Entangled-Photon Source Research Engineer, Massy
Entangled-Photon Source Research Engineer, Massy
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Massy, France -
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Description
AboutQuandela: Quandela is a European deeptech scale-up building modular, scalable and energy-efficient photonic quantum computers, accessible both on the cloud and on-premise.
With a team of more than 140 people, we develop our own hardware and software stack, from semiconductor quantum emitters to quantum control systems and algorithms.
Our ambition is to turn cutting-edge quantum optics into operational quantum computing systems.
Within this roadmap, hybrid architectures combining photonic qubits and spin-based quantum memories play a central role in enabling scalable cluster-state quantum computing.
Aboutthisposition: Located at IPVF in Massy, this position is part of the Semiconductor R&D division and integrated within the Spin Cluster / Cooling team.
The team develops experimental platforms enabling spin-photon and spin-spin entanglement. Within this framework, your role will focus on stabilizing and improving spin-photon cluster state generation while implementing fast optical control schemes operating at nanosecond time scales.
Working at the interface between theory and experiment, you will translate cluster-state protocols into robust and reproducible laboratory implementations, contributing directly to demonstrator milestones and helping move these concepts toward scalable hardware.
Whatwillyoudo?➡️
Developandoperatespin-controlexperiments:
Buildandoperatecustomopticalsetups toaddressandcharacterizechargedquantum dots atcryogenictemperatures.
Implementandrefinepicosecondpulseshapingand pulsesequences.
Manipulatespin statesusingall-opticalapproachesandappliedfields.
Implementreal-timeswitchingof pulsesequencesatnanosecondtimescales(6–24 ns).
Ensurepropersynchronizationbetweenopticalpulses and fastelectroniccontrolsystems.
➡️
Characterizeandoptimizesystem performance:
Characterizespin-photonemissionpropertiesandcoherencemetrics.
Optimizepulsesequencesandexperimentalparameterstoimprovestatefidelity.
Identifyexperimentallimitations and proposepracticalimprovements.
➡️
Contributeto theresearchroadmap:
Systematicallydocumentexperimentalresultsand reportfindings.
Collaboratewithinternalteamswhentransferringvalidatedresultstowardintegration.
Howyou’llgrow? 0-3 months
→ Reproduce and stabilize existing setups. 3-6months →Operate independently and manage daily laboratory activity. 6-12months →Take responsibility for dedicated technical modules. Beyond one year
→ Deepen expertise and contribute to platform evolution.
Whatwe’relookingfor? We are seeking an experimental physicist with experience in spin manipulation in solid‑state quantum systems.
A PhD, or early postdoctoral experience, in Quantum Optics, Condensed Matter Physics, or a closely related field would be particularly valued. Experience with platforms such as charged quantum dots, NV centers, silicon carbide spins, or comparable optically addressable systems will help you integrate quickly into our environment.
If you have already controlled spins using optical pulse sequences and are familiar with the practical challenges of manipulating spin states in the lab, we encourage you to clearly highlight this experience in your application.
Must‑have
Strongexperimentalspin background (PhD level).
Hands‑on optical spin control in cryogenic environments.
Familiarity with nanosecond timing and synchronization constraints.
Python for experiment control and data analysis.
High autonomy and experimental rigor.
Important (cangrowhere)
Experience with quantum dots or trion‑based systems.
Familiarity with coherence‑enhancement techniques.
Exposure to entanglement or cluster‑state protocols.
Experience combining optical control with fast electronics.
Bonus
Early postdoctoral experience in spin‑based systems.
Publications in spin‑based quantum optics.
Experience in collaborative or industrial R&D.
If you do not tick every box but have a strong background in spin physics and share our R&D mindset— combining curiosity, scientific rigor, and the desire to build experimental expertise within a collaborative team — we encourage you to apply.
Join one of the fastest‑growing quantum hardware companies in Europe and contribute directly to the development of next‑generation spin‑based photonic architectures.
Work on advanced spin‑photon experiments for hybrid quantum platforms
Contribute to demonstrator milestones bridging research and hardware
Grow within a high‑level R&D environment at the interface of optics and hardware
Collaborate with theorists and experimental teams across disciplines
Competitive compensation aligned with your experience and level of responsibility
Company savings plan
100% health coverage (Alan)
Transport reimbursement or mobility bonus
Swile meal vouchers
Access to Gymlib
#J-18808-Ljbffr
With a team of more than 140 people, we develop our own hardware and software stack, from semiconductor quantum emitters to quantum control systems and algorithms.
Our ambition is to turn cutting-edge quantum optics into operational quantum computing systems.
Within this roadmap, hybrid architectures combining photonic qubits and spin-based quantum memories play a central role in enabling scalable cluster-state quantum computing.
Aboutthisposition: Located at IPVF in Massy, this position is part of the Semiconductor R&D division and integrated within the Spin Cluster / Cooling team.
The team develops experimental platforms enabling spin-photon and spin-spin entanglement. Within this framework, your role will focus on stabilizing and improving spin-photon cluster state generation while implementing fast optical control schemes operating at nanosecond time scales.
Working at the interface between theory and experiment, you will translate cluster-state protocols into robust and reproducible laboratory implementations, contributing directly to demonstrator milestones and helping move these concepts toward scalable hardware.
Whatwillyoudo?➡️
Developandoperatespin-controlexperiments:
Buildandoperatecustomopticalsetups toaddressandcharacterizechargedquantum dots atcryogenictemperatures.
Implementandrefinepicosecondpulseshapingand pulsesequences.
Manipulatespin statesusingall-opticalapproachesandappliedfields.
Implementreal-timeswitchingof pulsesequencesatnanosecondtimescales(6–24 ns).
Ensurepropersynchronizationbetweenopticalpulses and fastelectroniccontrolsystems.
➡️
Characterizeandoptimizesystem performance:
Characterizespin-photonemissionpropertiesandcoherencemetrics.
Optimizepulsesequencesandexperimentalparameterstoimprovestatefidelity.
Identifyexperimentallimitations and proposepracticalimprovements.
➡️
Contributeto theresearchroadmap:
Systematicallydocumentexperimentalresultsand reportfindings.
Collaboratewithinternalteamswhentransferringvalidatedresultstowardintegration.
Howyou’llgrow? 0-3 months
→ Reproduce and stabilize existing setups. 3-6months →Operate independently and manage daily laboratory activity. 6-12months →Take responsibility for dedicated technical modules. Beyond one year
→ Deepen expertise and contribute to platform evolution.
Whatwe’relookingfor? We are seeking an experimental physicist with experience in spin manipulation in solid‑state quantum systems.
A PhD, or early postdoctoral experience, in Quantum Optics, Condensed Matter Physics, or a closely related field would be particularly valued. Experience with platforms such as charged quantum dots, NV centers, silicon carbide spins, or comparable optically addressable systems will help you integrate quickly into our environment.
If you have already controlled spins using optical pulse sequences and are familiar with the practical challenges of manipulating spin states in the lab, we encourage you to clearly highlight this experience in your application.
Must‑have
Strongexperimentalspin background (PhD level).
Hands‑on optical spin control in cryogenic environments.
Familiarity with nanosecond timing and synchronization constraints.
Python for experiment control and data analysis.
High autonomy and experimental rigor.
Important (cangrowhere)
Experience with quantum dots or trion‑based systems.
Familiarity with coherence‑enhancement techniques.
Exposure to entanglement or cluster‑state protocols.
Experience combining optical control with fast electronics.
Bonus
Early postdoctoral experience in spin‑based systems.
Publications in spin‑based quantum optics.
Experience in collaborative or industrial R&D.
If you do not tick every box but have a strong background in spin physics and share our R&D mindset— combining curiosity, scientific rigor, and the desire to build experimental expertise within a collaborative team — we encourage you to apply.
Join one of the fastest‑growing quantum hardware companies in Europe and contribute directly to the development of next‑generation spin‑based photonic architectures.
Work on advanced spin‑photon experiments for hybrid quantum platforms
Contribute to demonstrator milestones bridging research and hardware
Grow within a high‑level R&D environment at the interface of optics and hardware
Collaborate with theorists and experimental teams across disciplines
Competitive compensation aligned with your experience and level of responsibility
Company savings plan
100% health coverage (Alan)
Transport reimbursement or mobility bonus
Swile meal vouchers
Access to Gymlib
#J-18808-Ljbffr
Informations clefs
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Nom de l’entrepriseQuandela SA -
Titre de posteEntangled-Photon Source Research Engineer
-
Signaler -
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