Aufgabengebiet
- Leitung und Steuerung technischer Entwicklungsprojekte im Bereich optischer Referenzsysteme über den gesamten Produktlebenszyklus
- Koordination interdisziplinärer Teams aus Optikentwicklung, Konstruktion, Elektronik, Software, Produktion und Qualitätssicherung
- Sicherstellung von Projektzielen hinsichtlich Zeit, Budget, Qualität und technischer Anforderungen
- Verantwortung für technische Spezifikationen, Produktweiterentwicklungen sowie technische Reviews und Risikoanalysen
- Schnittstellenmanagement zu internen Fachbereichen, Kunden, Lieferanten und externen Entwicklungspartnern
- Erstellung und Präsentation von Projektstatusberichten und Entscheidungsgrundlagen für Management und Stakeholder
Profil
- Abgeschlossenes Studium im Bereich Physik, Elektrotechnik, Maschinenbau, Photonik, Lasertechnik oder einer vergleichbaren technischen Fachrichtung
- Erfahrung im technischen Projektmanagement, idealerweise in der Entwicklung komplexer Lasersysteme oder High-Tech-Produkte
- Ausgeprägtes technisches Verständnis in den Bereichen Optik und Elektronik
- Erfahrung in der Leitung interdisziplinärer Teams sowie in der Steuerung externer Partner und Lieferanten
- Idealerweise Erfahrung in der Entwicklung optischer Referenzsysteme (Ultra-Stable-Lasers)
- Strukturierte, lösungsorientierte und eigenverantwortliche Arbeitsweise kombiniert mit hoher Kommunikations- und Organisationsstärke
- Sehr gute Englischkenntnisse in Wort und Schrift
- Sicheres Auftreten gegenüber Kunden, Management und Projektpartnern
Wir bieten
- Spannende und anspruchsvolle Aufgaben in einem dynamisch wachsenden Markt
- Eigenverantwortliches Arbeiten in einem hochmotivierten Team mit Gestaltungsfreiraum
- Eine Vergütung, die Sie am Unternehmenserfolg beteiligt, sowie ein Modell zur betrieblichen Altersvorsorge
- Eine individuelle und praxisorientierte Einarbeitung sowie Möglichkeiten zur beruflichen Weiterbildung
- JobRad-Leasing oder kostenloses Deutschlandticket
- 30 Tage Urlaub sowie regelmäßige Mitarbeiterevents
- Einen sicheren Arbeitsplatz und eine unbefristete Festanstellung
- Flache Hierarchien, Duz-Kultur und kurze Entscheidungswege
TECHNICAL & MARKET ANALYSIS | Appended by Quantum.Jobs
The intersection of precision photonics and industrial hardware manufacturing represents a critical scale bottleneck within the quantum information science and technology sector. As quantum computing platforms transition from laboratory demonstrations toward commercial-grade deployments, the stability of ultra-stable laser subsystems becomes paramount to maintaining long-term qubit coherence times across neutral atom, trapped ion, and photonic modalities. The management of these highly technical development cycles translates directly into value-chain leverage, determining whether systems scale effectively or suffer from localized integration failures. Sector-wide efforts continue to address talent and integration challenges in quantum systems, making structured execution engineering vital for reducing technology translation risks. By stabilizing the delivery protocols of complex optical reference systems, this role type ensures the reproducible performance required for high-consequence application deployment.
The photonics layer functions as the fundamental enabling infrastructure for multiple quantum computing and sensing architectures, demanding absolute systemic reliability during physical deployment. Within the hardware manufacturing domain, the lack of standardized optical interfaces and severe component dependencies create acute escalation risks that directly affect deployment schedules. Current industry focus lies on bridging classical and quantum capabilities at scale, which shifts the baseline challenge from initial physics validation to repeatable, multi-environment engineering stability. High-precision laser orchestration requires managing narrow margins of error where structural thermal fluctuations, phase noise, and wavelength drift introduce catastrophic variations into the wider hardware stack.
Ecosystem indicators from regional industrial networks highlight that the primary operational friction points reside in cross-functional coordination. The alignment of optics development with electronics engineering, precision mechanics, and control software defines the throughput rate of high-tech production pipelines. Furthermore, export control restrictions and specialized component scarcity threaten the continuity of deep-tech development pathways, amplifying the need for sophisticated lifecycle governance. As organizations attempt to move past localized prototypes, managing technical reviews and systemic risk analysis under strict compliance mandates serves as the primary stabilizing element against structural bottlenecks in the hardware layer.
The capability architecture for this role type centers on the synchronization of advanced photonics principles with structured systems engineering frameworks. Mastery of multi-disciplinary interface points is critical for managing the precise dependencies between laser subassemblies and underlying control electronics. This requires an operational understanding of how localized changes in optical wavelengths alter the execution stability of quantum-native compilers and physical qubit manipulators.
These integration capabilities directly impact production throughput by establishing predictable lifecycle architectures for complex optical reference hardware. Implementing rigorous verification and risk-mitigation protocols allows teams to isolate systemic failures before full-scale hardware manufacturing begins. By orchestrating communication pipelines between internal optical designers and external hardware component suppliers, this function reduces performance variations across highly distributed high-tech supply chains. - Accelerates the transition of precision laser assemblies from prototype validation to scalable industrial production
- Minimizes component integration friction across highly fragmented hardware and software interface layers
- Streamlines the deployment lifecycle of ultra-stable optical reference subsystems within deeper quantum architectures
- Enhances supply chain resilience through the structured coordination of specialized technical vendors
- Promotes technical risk mitigation by enforcing rigorous multidisciplinary engineering review protocols
- Optimizes capital allocation by aligning technical development budgets with long-term technology roadmaps
- Shortens engineering iteration cycles through the implementation of standardized hardware verification steps
- Fortifies product reproducibility metrics across multi-environment high-tech manufacturing pipelines
- Facilitates data-driven project governance for executive stakeholders navigating highly volatile hardware markets
- Decreases localized technical dependencies by creating comprehensive architectural specification frameworks
- Strengthens cross-functional team throughput via formalized interface management protocols
- Secures predictable scaling trajectories for hardware subcomponents within the broader deep-tech ecosystemIndustry Tags: Photonics Infrastructure, Laser Systems Engineering, Hardware Integration, Optical Reference Systems, Deep Tech Lifecycle, Cross-Functional Governance, Systems Architecture, High-Tech Manufacturing, Risk Management
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