Solid Energy Systems
SES AI Corp. (NYSE: SES) is dedicated to
accelerating the world’s energy transition
through groundbreaking material discovery and advanced battery management. We are at the forefront of revolutionizing battery creation, pioneering the integration of
cutting-edge machine learning
into our research and development. Our AI-enhanced, high-energy-density and high-power-density Li-Metal and Li-ion batteries are unique; they are the
first in the world
to utilize electrolyte materials discovered by AI. This powerful combination of "AI for science" and material engineering enables batteries that can be used across various applications, including
transportation (land and air), energy storage, robotics, and drones
.
A highly competitive salary and robust benefits package, including comprehensive health coverage and an attractive equity/stock options program within our NYSE-listed company.
The opportunity to contribute directly to a meaningful scientific project—accelerating the global energy transition with a clear and broad public impact.
Work in a dynamic, collaborative, and innovative environment at the intersection of AI and material science, driving the next generation of battery technology.
Significant opportunities for professional growth and career development as you work alongside leading experts in AI, R&D, and engineering.
Access to state-of-the-art facilities and proprietary technologies used to discover and deploy AI-enhanced battery solutions.
What we Need The SES AI
Prometheus team
is seeking an exceptional
Computational Materials Scientist to
combine physics‑based simulation (DFT, MD, quantum modeling) with AI‑assisted material prediction to generate high-quality training data and accelerate materials discovery. This role is crucial for advancing our understanding of electrochemical energy materials at the atomic level. As a Computational Materials Scientist, you will be a core data‑driven modeler responsible for executing and automating complex simulations.
Essential Duties and Responsibilities
Atomistic Modeling & Simulation
Conduct and oversee DFT (Density Functional Theory), MD (Molecular Dynamics), and QM (Quantum Mechanics) simulations of battery components, including electrolytes, coatings, and electrodes.
Develop and refine ML‑enhanced force fields and surrogate models to accelerate simulation time scales and enable multi‑scale simulation efforts.
Apply expertise in atomistic simulation and quantum modeling to solve key challenges in electrochemical energy materials (e.g., batteries/fuel cells).
AI Data Generation & Prediction
Generate high-quality, structured simulation data to serve as training sets for AI property prediction models and material screening modules.
Contribute to the development of battery domain LLM features and advanced property‑prediction models.
Automate complex simulation workflows using strong coding practices to enhance efficiency and scalability.
Collaborate with experimental teams, leveraging a hybrid computational + experimental literacy to validate models and drive design iteration.
Utilize advanced simulation tools (VASP, Quantum Espresso) and data science libraries (TensorFlow, Pandas) to manage and analyze large datasets.
Education and/or Experience
Education: Ph.D. in Mechanical Engineering, Materials Science, Chemical Engineering, or a closely related computational/physics field.
Core Simulation Expertise: Deep and extensive experience in atomistic simulation and quantum modeling, including proficiency with key QM/DFT tools (VASP, Quantum Espresso) and MD simulations.
Domain Focus: Strong background in electrochemical energy materials and extensive computational work focused on batteries/fuel cells.
Coding Proficiency: Strong coding skills in Python (along with related libraries like Pandas and TensorFlow) for simulation workflow automation and data analysis.
ML Application: Experience in developing or utilizing ML‑enhanced force fields and surrogate models for materials prediction, or equivalent practical experience.
Preferred Qualifications
LLM Development: Experience in developing battery domain LLM features or property‑prediction models.
Hybrid Skillset: Demonstrated experience working in a hybrid computational + experimental environment.
Tooling Diversity: Familiarity with additional data analysis tools like R, SQL, MATLAB, and time‑series forecasting libraries like Prophet.
Target Background: Previous experience at national laboratories, XtalPi, Entalpic, or deep battery modeling groups.
Apply for this job #J-18808-Ljbffr
accelerating the world’s energy transition
through groundbreaking material discovery and advanced battery management. We are at the forefront of revolutionizing battery creation, pioneering the integration of
cutting-edge machine learning
into our research and development. Our AI-enhanced, high-energy-density and high-power-density Li-Metal and Li-ion batteries are unique; they are the
first in the world
to utilize electrolyte materials discovered by AI. This powerful combination of "AI for science" and material engineering enables batteries that can be used across various applications, including
transportation (land and air), energy storage, robotics, and drones
.
A highly competitive salary and robust benefits package, including comprehensive health coverage and an attractive equity/stock options program within our NYSE-listed company.
The opportunity to contribute directly to a meaningful scientific project—accelerating the global energy transition with a clear and broad public impact.
Work in a dynamic, collaborative, and innovative environment at the intersection of AI and material science, driving the next generation of battery technology.
Significant opportunities for professional growth and career development as you work alongside leading experts in AI, R&D, and engineering.
Access to state-of-the-art facilities and proprietary technologies used to discover and deploy AI-enhanced battery solutions.
What we Need The SES AI
Prometheus team
is seeking an exceptional
Computational Materials Scientist to
combine physics‑based simulation (DFT, MD, quantum modeling) with AI‑assisted material prediction to generate high-quality training data and accelerate materials discovery. This role is crucial for advancing our understanding of electrochemical energy materials at the atomic level. As a Computational Materials Scientist, you will be a core data‑driven modeler responsible for executing and automating complex simulations.
Essential Duties and Responsibilities
Atomistic Modeling & Simulation
Conduct and oversee DFT (Density Functional Theory), MD (Molecular Dynamics), and QM (Quantum Mechanics) simulations of battery components, including electrolytes, coatings, and electrodes.
Develop and refine ML‑enhanced force fields and surrogate models to accelerate simulation time scales and enable multi‑scale simulation efforts.
Apply expertise in atomistic simulation and quantum modeling to solve key challenges in electrochemical energy materials (e.g., batteries/fuel cells).
AI Data Generation & Prediction
Generate high-quality, structured simulation data to serve as training sets for AI property prediction models and material screening modules.
Contribute to the development of battery domain LLM features and advanced property‑prediction models.
Automate complex simulation workflows using strong coding practices to enhance efficiency and scalability.
Collaborate with experimental teams, leveraging a hybrid computational + experimental literacy to validate models and drive design iteration.
Utilize advanced simulation tools (VASP, Quantum Espresso) and data science libraries (TensorFlow, Pandas) to manage and analyze large datasets.
Education and/or Experience
Education: Ph.D. in Mechanical Engineering, Materials Science, Chemical Engineering, or a closely related computational/physics field.
Core Simulation Expertise: Deep and extensive experience in atomistic simulation and quantum modeling, including proficiency with key QM/DFT tools (VASP, Quantum Espresso) and MD simulations.
Domain Focus: Strong background in electrochemical energy materials and extensive computational work focused on batteries/fuel cells.
Coding Proficiency: Strong coding skills in Python (along with related libraries like Pandas and TensorFlow) for simulation workflow automation and data analysis.
ML Application: Experience in developing or utilizing ML‑enhanced force fields and surrogate models for materials prediction, or equivalent practical experience.
Preferred Qualifications
LLM Development: Experience in developing battery domain LLM features or property‑prediction models.
Hybrid Skillset: Demonstrated experience working in a hybrid computational + experimental environment.
Tooling Diversity: Familiarity with additional data analysis tools like R, SQL, MATLAB, and time‑series forecasting libraries like Prophet.
Target Background: Previous experience at national laboratories, XtalPi, Entalpic, or deep battery modeling groups.
Apply for this job #J-18808-Ljbffr