Lorenzo Miri

Lorenzo Miri's picture

Ph.D. candidate in Ingegneria Elettrica, Elettronica E Delle Comunicazioni , 39th cycle (2023-2026)
Department of Electronics and Telecommunications (DET)

Profile

PhD

Research topic

UltraViolet Light Emitting DIodes (UV-LED)

Tutors

Research interests

Computational Electromagnetics (CEM) and EM simulation
Electronic devices: modeling and characterization
Micro- and nanotechnologies, devices, systems and applications
Modeling, simulation and CAD
Photonic devices and solar cells

Biography

I deal with multi-physics simulations of semiconductor-based opto-electronic devices using in-house TCAD (technology computer aided design) tools developed by our research group. Specifically, I deal with a specific type of LED, operating in the UVC band (Ultraviolet C Light Emitting Diodes), useful in many applications ranging from sterilization to biosensing. This type of devices can integrate a tunnel junction to deal with technological problem involving p-dopants for nitride-based semiconductors. In this view, to properly simulate such devices, it is required to analyse them from the quantum transport standpoint (non-equilibrium Green's function approach for electrons and holes, coupled together) and to the semiclassical electronic transport standpoint (drift-diffusion). The aim of this project is to obtain a combined description of the device that can approximate as much as possible the real behaviour of real UVC-LEDs in terms of IV characteristic.

Research

Other activities and projects related to research

I deal with multi-physics simulations of semiconductor-based opto-electronic devices using in-house TCAD (technology computer aided design) tools developed by our research group. Specifically, I deal with a specific type of LED, operating in the UVC band (Ultraviolet C Light Emitting Diodes), useful in many applications ranging from sterilization to biosensing. This type of devices can integrate a tunnel junction to deal with technological problem involving p-dopants for nitride-based semiconductors. In this view, to properly simulate such devices, it is required to analyse them from the quantum transport standpoint (non-equilibrium Green's function approach for electrons and holes, coupled together) and to the semiclassical electronic transport standpoint (drift-diffusion). The aim of this project is to obtain a combined description of the device that can approximate as much as possible the real behaviour of real UVC-LEDs in terms of IV characteristic.

Publications

Latest publications View all publications in Porto@Iris