"The first project focused on certifying quantum measurements with two outcomes (so-called binary measurements). We used a simple mathematical approach to design robust self-testing procedures for pairs of binary measurements, which can be applied to every pair of binary measurements. The results were published in Physical Review A.
The second project was a big international collaboration with researchers from Canada, Hungary, Taiwan and Singapore. We posed many important and fundamental questions about the nature of quantum correlations and answered them. The results were published in Physical Review A.
The next two projects resulted from a fruitful collaboration with the Group of Applied Physics at the University of Geneva. We have realised that some techniques developed previously can be applied to new scenarios. In particular, we have developed a procedure for certifying states and measurements in the prepare-and-measure scenario (related to the so-called ""quantum random access codes"") and a procedure for certifying entangled measurements in the bilocality scenario (two independent quantum sources). The results are available at an online repository (the arXiv) and are currently under review.
The last project was a collaboration with Institute for Photonic Sciences (Barcelona, Spain) and Center for Theoretical Physics (Warsaw, Poland). We have provided a procedure to certify the maximally entangled state of two qutrits and a particular type of important quantum measurements acting on it (three ""mutually unbiased bases""). We are currently working on generalising this approach to higher-dimensional systems. The results are available at an online repository (the arXiv) and will be submitted to a journal soon."