Cavity Quantum Optomechanics
Light exerts a force when it reflects from an object. This radiationpressure force is a central tool in optomechanics, which aims to utilise the
tools of quantum optics to prepare and study quantum states of motion of a mechanical resonator. We pursue research questions addressing the very
foundations of physics and develop optomechanical quantum technologies. Some examples of our recent work in quantum optomechanics includes:


Experimentally generating interference fringes in the motion of a mechanical resonator by projection onto an optical NOON state [New Journal of Physics 20, 053042 (2018)], and studying how these operations can be used to grow large mechanical superposition states [Quantum Science and Technology 4, 014003 (2019)].

Proposing how to perform phonon addition and substraction to a mechanical oscillator using single photon counting
[Physical Review Letters 110, 010504 (2013)],
and utilising such operations in combination with mechanical position measurements for quantum state engineering
[Physical Review A 93, 053818 (2016)].

Experimentally performing mechanical positionsquared measurements
[Nature Communications 7, 10988 (2016)],
based on exploiting the optical nonlinearity of the radiationpressure interaction
[Physical Review X 1, 021011 (2011)].

Proposing a pulsed approach for mechanical cooling and squeezing by measurement, as well as mechanical state tomography
[Proc. Natl. Acad. Sci. USA 108, 16182 (2011)].
We experimentally demonstrated this technique with a cantilever in an initial thermal state and achieved 36 dB of thermal noise squeezing
[Nature Communications 4, 2295 (2013)].

Brillouin Optomechanics

Using Brillouin scattering provides a promising new avenue to pursue quantum optomechanics. Some of our recent work in this area includes:

Performing the first experimental demonstration of Brillouin optomechanical strong coupling to high frequency phonons [Optica 6, 7 (2019)].

Towards TableTop Tests of Quantum Gravity
How does gravity affect quantum states of massive objects?
Can we find experimental signatures that help light the path to a theory of quantum gravity?
Our team is motivated by these, and related, questions and uses quantum optomechanics as an experimental testbed to search for potential quantumgravitational phenomena.
Some of our recent work in this area includes:

Developing a scheme how to probe quantumgravityinduced deformations to the canonical commutator between position and momentum (test the generalized uncertainty principle, GUP)
[Nature Physics 8, 393 (2012)].

Proposing a technique to amplify the signaltonoise ratio of our commutatorprobing scheme using an extended pulse sequence
[Physical Review A 96, 023849 (2017)].

Studying and contrasting the predictions made by classical and quantum physics for optomechanical protocols using closed loops in phasespace (geometric phases)
[Physical Review A 93, 063862 (2016)].


Hybrid Quantum Systems
Hybrid quantum systems combine the functionalities of two or more experimental systems in order to best utilize the advantages that each system affords or for quantum transduction/networking applications. Some of our recent work in this area includes:


Quantum Photonics

The quantum control of light is central to numerous experiments that aim to test the fundamentals of physics and develop new quantum technologies. We are pursuing both experiment and theory in quantum photonics and are interested in quantum sensing, simulation, and information applications. Some of our recent work in this area includes:

