Semiconductors

Optimize crystal growth for space-based fabrication.

Improve crystal growth, reduce gravity-driven defects, and optimize fabrication processes for space-based semiconductor manufacturing.

The challenge

Gravity limits crystal quality on Earth.

Semiconductor crystal growth on Earth is limited by buoyancy-driven convection, which creates defects and non-uniformities. Microgravity eliminates these effects — but optimizing the process in space requires expensive, iterative experimentation.

Defect rate reduction
possible in microgravity

10x

Crystal uniformity
improvement

How G-SPACE helps

Model yield before you fly.

Growth simulation

Model crystal growth under varying microgravity conditions to predict wafer quality and optimize pull rates, temperatures, and dopant concentrations.

Defect prediction

Forecast defect density and distribution for different process configurations, minimizing waste and maximizing usable wafer area.

Yield optimization

Find the process window that maximizes yield for your target material and specification, reducing the number of flights to production readiness.

Use cases

Applications in semiconductors

Silicon and gallium arsenide crystal growth
Wafer quality optimization
Defect reduction and uniformity improvement
Novel semiconductor material discovery

Ready to start

Optimize your semiconductor manufacturing in space.

Book a demo to see how G-SPACE predicts crystal quality and optimizes growth parameters.

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