1). Generation of a range of entangled states of two distant and disparate macroscopic objects
- a novel approach towards entanglement generation between those two macroscopic systems
- generation of an entangled state of a mechanical oscillator, a mm-size dielectric membrane and an
atomic spin oscillator built of 100 million atoms. Nature Physics, highlighted in by Nature News and Views and other outlets.
2). Demonstration of the measurement of force and acceleration beyond the standard quantum limit
of sensitivity.
- transduction of electric and magnetic signals to the optical domain, magnetocardiography on an isolated animal
heart, magnetic resonance imaging and detection of low-conductivity objects with an optical magnetometer.
3). Observation of macroscopic superposition states of moving millimetre size objects is fundamental for testing the limits of quantum theory.
- a macroscopic object, a mm size dielectric membrane, is cooled close to near absolute zero temperature
- photon scattering signifying the processes of adding and subtracting a single motional phonon
- a single spin excitation in a macroscopic ensembles of room temperature atoms.
4). Feasibility studies of application of the negative mass idea to multipartite entanglement involving
spins, photons and massive objects such as mirrors of gravitational wave interferometers.
- development of a "negative-mass quantum noise eater" which can be used for the proof-of-principle demonstration of enhanced sensitivity of
gravitational wave interferometers (GWIs), such as LIGO
- a magnetic "negative mass" oscillator in the quantum regime, and a source of entangled light which couples to the atomic negative mass system and to the GWI
A new idea paves the way towards experimentally feasible implementation of the negative mass atomic system.
5) We have demonstrated a macroscopic superposition state within a macroscopic atomic object and used it as a single photon source with built-in memory.
6) The first evidence of a single quantum excitation (Fock state) of motion of a macroscopic object is observed
7) We have invented and demonstrated magnetic induction tomography with an atomic ensemble in a quantum squeezed state providing an enhanced sensitivity to detection of weakly conducting objects