Quantum Computers,
Built for the Real World

Our technology

Making entanglement reliable

At the core of our approach is on-demand entanglement — a deterministic way to generate and distribute entanglement, which makes photonic quantum systems practical rather than experimental. In simple terms: we produce the quantum resource we need when we need it, so the system can scale without the overhead of probabilistic workarounds.

What we do

Improving the quality of simulation results

Many of today’s hardest problems in materials, chemistry, manufacturing, and life sciences cannot be accurately simulated with classical computers. The number of possible quantum states grows too fast, forcing classical simulations to rely on heavy approximations.

As a result, innovation often depends on trial and error rather than reliable insight. Quantum computers can model these systems more naturally, reducing reliance on approximations and improving the quality of simulation results.

Our core principle: Quantum computers should be

Deterministic

Scalable

Deployable

Useful

What’s Inside

Built for scale. High speed, fibre connected, telecom compatible modules

Connecting photon sources with low loss optical switching and processing using standard telecom fibre. Bringing quantum photonics out of the lab and into real-world infrastructure.

Create

Telecom Photon Sources

Proprietary quantum dot technology on
Indium Phosphide

Route

Optical Switching

High-speed, low-loss lithium niobate

Compute

Quantum Processing Units

Silicon integrated photonic processors

Measure

Single Photon Detectors

Superconducting detectors

PHOTONIC CORE

QGATE. Architecture for photonic quantum computing

World's first architecture based on Aegiq’s deterministic photon sources to create large, entangled cluster states

Find out More

Significantly reducing component count and physical size to make on-prem, rack deployment a reality

Reducing compilation time by several orders of magnitude, which can otherwise negate any benefit from quantum hardware.

Improving the thresholds for photonic loss, bringing the era of photonic quantum error correction into the near term.

Our approach

What makes Aegiq different

We generate entanglement on demand

It removes the reliance on probabilistic processes and eliminates the need for complex scaling workarounds. This allows entanglement to be distributed across a modular, manufacturable platform, bringing quantum systems closer to practical scalability beyond laboratory demonstrations.

We use deterministic single-photon sources

It enables reliable large-scale quantum operations, removes hidden scaling overhead, and simplifies system design. By avoiding the complexity traps of probabilistic photonics, this creates a clearer, more predictable path to practical quantum computing.

We built the QGATE architecture thatreduces routing and gate decomposition

While keeping compilation manageable as systems grow. The architecture increases tolerance to optical loss — up to 26% — making modular, fibre-connected quantum systems more robust and scalable.

What this enables

Quantum simulation for real-world impact

By moving beyond trial-and-error, quantum simulation enables faster iteration, better decisions, and clearer paths to performance improvements. Our technology is focused on quantum simulation for real-world impact, including:

materials and chemistry (batteries, catalysts, alloys, polymers)

advanced manufacturing and complex physical processes

life sciences and molecular interactions

INTERPRETING QUANTUM RESULTS

Built for the real world

Aegiq’s quantum computers are designed to move beyond laboratory demonstrations and into real computing environments. By focusing on deterministic photonics and on-demand entanglement, we reduce complexity, enable realistic scaling,

and build systems that can be deployed alongside existing HPC, GPU, and AI infrastructure.

Our goal is simple: make quantum computing reliable, practical, and useful at scale.

What you can trial first

Workload discovery

Identify simulation targets where quantum methods are expected to help (chemistry, materials, process models).

Integration planning

How a rack-deployed quantum system would sit alongside your HPC/GPU stack.

Roadmap and benchmarks

Agree success metrics and a step-by-step path to larger problem sizes.

Application

Driving quantum innovation across industries

With unprecedented capabilities, quantum computing will reshape industries by solving critical, large-scale problems.

Quantum Computers,
Built for the Real World

Making entanglement reliable