I carried out a key validation of our model of dark matter: I combined two maps of dark matter obtained by completely different techniques and by independent teams, and recovered a correlation over the overlapping area and epochs. This lead to two (first author) publications since January 2016.
Within the Kilo Degree Collaboration, I am leading the numerical modelling of the weak lensing observations, which is required for the interpretation of the measured cosmic distortions. This role places me at the centre of a group of scientists that intent to use my tools, control samples and mocks data. I am thereby involved in many projects, including the study of cosmic shear (Hildebrandt et al, 2017, MNRAS. 465, 1454), hot gas (Hojjati et al, 2017, MNRAS, 471, 1565) on cosmological scales, combined probe analysis (Harnois-Deraps et al, 2017, MNRAS, 471, 1619), test of models of gravity beyond Einstein General Relativity (Amon et al, 2017, arXiv:1711.10999) and the weak lensing investigation of extremely under-dense regions of the cosmos, also called cosmic voids (paper in preparation).
These studies provided tight constraints on many of the parameters from theoretical cosmological models.
I have also contributed to two independent studies (Sellentin et al, 2017, arXiv:1712.04923 plus one in preparation) that address issues of inaccurate inference in cosmic shear measurements, despite the data and modelling being correct.
All these studies paved the way for upcoming similar analyses with the next generation of galaxy surveys (e.g. LSST, Euclid). Many of the tools will be re-used and many of the analyses strategies will be adopted.
I am jointly supervising a PhD student, I supervised two summer projects and a Honours 1-term project taken by undergraduate students.