JARA-JARA\-FIT
Institute Collections > PGI > PGI-9
Workflow collections > Public records
Publications database
Open Access
 Record created 2025-01-27, last modified 2025-02-03
Similar records


OpenAccess:
Download fulltext PDF
Rate this document:

Rate this document:
1
2
3
4
5
 
(Not yet reviewed)
JuSER :: Search :: Submit :: Personalize :: Help
Powered by Invenio v1.1.7 | join2_v2508a
Maintained by juser@fz-juelich.de

Impressum | Data Privacy Policy
This site is also available in the following languages:
Deutsch  English