Quantum Topological Qubit Advanced Manufacturing Engineer

GlobalFoundries•Essex Junction, VT

1d•$85,000 - $146,000

About The Position

The Topological Qubit AME (Principal Engineer) is a hands-on technical contributor within the Quantum Technology Solutions organization focused on enabling scalable topological quantum computing platforms. This role develops and optimizes semiconductor process modules and materials systems required for topological qubit devices, working closely with device, integration, and materials teams to translate advanced concepts into manufacturable solutions. As a Principal Engineer, this role focuses on development, characterization, and optimization of process technologies supporting topological qubits. The engineer will work across deposition, etch, and epitaxy processes to enable superconducting materials, III‑V heterostructures, and low-loss dielectrics, ensuring robust, repeatable, and scalable manufacturing aligned with device and integration requirements.

Requirements

BS or MS in Materials Science, Electrical Engineering, Physics, Chemical Engineering, or related field
5–8+ years of experience in semiconductor process or manufacturing engineering
Hands-on experience with deposition, etch, or epitaxial processes
Strong understanding of semiconductor materials and process–device interactions
Experience with materials characterization and data analysis
Familiarity with DOE and statistical analysis methods
Strong analytical, problem-solving, and communication skills

Nice To Haves

Experience with superconducting or quantum-relevant materials systems
Background in III‑V epitaxy and heterostructure engineering (MBE, MOCVD)
Familiarity with topological quantum devices or advanced device platforms
Experience with BEOL integration, interconnects, or advanced packaging
Exposure to cryogenic materials behavior and low-temperature operation
Experience with yield improvement, SPC, or variability analysis
Experience in advanced R&D or emerging semiconductor technologies

Responsibilities

Develop and optimize process modules including PVD, CVD, ALD, etch, and epitaxial growth (MBE, MOCVD)
Engineer advanced materials systems including III‑V heterostructures, superconductors, and low-loss dielectrics
Design and execute DOE experiments to evaluate materials, interfaces, and device performance drivers
Characterize films using electrical, physical, and structural techniques to assess quality and variability
Analyze data to identify key process drivers, defect mechanisms, and optimization opportunities
Develop process recipes to meet device requirements, including cryogenic and low-noise performance
Support integration of process modules into device and BEOL flows, including superconducting interconnects
Collaborate with device and integration teams to align process behavior with device physics requirements
Apply SPC and variability analysis to improve process stability, repeatability, and yield
Support yield-learning and root-cause analysis activities
Document process flows, results, and learnings for knowledge transfer and scale-up
Perform all activities in a safe and responsible manner and support all Environmental, Health, Safety & Security requirements and programs.