Work began with defining detailed system requirements based on state-of-the-art analysis and application needs in photonics, MEMS, advanced packaging, sensors, and meta-optics. A high-power spun tapered double-clad fibre amplifier achieved 110 W average power at 1040 nm, producing 9 ns pulses at 100 kHz with 1.1 mJ energy, M² < 1.2 and >97.5% polarisation purity. Temporal coherence lengths up to 177 cm exceeded the 1.5 m target after frequency conversion to 345 nm. The adaptive optics module, incorporating a 37-channel deformable mirror with R=99% coating at 347 nm, achieved λ/20 correction under simulated 20 W thermal load. The alignment system was prototyped and verified, delivering sub-10 nm coordinate accuracy, translating to <25 nm overlay in final use.
The 388 nm test bench was assembled, aligned, and validated through initial exposures, confirming system functionality and identifying optimisation routes. The first binary amplitude holographic mask was designed, fabricated, coated, and characterised to inform improved second-generation masks. A rigorous Maxwell-based vector diffraction engine was implemented and validated, while experimental resist characterisation at 388 nm enabled accurate exposure modelling for binary and grayscale mask synthesis.
By the end of the period, all major technical building blocks—high-coherence laser, precision alignment, adaptive optics, validated modelling tools, and first-generation masks—were delivered. Integration with frequency doubling and process optimisation will lead to the final cleanroom demonstration.