Tellier Dynamics operates on a timeline measured in centuries. Our directive is to align civilization with the geodynamo, responsibly tapping into the planetary engine that powers Earth's own magnetic shield.
The Physics works.
The Drill is catching up.
We have designed the Telluric Radial Systemâ„¢ (TRS) to be the definitive architecture for safe, predictable, scalable baseload geothermal power. However, we are pragmatic about the present reality. Current mechanical drilling costs make deep conductive loops economically challenging at scale.
The industry requires a fundamental step-change in subsurface access to make 10km+ depths viable.
We mitigate risk by design. Beyond cost, the critical challenge of the geothermal century is safety. Unlike EGS approaches that rely on hydraulic fracturing to create permeability, our closed-loop architecture maintains complete hydrostatic control. We focus relentlessly on mitigating the risks of induced seismicity, ensuring that planetary-scale power does not come at the cost of local tectonic stability.
We are engineering the bridge. The challenge of directed-energy drilling isn't just vitrifying rock; it is maintaining precision collimation over 20 kilometers of borehole-as-waveguide. We are actively modeling the complex physics required to stabilize the beam at extreme depths and the thermodynamic geometries necessary to "turn the beam", enabling the transition from vertical access to the lateral radial systems required for safe + scalable power.
We deploy our proprietary simulation stack to solve high-value thermal problems for industrial partners. By applying our optimization algorithms to developing energy systems, we validate our models and generate immediate revenue to fund autonomous R&D.
Execution of the TRS architecture in shallower, permeable formations where mechanical drilling is viable today. This establishes the first grid-connected pilots and proves the "Phased Scaling" economic model.
Integration with Directed Energy Drilling (DED) systems. Once drilling costs decouple from depth, we deploy the TRS at 10km+, unlocking terawatts of permanent, planetary-scale power.
We operate a solver-agnostic computational pipeline. Depending on the thermodynamic regime, we utilize the optimal kernel for the task, ranging from industry-standard coupled THM solvers to custom-built fluid dynamic engines.
From custom Linux kernel optimization for high-throughput data acquisition to designing closed-loop fluid networks, we bridge the gap between theoretical physics and deployable hardware.
We maintain internal high-density compute clusters with a demonstrated background in systems security. This allows for rapid iterative prototyping and massive parallelization without the security risks or latency of public cloud environments.
We specialize in refactoring legacy scientific code for modern hardware. By porting serial CPU bottlenecks to parallelized CUDA/C++ workflows, we frequently reduce simulation runtimes by orders of magnitude.
Founder & Lead Engineer
Sam combines a background in physics and computational engineering with a deep commitment to environmental preservation. His work focuses on designing energy systems that function in harmony with the biosphere, rather than extracting from it. He founded Tellier Dynamics to tackle the specific thermodynamic constraints that must be solved to secure a sustainable future for generations to come.
Cornell University
Physics & Computer Science
Multi-Physics Modeling
Secure HPC Integration