چكيده لاتين
With the rapidly growing demand for high bandwidth in modern processing and communication systems, silicon optical modulators based on micro-ring resonators have attracted significant attention as one of the key components of silicon photonics. These modulators, by exploiting the free-carrier plasma dispersion effect, enable high-speed and low-power electro-optic modulation. However, the main challenge in structures based on free-carrier depletion lies in the intrinsic trade-off between modulation efficiency and bandwidth, which limits their overall performance.
In this thesis, to investigate and optimize this challenge, the performance of silicon micro-ring modulators based on PN junctions with various configurations including horizontal, vertical, and U-shaped arrangements has been analyzed, and the Z-shaped structure has been simulated as the optimal option. The designs and simulations were carried out using Lumerical software in several stages: starting with waveguide mode analysis and coupling coefficient calculation, followed by modeling of doping profiles and electric fields, and finally, dynamic performance evaluation of the modulator through both frequency- and time-domain simulations. Key parameters such as refractive index variation, modulation efficiency, bandwidth, frequency response, and power consumption were assessed.
The simulation results demonstrate that the Z-shaped PN junction structure, with its optimized design, provides a superior balance between modulation efficiency and bandwidth compared to other configurations. Moreover, the Z-shaped design achieves a remarkable improvement in response speed and efficiency by reducing series resistance and junction capacitance, offering the potential to reach modulation rates in the range of hundreds of gigabits per second. This makes it a promising candidate for next-generation high-speed intra-chip and inter-chip optical interconnects.
The findings of this research provide valuable theoretical and practical insights into the optimization of PN junction configurations in silicon optical modulators. Furthermore, by confirming the effectiveness reported in recent studies and offering precise numerical analysis, this work takes an important step toward advancing silicon photonics technology toward ultra-compact, low-power, and high-speed integrated chips.
