Job Description
Join Nexus Technologies Inc. at the forefront of technological evolution as we pioneer quantum computing solutions for 2026 and beyond. We seek a visionary Quantum Computing Architect to design next-gen quantum systems that will revolutionize industries worldwide. This role offers unparalleled opportunities to shape the future of computational science while collaborating with Nobel laureates and industry pioneers.
Our Austin-based innovation hub provides state-of-the-art facilities and a culture that thrives on bold thinking. You'll lead cross-disciplinary teams to develop fault-tolerant quantum processors, implement novel error correction protocols, and create scalable quantum architectures. The ideal candidate will combine deep technical expertise with strategic vision to translate theoretical breakthroughs into practical applications.
Responsibilities
- Design and implement fault-tolerant quantum computing architectures for enterprise-scale applications
- Develop quantum error correction protocols achieving >99.9% fidelity rates
- Create hybrid quantum-classical computing frameworks for complex optimization problems
- Lead R&D initiatives in topological qubit implementations and quantum machine learning
- Collaborate with hardware teams to optimize cryogenic control systems and photonic interconnects
- Establish quantum security protocols resistant to post-quantum cryptographic threats
- Mentor junior researchers and publish breakthrough findings in Nature/Science journals
Qualifications
- PhD in Quantum Computing, Physics, or Computer Science with 5+ years industry experience
- Proven track record in implementing quantum algorithms with >1000 qubit systems
- Expertise in quantum error correction codes (surface, color, LDPC)
- Proficiency with quantum programming frameworks (Qiskit, Cirq, Q#)
- Deep understanding of quantum decoherence mitigation techniques
- Experience with superconducting qubit fabrication and control electronics
- Published research in top-tier quantum computing journals
- Strong background in topological materials and Majorana fermion manipulation