Job Description
Join Nexus Labs at the forefront of 2026's quantum UX revolution! We're seeking a visionary Quantum UX Architect to design next-generation human-computer interfaces that transcend traditional paradigms. This role merges neuroscience, quantum computing principles, and predictive user behavior modeling to create immersive experiences that anticipate user needs before they're expressed. You'll lead a cross-disciplinary team of quantum researchers and interaction designers to prototype interfaces for our flagship quantum-entangled computing platform.
Our ideal candidate thrives at the intersection of theoretical physics and human-centered design, with a proven track record of shipping breakthrough products that redefine industry standards. You'll work directly with our CTO to shape the future of human-machine collaboration in a post-quantum world.
Responsibilities
- Design quantum-entangled user interfaces that leverage superposition states for adaptive experiences
- Develop predictive UX frameworks using quantum machine learning algorithms
- Lead user research studies incorporating quantum consciousness modeling techniques
- Collaborate with quantum hardware engineers to translate technical constraints into innovative solutions
- Establish industry-first accessibility standards for quantum interaction paradigms
- Mentor junior designers in quantum psychology and emergent behavior theory
- Present breakthrough concepts to executive stakeholders and venture capital partners
Qualifications
- Masters or PhD in Human-Computer Interaction, Cognitive Science, or Quantum Computing
- 5+ years designing for emerging technologies (AR/VR, AI, quantum interfaces)
- Published research in quantum cognition or human-machine entanglement
- Expertise in quantum programming languages (Q#, Quil) and quantum circuit design
- Portfolio demonstrating 3+ shipped products with paradigm-shifting UX
- Certification in Quantum Interaction Design (QID) from QIP
- Experience with neural interface hardware (Neuralink, CTRL-Labs)
- Deep understanding of quantum decoherence effects on user perception