Systems & Products

Modular UHV and cold-atom platforms designed for reproducible research, long-term stability, and industrial deployment.

Product Philosophy

All systems are designed as modular building blocks rather than monolithic instruments. This allows laboratories and industrial teams to scale, reconfigure, and maintain their platforms over time without vendor lock-in.

Each module is delivered with full documentation, physics rationale, and integration guidelines.

Core Systems

2D MOT Platform

A compact, high-flux cold-atom source optimized for continuous loading of downstream traps. Designed for stable long-term operation under UHV conditions.

Key Features

  • High atomic flux with low divergence
  • Rubidium and Cesium compatible
  • CF-based UHV mechanical interfaces
  • Optimized optical access and beam geometry

Typical Use

  • Loading of 3D MOT systems
  • Cold-atom beam experiments
  • Compact quantum sensors
UHV Cold Atoms Modular

Zeeman Slower

Custom-designed Zeeman slowers with numerically optimized magnetic field profiles for maximum capture efficiency.

Key Features

  • Tailored magnetic field profiles
  • Thermal-magnetic co-design
  • Low power consumption options
  • Integrated thermal management

Typical Use

  • High-velocity atomic beam slowing
  • Improved MOT loading efficiency
  • Precision cold-atom experiments
Magnetic Design Beam Slowing High Stability

3D MOT Chamber

A science-grade three-dimensional MOT chamber designed for sub-Doppler cooling, long trap lifetimes, and downstream quantum manipulation.

Key Features

  • Optical-grade viewports
  • UHV / XHV compatible materials
  • Magnetic field symmetry optimization
  • Ready for optical or magnetic trapping

Typical Use

  • Ultra-cold atom preparation
  • Quantum sensing and metrology
  • Foundations for optical lattices and traps
3D MOT Quantum Ready Research-Grade

Customization & Integration

All systems can be adapted to specific experimental, spatial, or operational constraints. This includes mechanical customization, thermal design, magnetic field tailoring, and integration with existing vacuum infrastructure.

Control interfaces are designed to integrate naturally with modern experiment automation, logging, and AI-based optimization frameworks.