Boundary conditions belong to faces
Pick a face once. Its thermal or mechanical condition follows that face through meshing and solver handoff.
Build the geometry, mesh it, characterize heterogeneous materials, configure constitutive laws and boundary conditions, solve coupled THMC-G physics, and interpret the results inside one object-oriented desktop workflow. The same model becomes the base for scientific data management, custom simulation apps, digital twins, uncertainty studies, and AI-assisted decision support.
Geometry, meshing, material characterization, the coupled solver, data records, and the result viewer share one model. Terra Multiphysics keeps the engineering objects intact, then extends the same model toward imaging, monitoring, uncertainty studies, custom apps, and operating digital twins.
Build and edit solids on an owned CAD kernel — primitives, booleans, transforms, and face-level boundary conditions.
Learn more →Automatic tetrahedral meshing at coarse, medium, or fine resolution — no manual element work.
Learn more →A coupled thermo-hydro-mechanical-chemical-gas finite-element engine for heterogeneous and evolving porous media.
Learn more →Surrogates, uncertainty studies, monitoring links, and AI-assisted tools turn validated model evidence into faster decisions.
Learn more →Roadmap layer for team-specific simulation apps, operating digital twins, field data integration, and GPU/HPC-ready batch workflows.
Learn more →Integrated plan, section, and 3-D views from the same finite-element model, with traceable result interpretation.
Learn more →Solids, faces, pipes, materials, constitutive laws, boundary conditions, physics settings, solver cases, scientific data, and result fields live as named objects inside the same project.
Pick a face once. Its thermal or mechanical condition follows that face through meshing and solver handoff.
Soil, rock, gas, fluid, and pipe definitions are model objects, so heterogeneous regions can reuse the same constitutive laws without duplicating input blocks.
Each solver case carries its settings, source objects, mesh, monitoring records, and result fields. You can compare runs without losing where they came from.
Build the model from scratch on an owned CAD kernel - no external pre-processor in the loop.
Start from boxes, cylinders, and other primitives, then combine them with boolean union, cut, and intersection, plus transforms, to build the model geometry directly in the app.
Pick individual faces of a solid and assign temperatures or other boundary conditions to them, so the boundary setup follows the geometry instead of a separate mesh-side workflow.
Save a model and reopen it later. The geometry flows straight into meshing, THMC-G solving, visualization, data management, and deployment as one reproducible pipeline.
A built-in mesher turns the geometry into an analysis-ready tetrahedral mesh, automatically.
Mesh the model directly from the built geometry — no hand-built elements and no external pre-processor between geometry and solve.
Choose a resolution to trade speed against detail. A design mesh resolves the trends quickly; a fine mesh sharpens the field where it matters.
The mesh hands off to the coupled engine as part of one reproducible pipeline, so geometry, mesh, solve, visualization, data records, and deployment studies stay self-consistent.
A custom finite-element solver resolves coupled thermal, hydraulic, mechanical, chemical, and gas transport processes together, with support for heterogeneous and evolving porous media.
A monolithic Newton-Raphson scheme solves the coupled fields together, capturing feedback between heat, flow, deformation, chemical change, and gas transport.
Soil and rock constitutive laws, transport parameters, and heterogeneous material regions are explicit model objects, ready for laboratory calibration and field comparison.
Engineered components, porous media, and boundary processes are resolved inside the same solve, so the platform can grow from geo-energy cases to broader subsurface infrastructure.
Validated coupled runs, monitoring data, uncertainty quantification, and surrogate models can turn the finite-element platform into fast design exploration and AI-assisted decision support.
For the current geo-energy demo, outlet temperature, heat delivered, and pressure drop return in one shot - validated to R² 0.9997 against held-out solver runs.
Global sensitivity, confidence intervals, and uncertainty bands show which inputs drive the result and where the model needs better data.
Map candidate designs to a performance frontier, connect field observations to model updates, and use AI support to help interpret scenarios without losing traceability.
Read the result without exporting it. Integrated plan, section, and 3-D views render fields straight from the same finite-element model.
Inspect the model as plan views, vertical sections, or colour-mapped 3-D fields, with result interpretation tied back to the source objects.
See domain, engineered components, and subsurface fields together - self-consistent IDs straight from the same solve, no re-import.
Rotate the result to look at the field from any angle - interactive 3-D results in the same workflow as geometry, mesh, solve, and data review.
The current product is a desktop workflow for validated subsurface modelling. The next layer packages those workflows into repeatable tools teams can deploy, automate, connect to field systems, and use as operating digital twins.
Package a validated Terra Multiphysics workflow for one repeated engineering task, so teams can run it without rebuilding the model from scratch each time.
Connect design models to monitored field data, compare expected and observed behaviour, and help owners tune subsurface assets over time.
Scale batch solves, geophysical imaging links, uncertainty studies, surrogate training, and larger validation campaigns while keeping the desktop app as the engineering control room.
A standard Windows desktop is enough for the current application. Terra Multiphysics is self-contained - its own geometry builder, mesher, solver workflow, visualization, data layer, and AI demo, with GPU/HPC scaling on the roadmap.
The current workflow runs locally on your machine. No cloud account or internet connection is required to model, mesh, solve, manage project data, or view results.
Project data never leaves your computer. The optional natural-language copilot is the only feature that can call an external service, and only if you switch it on with your own API key.
Geometry, meshing, material setup, the coupled solver, visualization, and data-driven tools ship as one installer - no external pre-processor and no dependency chase.
We're onboarding a small group of early-access design partners now.
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