Technique - (2) Atom interferometry inertial sensing (compact/fieldable)

Type: Experimental

Description: Cold-atom-based accelerometers and gyroscopes built for field deployment on ships, underground, and in the Arctic, achieving GPS-denied quantum-enhanced inertial navigation.

Department(s)/lab(s): Physics – QOLS / Centre for Cold Matter | Centre for Cold Matter – Quantum Navigation @ Imperial
Summary:

Cotter leads the Quantum Navigation research stream at Imperial's Centre for Cold Matter. He develops compact, fieldable cold-atom inertial sensors for GPS-denied navigation. Milestones: first demonstration of a cold-atom accelerometer on the London Underground (measuring acceleration/vibration in a real transit environment); successful field trials of quantum inertial sensors aboard the Royal Navy research ship XV Patrick Blackett (2023); Arctic field trials with Royal Navy (2025). His sensors use magnetically launched cold-atom Rb clouds and simultaneous multi-axis interferometry. He also contributes to AION-related atom interferometry work and the Quantum Technology Hub in Sensors and Timing. Department of Materials cross-appointment.

Department(s)/lab(s): Physics | SYRTE - Cold Atom Interferometry & Inertial Sensors Team @ CNRS
Summary:

Landragin directs SYRTE and its Cold Atom Interferometry and Inertial Sensors team, which develops light-pulse atom interferometers as absolute gravimeters and gyroscopes: the Cold Atom Gravimeter (CAG), whose single-laser pyramid-reflector design he co-invented and commercialized through the start-up Muquans (now Absolute Quantum Gravimeter, AQG), and continuously-operating cold-atom gyroscopes reaching record joint sensitivity. Applications span geodesy, hydrology, volcano monitoring and inertial navigation. He received the CNRS Innovation Medal in 2020.