Explores the application of carbon nanotubes in enhancing electron transfer for biosensors, emphasizing their role in improving sensitivity and detection limits.
Explores the properties and applications of carbon nanostructures, including graphene and carbon nanotubes, emphasizing their unique characteristics and diverse uses.
Covers the use of machine learning to predict the mechanical properties of carbon nanotubes and their composites through multiscale characterization techniques.
Explores the chemistry of silicon and carbon compounds, including conductivity differences, compound existence, carbon nanotubes history, and environmental impact of carbon dioxide.
Explores micro- and nanoelectromechanical systems, including practical applications, RF resonators, motion detection, and sensitive mass detection using carbon nanotubes.
Explores nanoparticle fabrication methods, challenges in carbon nanotube and nanowire production, and the comparison of bottom-up and top-down approaches.
Compares epoxy resin with thermoset and thermoplastic materials, focusing on its high strength, adhesion, and chemical resistance, and explores its diverse applications in various industries.
Explores the development of biological models with integrated monitoring, focusing on cell membranes, conducting polymer scaffolds, and bioelectronic devices.
Compares traditional amplitude-based sensor interfaces with a new time-based approach, showcasing the advantages of digital designs and potential for improved energy efficiency.
