Research

The Quantum Foundry’s research focus is broadly categorized into three main thrusts.

Thrust 1: Natively Entangled Materials

Thrust 1: Natively Entangled Materials

Materials with highly entangled many-body states and protected coherence.
Thrust 2: Interfaced Topological States

Thrust 2: Interfaced Topological States

Create and control protected quantum states via the creation of hybrid (ie. interfaced) materials.
Thrust 3: Coherent Quantum Interfaces

Thrust 3: Coherent Quantum Interfaces

Engineer material platforms that host localized quantum states with robust coherence.

 Highlights

thrust 1 image

Molecular Beam Epitaxy of Candidate Topological Superconductor Sr3SnO

Thrust 1: Research Highlight
Fermi surface and surface states measured with ARPES

Epitaxial Growth and Electronic States of Ultrathin Bi (111) Films on InSb (111)B

Thrust 2: Research Highlight
Lillian Hughes in the lab

Two-Dimensional Spin Systems in PECVD-Grown Diamond with Tunable Density and Long Coherence for Enhanced Quantum Sensing and Simulation

Thrust 3: Research Highlight
Figure 1

Incommensurate charge-stripe correlations in the kagome superconductor CsV3Sb5−xSnx

Thrust 1: Research Highlight
Mukherjee Group

Molecular beam epitaxy of PbSnSe semiconductors for quantum devices

Thrust 2: Research Highlight
A Surface Acoustic Wave Capacity Integrated with 2D Material Based Single Photon Emitters

Acoustic & Photonic Cavity Integration of 2D Material-based Single-Photon Emitters

Thrust 3: Research Highlight
2D PLOT 135

Coherent phonon spectroscopy of CsV3Sb5−xSnx

Thrust 1: Research Highlight