Electric field enhenamnet distribution of a gold Canadian nano-flag at the wavelength of 2.6 micrometers.

Nipissing Computational Physics Lab (NCPL) aims to develop, implement, and utilize advanced numerical algorithms and computational techniques to address challenges in nanophotonics, particularly in nanotechnology and nanomedicine applications. Our lab is designed for junior and senior science and engineering students.

We focus on creating algorithms for nanoscale and multiphysics problems, represented by 3D fully coupled partial differential equations. To achieve this, we utilize a high-performance computational server and multiple workstations with various operating systems, enabling us to work on diverse computational and simulation programs.

By employing cutting-edge computational methodologies, our lab tackles complex nanoscale problems, contributing to advancements in nanophotonics and its applications in nanotechnology and nanomedicine.

Recently, within the scope of light matter interaction topics, we have published and been working on the following areas. For more details please click on the research link.

• Photothermal Processes in Phase-Change Material-Enhanced Photonic Structures
• Nanoparticle-Mediated Photodynamic and Photothermal Therapies
• Photoacoustic Responses of Nanostructures Under Pulsed Laser Irradiation 
• Plasmonic Enhancement of Continuous Wave, Short, and Ultrashort Laser Interactions with Metallic Nanostructures 
• Hybrid Nanostructures through Combining Quantum Dots and Plasmonic Nanostructures

You can also see our google scholar profile: