Technologist III

NASA Jet Propulsion Laboratory

1d•$123,864 - $170,248•Onsite

About The Position

New ideas are all around us, but only a few will change the world. That’s our focus at JPL. We ask the biggest questions, then search the universe for answers—literally. We build upon ideas that have guided generations, then share our discoveries to inspire generations to come. Your mission—your opportunity—is to seek out the answers that bring us one step closer. If you’re driven to discover, create, and inspire something that lasts a lifetime and beyond, you’re ready for JPL. Located in Pasadena, California, JPL has a campus-like environment situated on 177 acres in the foothills of the San Gabriel Mountains and offers a work environment unlike any other: we inspire passion, foster innovation, build collaboration, and reward excellence. The Instrument Systems, Microdevices, and Sensors Section (365) is responsible for developing and infusing next generation technologies spanning quantum, micro-nanodevices and sensors that enable advanced flight sensors, instruments, and deep space communications. This section also serves to support the Communications and Instruments Division implement flight instruments through Instrument Systems Engineering, Instrument Integration and Test spanning from RF through ultraviolet (UV), including micro-electro-mechanical systems and quantum engineering. We invite you to join the Optical & Quantum System Engineering Group to serve as a Technologist III. You will be reporting administratively to the Group Supervisor. The Optical & Quantum System Engineering Group (365D) provides lifecycle leadership in the formulation, planning and execution of the project systems engineering function for JPL quantum space flight instruments. Our expertise includes systems architecting, project system engineering leadership, quantum atomic systems, quantum optical communication systems, and flight quantum system operations.

Requirements

Bachelor’s degree in Physics, Optical Engineering, or related technical discipline with a minimum of 6 years of professional experience, or Master’s degree in a related discipline with a minimum of 4 years of experience, or Ph.D. in a related discipline with a minimum of 2 years of experience.
Atomic physics technical background
Extensive experience with atom interferometry systems and research.
Experience with atom interferometry for gravity measurement/sensing.
Demonstrated success in performing atomic physics research
Demonstrated ability to design, plan, and assemble cold atom and atom interferometry laboratory systems and testbeds
Familiarity/understanding of the Quantum Gravity Gradiometer (QGG) instrument architecture
Track record of innovation in quantum physics, demonstrated through peer-reviewed publications and/or successful instrument delivery
Experience with the operation, characterization, and/or study of one or more of the following technologies: atom interferometry, stabilized laser systems, ultra-high vacuum systems, laser cooling of atoms, and quantum gravity gradiometry
Must be a motivated individual who can work effectively within a multidisciplinary team structure
Desire to learn how to develop, propose, win, and execute long-term research and development plan related to advancing space-based quantum systems
Strong written, verbal communication, and presentation skills

Nice To Haves

Excellent problem-solving skills
Demonstrated leadership skills
Ability to manage multiple issues, tasks, and priorities concurrently

Responsibilities

Maintain and develop software, electronics, and optical subsystems for Bose–Einstein condensates (BEC)-based ultra-cold atom testbeds, optimizing performance and reliability.
Conduct research in optical transport and long-interrogation-time atom interferometry, and develop models that align theory with experimental results and project performance in microgravity.
Support ultra-cold atom experiments in microgravity and development of space-grade hardware for atomic physics package and laser optical systems.
Support software development and validation for autonomous operations of ultra-cold atom experiments in microgravity.
Document results and findings, and communicate them through reports and technical discussions.
Collaborate in a multi-disciplinary team working environment with domestic and international partners on behalf of projects.
Present results in conferences and peer-reviewed journals.
Actively participate in proposal development activities.