QDM-Based Quantum Computing

Overview

DRY eWorks is at the frontier of quantum computer engineering, focusing on QDM-based (Quantum Dot Molecule) qubits. These scalable, semiconductor-compatible architectures allow us to design robust quantum processors using electron spin and charge state manipulation.

QDM-Based Qubits

Quantum Dot Molecules enable precise qubit manipulation through controllable coupling of quantum dots. Key innovations include:

Spin and Charge Encoding
Hybrid Qubits
Scalable Fabrication
Error-Tolerant Architectures

Join us on our Journey

Technology Comparison

Here's how QDM-based qubits compare with other leading quantum technologies:

Method	Mechanism	Hardware	Advantages	Challenges	Companies
Quantum Dot Molecules	Coupled quantum dots with tunable electron states	Semiconductor nanofabrication	Room-temp operation, scalable, CMOS-compatible	Precise control, quantum coupling complexity	DRY eWorks
Superconducting	Josephson junctions and microwave signals	Dilution refrigerators, RF equipment	Fast gate times, commercial momentum	Cryogenic needs, decoherence	IBM, Google
Trapped Ions	Laser-controlled ion states	Vacuum chambers, lasers	Long coherence times	Complex optics, low gate speeds	IonQ, Honeywell
Photonic	Photon entanglement & interference	Waveguides, detectors	Room-temp, low noise	Photon loss, scaling	Xanadu, PsiQuantum
Topological	Non-abelian quasiparticles	Exotic materials	Fault-tolerant by nature	Still theoretical	Microsoft
Neutral Atoms	Trapped in optical tweezers	Precision lasers, cooling systems	High flexibility, 3D scalability	Latency in gate ops	Pasqal, ColdQuanta

Our Vision

We envision quantum computers that are affordable, reliable, and ready for integration across domains. DRY eWorks is pushing quantum hardware toward nanoscale solutions that eliminate bulky cryogenic systems.

Scalable Design: Architectures that scale with classical chip infrastructure.
Cost-Effectiveness: Using standard fab processes for affordability.
Real-World Readiness: Qubits that operate at or near room temperature.