Explores low-dimensional devices, focusing on nanowires and quantum dots, their properties, applications, and the challenges in their fabrication and performance.
Explores the properties of crystalline silicon absorbers in solar cells, discussing absorption coefficients, dispersion effects, and absorption mechanisms in semiconductors.
Discusses the principles of pn junctions and heterostructures in semiconductor physics, focusing on their electrical characteristics and practical applications.
Covers the basics of energy states in matter, thermal transport, and solar systems, emphasizing the importance of electrochemistry in solar energy applications.
Explores compound semiconductor nanostructures, focusing on energy de-fossilization, nanowire applications in solar cells, and photonics principles for solar cell efficiency.
Explores standard cell processing techniques for silicon solar cells, including PERC, PERL, and PERT structures, focusing on efficiency and manufacturing challenges.
Explores the fundamentals and efficiency of photovoltaics, covering topics such as the photovoltaic effect, bandgap optimization, and efficiency limits.
Explores the potential of solar energy, efficiency of solar cell technologies, differences between inorganic and organic materials, and advancements in organic solar cell fabrication.
