My research focuses on mesoscopic superconductivity and quantum devices built from semiconductor–superconductor hybrids and quantum dots. I develop fabrication methods and low-temperature transport techniques to engineer and probe proximity effects across superconductor–semiconductor interfaces in mesoscopic devices. Using these tools, I have explored minimal Kitaev chains in coupled quantum dots, Cooper-pair splitting with singlet/triplet control, gate-tunable Josephson-diode effects, and electrostatic control of bulk proximity effects in hybrid devices. Earlier work spans topological materials, graphene superlattices, and superconductivity in hyperdoped semiconductors. My overarching aim is to establish controllable building blocks for novel, protected qubits and to create a platform for realising new states of matter in artificial quantum systems. Looking ahead, I will extend these efforts to planar semiconductor–superconductor hybrids based on two-dimensional hole gases in strained Ge/SiGe quantum wells—a CMOS-compatible platform with the potential to scale proof-of-concept quantum devices.