econd Harmonic Generation (SHG) is a nonlinear optical process where two photons combine to produce a single photon with twice the frequency of the original. This effect is highly dependent on material properties such as crystal symmetry and phase-matching conditions, making it a useful probe for optical material design. We aim to optimize SHG efficiency to enhance light manipulation in nanoscale systems by engineering material compositions, interfaces, and structural arrangements,
We investigate SHG in engineered perovskite and quantum nanostructures, focusing on tuning their nonlinear optical responses for improved phase-matching and coherence lengths. Through precise control over material interfaces and structural configurations, our work aims to enhance SHG output, expanding its applications in optoelectronics and integrated photonics.
Our studies leverage advanced techniques to characterize and refine these nonlinear interactions, contributing to the development of next-generation optical devices. By understanding and optimizing SHG processes in novel materials, we aim to push the boundaries of frequency conversion, quantum optics, and ultrafast photonic technologies.