Home | QUANTUM INFORMATION WITH TRAPPED IONS

Welcome to the Laboratory for Quantum Information with Trapped Ions (QITI), led by Prof. K. Rajibul Islam at the Institute for Quantum Computing and the Department of Physics and Astronomy, University of Waterloo (Ontario, Canada).

We build programmable trapped-ion quantum processors and simulators, develop quantum control and simulation methods, and pursue open, full-stack approaches that accelerate the broader ecosystem.

Current flagship efforts include scaling trapped-ion platforms for quantum simulation and computation (Bloodstone, based on ytterbium ions) and advancing open hardware and software through Open Quantum Design (OQD).

What we do

Building quantum processors

We engineer scalable trapped-ion quantum processors with an emphasis on high-fidelity control, modular hardware, and paths to larger systems.

Explore our Processors

Quantum simulation and quantum information

Quantum simulation and computation

We develop quantum control protocols for trapped-ion qubits and explore algorithms for quantum simulation of complex, interacting many-body systems.

Research overview

Open full-stack ecosystem (OQD)

Through Open Quantum Design (OQD), we help build and share open hardware and software components that make trapped-ion systems more accessible and extensible.

Learn about OQD

Featured highlight

LightFlow Optics: A new lab startup for web-based optical circuit design

LightFlow Optics, co-founded in 2024 by Sainath Motlakunta, Chung-You (Gilbert) Shih, and Prof. Rajibul Islam, is building a cloud-based platform to design, visualize, and fabricate optical circuits with faster iteration and streamlined handoff to manufacturing.

Join and collaborate

We welcome strong applicants at the undergraduate, graduate, and postdoctoral levels, and we are interested in research collaborations across quantum science and engineering.

Join Research

We acknowledge financial support from the University of Waterloo, NSERC, the Government of Ontario, NFRF, and CFREF through the Transformative Quantum Technologies (TQT) program.

Recent Publications

Achieving 1E-5 level relative intensity crosstalk in optical holographic qubit addressing via a double-pass digital micromirror device

[2025]

Shilpa Mahato , Rajibul Islam

arXiv:2512.13882

We demonstrate that holographic beam shaping can suppress relative intensity crosstalk between neighboring ions to the (10^{-5}) level. This level of precision enables high-fidelity qubit control, including in situ mid-circuit measurement and reset operations.

A Room-Temperature Extreme High Vacuum System for Trapped-Ion Quantum Information Processing

[2025]

Lewis Hahn , Nikhil Kotibhaskar , Fabien Lefebvre , Sakshee Patil , Sainath Motlakunta , Mahmood Sabooni , Rajibul Islam

arXiv:2512.11794

Increasing ion lifetime by lowering background pressure is key for scaling quantum processors. Here, we demonstrate near–extreme-high-vacuum pressures in a room-temperature apparatus forming the core of the Bloodstone quantum processor, avoiding cryogenic complexity while enabling greater optical access for individual qubit control.

Mitigating Optical Crosstalk for In-Situ Mid-Circuit Measurement and Reset in a Trapped-Ion Quantum Simulator

[2025]

Shilpa Mahato, MSc thesis.

University of Waterloo [Thesis link]

Trapped-ion qubits have emerged as a leading architecture for building both digital and analog quantum computers. Their long coherence times, simple state preparation and …

All Publications

What we do

Building quantum processors

Quantum simulation and computation

Open full-stack ecosystem (OQD)

Featured highlight

Featured video

Join and collaborate

Recent News

Beryl traps its first ions!

10 Sep 2025 - Ali defends his MSc thesis!

10 Sep 2025 - paper on Optical Field Characterization with Ions is now up on Arxiv!

Recent Publications

Achieving 1E-5 level relative intensity crosstalk in optical holographic qubit addressing via a double-pass digital micromirror device

A Room-Temperature Extreme High Vacuum System for Trapped-Ion Quantum Information Processing

Mitigating Optical Crosstalk for In-Situ Mid-Circuit Measurement and Reset in a Trapped-Ion Quantum Simulator