The nonstop scaling of Metal-Oxide-Semiconductor Field-Effect Transistors (MOSFETs) is considered a driving force in semiconductor technology, allowing higher integration densities, enhanced performance, and reduced power consumption. However, fundamental challenges arise as device dimensions shrink to the nanoscale, such as short-channel effects, threshold voltage variation, leakage currents, and gate oxide tunneling. This study critically surveys these scaling limitations and shows potential solutions, such as high-k gate dielectrics, metal gate integration, and novel device architectures. Other transistor designs, including FinFETS, Gate-All-Around (GAA) transistors, and emerging beyond-CMOS devices, are assessed for their potential to extend Moore's Law. This study also addresses advancements in materials, including two-dimensional (2D) semiconductors and carbon-based nanostructures, that offer promising substitutes to conventional silicon technology. Regardless of these innovations, significant obstacles remain in achieving fabrication, reliability, and cost-effectiveness at sub-5nm nodes. This review paper provides insights into current progress and future guide for nanoscale MOSFET development, comprehensively assessing the challenges and opportunities in next-generation transistor technology. The findings aim to guide researchers and industry professionals toward sustainable semiconductor scaling approaches.
Solar cells play a vital role in renewable energy systems, and ongoing research is dedicated to enhancing their power efficiency and longevity. Advancements in perovskite solar cells, particularly in power conversion efficiency (PCE), have shown significant progress, confirming its viability as a technology. Perovskite solar cells have achieved power conversion efficiency (PCE) levels of up to 25.5%, comparable to conventional photovoltaic technologies like silicon, gallium arsenide, and cadmium telluride. The substantial enhancement in power conversion efficiency figures over the last decade has shown a remarkable advancement in the efficiency of perovskite solar cells. This study examines the trajectory of perovskite solar cells in becoming economically feasible and generally embraced as a critical renewable energy technology. The advancement of flexible and wearable solar cells, together with miniature solar-powered sensors, has increased the efficiency of solar cell power production. Perovskite solar cells have shown a specific power of 23 W/g, much higher than traditional silicon or gallium arsenide solar cells. Further research is needed to address the challenges related to perovskite solar cells' stability and power conversion efficiency. Perovskite solar cells integrated with energy storage units have the potential to enhance the overall efficiency of the system. This study discusses an approach to improve the efficiency of novel solar cells, specifically focusing on lead-free tin-based perovskite solar cells and tandem solar cells. The advancement of technology in thin films, such as hybrid nanocomposite thin films and quantum dot-sensitive solar cells, has the potential to improve the efficiency of solar cells. The primary outcome of this study is derived from the following inference: incorporating plasmatic nanostructures into thermal energy systems will enhance their efficiency and sustainability by integrating solar energy.