A Multiphoton Polymerisation Femtosecond Laser System works by focusing ultrashort laser pulses into a photosensitive material, where nonlinear absorption triggers polymerisation only at the focal volume. This voxel-by-voxel process enables true volumetric fabrication rather than conventional layer-by-layer printing. As a result, users can create suspended structures, internal channels, overhangs, and highly complex geometries with nanometre-scale control. Advanced motion stages, high-NA optics, and intelligent software ensure precise positioning, repeatability, and smooth integration from 3D CAD design to finished microstructures.

Ultrafast Femtosecond Laser Pulses

Femtosecond pulses enable nonlinear absorption and cold processing, preventing thermal damage while achieving exceptional spatial resolution.

Submicron and Nanoscale Resolution

The system supports feature sizes down to ~100–200 nm, making it suitable for nanophotonics, metamaterials, and biomedical microdevices.

True 3D Freeform Fabrication

Unlike conventional 3D printing, MPP allows fabrication of complex internal and suspended structures without support material.

High Numerical Aperture Optics

High-NA objectives provide tight focusing and isotropic voxel control for uniform resolution in all three dimensions.

Multi-Axis Precision Motion

Closed-loop XYZ stages and galvanometric scanners ensure smooth, accurate motion across large fabrication volumes.

Wide Material Compatibility

Supports a broad range of photopolymers, hybrid organic-inorganic resists, bio-resins, and functional materials.

Integrated CAD-to-Fabrication Workflow

Advanced software imports STL and CAD files, performs slicing, optimises exposure parameters, and visualises fabrication in real time.

Real-Time Monitoring and Process Control

Built-in imaging and feedback systems ensure alignment accuracy, process stability, and repeatable fabrication quality.

Scalable for Research and Prototyping

Ideal for single-device research as well as small-batch production of high-precision microcomponents.

Biomedical Engineering and Tissue Engineering

Fabrication of 3D scaffolds, microneedle arrays, cell traps, and drug-delivery microstructures with biocompatible materials.

Microfluidics and Lab-on-a-Chip

Creation of closed microchannels, mixers, valves, and integrated optofluidic components without bonding or assembly.

Photonics and Integrated Optics

Direct writing of waveguides, micro-lenses, gratings, couplers, and photonic interconnects with precise optical alignment.

Nanophotonics and Metamaterials

Manufacturing of chiral structures, photonic crystals, plasmonic scaffolds, and sub-wavelength optical elements.

MEMS and NEMS Prototyping

Rapid prototyping of compliant mechanisms, micro-springs, actuators, cantilevers, and micro-robotic components.

Aerospace, Defence, and Quantum Technologies

Production of lightweight optical mounts, alignment jigs, quantum photonic circuits, and miniaturised sensor platforms.

Biosensing and Diagnostics

Development of high-surface-area biosensors, SERS substrates, microcavities, and integrated chemical analysis platforms.