Lead Lunar Environments Scientist

About The Position

Requirements

• B.S. in Physics, Engineering, Planetary Science, or a related technical field.
• 5+ years of experience in fundamental planetary science research and/or applying planetary science knowledge to space systems design (advanced degrees can substitute for years of experience)
• Strong knowledge of the lunar surface environment, including relevant aspects of dust behavior, plasma interactions, exosphere effects, radiation, micrometeorites, and electrostatic charging dynamics.
• Experience synthesizing literature, experimental data, and modeling results of complex natural phenomena into coherent environment characterizations that support decision-making.
• Experience developing or applying physics-based models
• Proficient at working both independently to drive research and collaboratively to implement engineering solutions.
• Established relationships within the lunar science and exploration community.
• Excellent communication skills, with a proven ability to translate complex physics. concepts effectively to interdisciplinary colleagues in engineering, science and program management colleagues.

Nice To Haves

• M.S. or Ph.D. in a relevant field.
• Fluent in Python or another relevant programming language used for scientific computing and modeling.
• Experience translating in spacecraft charging, space environment effects, plasma interactions, environmental modeling, or physics-based analysis for aerospace systems .
• Direct experience developing spacecraft charging models, ideally with a specific emphasis on the lunar surface.
• Experience supporting hardware design for harsh or space environments.
• Familiarity with ESD/EMC, grounding/bonding, or charge mitigation for flight or other high-reliability systems.
• Experience defining environmental effects test objectives or supporting verification planning.

Responsibilities

• Serve as the team's SME on the lunar surface environment (including dust, charging, radiation, plasma, micrometeorites, and thermal extremes) and train cross-functional teams on relevant phenomena and their implications for hardware
• Define the scope, architecture, and validation strategy for lunar environment models; guide in prioritizing physics fidelity and identifying dominant uncertainty drivers
• Synthesize modeling results, scientific literature, and environmental data from terrestrial analog tests and lunar missions into environment characterizations that inform hardware design requirements and constraints
• Communicate confidence levels, uncertainty bounds, and recommended design margins to the systems engineering and design teams to support informed engineering decisions
• Engage and manage relationships with external SMEs and the broader scientific community to ensure models reflect the current state of knowledge
• Work with the systems engineering and test engineers to ensure environment characterization needs are reflected in verification planning and that appropriate validation hooks are identified early in hardware development

Benefits

• Medical, dental, vision, basic and supplemental life insurance, short and long-term disability, and other benefits
• Flexible PTO policy with paid company holidays.