Job Description
Join Nexus Future Labs at the forefront of quantum innovation as we redefine computational boundaries for 2026 and beyond. We're seeking a visionary Research Lead to architect next-generation quantum systems that will transform industries from pharmaceuticals to logistics. Our Austin R&D hub combines cutting-edge infrastructure with collaborative cross-disciplinary teams tackling humanity's most complex challenges. You'll drive breakthroughs in quantum error correction and algorithm optimization while mentoring a diverse cohort of quantum pioneers.
As part of our 2026 Roadmap initiative, this role offers unparalleled influence in shaping the quantum landscape through industry partnerships, open-source contributions, and patent development. We provide competitive equity packages, flexible hybrid work arrangements, and access to our state-of-the-art quantum annealing facilities.
Responsibilities
- Lead multi-disciplinary quantum research teams in developing novel algorithms for quantum advantage
- Architect fault-tolerant quantum computing frameworks targeting 2026 scalability milestones
- Establish strategic partnerships with academic institutions and quantum hardware manufacturers
- Drive quantum application development for optimization problems in logistics and cryptography
- Mentor researchers in quantum information theory and experimental physics
- Publish high-impact research in Nature Physics/Science and present at IEEE Quantum Week
- Secure $5M+ in government grants and industry consortium funding
Qualifications
- PhD in Quantum Physics, Computer Science, or related field with 5+ years industry experience
- Published research in top-tier quantum computing journals with 50+ citations
- Expertise in quantum error correction codes and fault-tolerant architectures
- Proficiency in quantum programming languages (Q#, Qiskit, Cirq)
- Track record of securing NSF/NIH grants or industry R&D partnerships
- Experience leading teams of 10+ quantum researchers or engineers
- Deep understanding of quantum supremacy challenges and NISQ-era limitations