This research explores quantum radar signal processing, using quantum entanglement to improve detection by better separating signal from noise. It demonstrates that quantum radars are experimentally viable and mathematically comparable to conventional systems, with potential advantages. Applications include low-power, safe technologies such as medical imaging and interference-free sensing.

Inspired by bird flight, this research investigates how wingtip feathers influence aerodynamics. Using bioinspired design, 3D-printed models, and wind tunnel experiments, it isolates the effects of feather separation, bending, and twisting. These insights improve aircraft stability, lift, and maneuverability, offering pathways to safer and more efficient aviation in turbulent environments.

My thesis describes how laboratory experiments recreate nuclear reactions occurring on accreting neutron stars. By developing a novel particle detection system, I achieved the first simultaneous neutron–proton measurements, enabling more complex studies that illuminate extreme matter, stellar evolution, and the cosmic origins of elements fundamental to life.