OUR VISION
AXIOMERA was founded with a singular vision:
To unlock the full potential of quantum technologies by overcoming the limitations of traditional manufacturing processes.
Traditional lithography and etching introduce impurities and defects that compromise the performance of quantum devices. Our breakthrough Functional Atomic Layer Deposition (FALD) technology eliminates these challenges, enabling the creation of ultra-pure, defect-free nanolayers essential for high-coherence qubits.
Why it matters?
- Ultrapure and Defect-free films
- Nanometer level control of film thickness
- Three-dimensional deposition control
- High reproducibility and repeatability
- Material versatility
- Engineered and tunable film structures
OUR STORY
The "Quantum Axiom"
In quantum computing, perfection is the ultimate axiom – a fundamental truth that defines the boundary between theoretical promise and practical reality.
The “Quantum Axiom” is an ideal state where every atom, every layer, and every junction is precisely placed, enabling quantum systems to function at their theoretical limits.
Yet, in reality, perfection is unattainable. Manufacturing processes introduce imperfections -defect, impurities and inconsistencies – leading to noise, decoherence and errors, pulling quantum devices away from their ideal performance.
The Reality
Imperfection is the norm…
Traditional manufacturing processes, such as lithography combined with etching process, inherently introduce impurities and defects. These processes, while effective for classical devices, fall short for quantum systems, where even a single defect can disrupt coherence and compromise performance.
The challenge is not to achieve absolute perfection – an impossible mission – but to get as close as possible to it.
The Breakthrough
Our proprietary and unique approach:
Functional Atomic Layer Deposition (FALD)
is a nanoscale deposition technology enabling selective, ultra pure and defect free thin film material deposition in a single machine.
At AXIOMERA – we’ve redefined what’s possible in quantum device manufacturing.