Job Description
Join Nexus Quantum Labs at the forefront of computational revolution. We're seeking a visionary Quantum Computing Architect to design and implement next-generation quantum systems that will redefine technology by 2026. This role offers unparalleled opportunity to shape humanity's digital future while working alongside Nobel Prize-winning physicists in our state-of-the-art Silicon Valley facility.
Our team pioneers breakthroughs in quantum error correction and topological qubits, with applications spanning drug discovery, climate modeling, and AI optimization. You'll lead the development of fault-tolerant quantum processors capable of solving previously impossible computational challenges. We offer competitive equity packages, unlimited PTO, and dedicated R&D budget for personal innovation projects.
Responsibilities
- Design scalable quantum processor architectures with 1000+ qubit capabilities
- Develop novel quantum error correction protocols for 2026-era hardware
- Lead cross-functional teams in quantum algorithm optimization and implementation
- Establish industry partnerships with quantum hardware manufacturers and research institutions
- Present quantum computing roadmaps to C-suite executives and venture capital partners
- Drive innovation in quantum machine learning integration for commercial applications
- Mentor quantum software engineers in advanced quantum programming paradigms
Qualifications
- PhD in Quantum Physics, Computer Science, or related field with 8+ years industry experience
- Published research in top-tier quantum computing journals (Nature/Science/Physical Review X)
- Proven track record of designing fault-tolerant quantum systems beyond NISQ era
- Expertise in quantum error correction codes (surface codes, color codes) and topological protection
- Proficiency in quantum programming frameworks (Qiskit, Cirq, Q#) and classical-quantum interfaces
- Experience securing $10M+ in quantum computing research funding or commercial partnerships
- Deep understanding of quantum hardware limitations and cryogenic system integration