Molecular self-assembly is a promising area of research in nanotechnology that has the potential to revolutionize the field of materials science. Molecular self-assembly is a process in which molecules autonomously arrange themselves into ordered structures without any external guidance or input. This process is driven by the interactions between the molecules, which can be either attractive or repulsive. By understanding and controlling this process, scientists can design and synthesize materials with novel properties not found in nature. Molecular self-assembly has many potential applications. For example, it can be used to create nanostructures with specific shapes and sizes, which can be used in a variety of applications such as drug delivery, nanoelectronics, photonics, and sensors. Additionally, self-assembled structures can be used as building blocks for larger structures, such as nanorobots or nanomachines. Furthermore, self-assembly can be used to create complex materials with a wide range of properties, such as superhydrophobicity, optical transparency, and thermal conductivity. Molecular self-assembly is a powerful tool for manipulating matter at the nanoscale, and it has the potential to revolutionize the fields of materials science and nanotechnology. Scientists are actively researching the mechanisms behind self-assembly, as well as its applications in a variety of areas such as medicine, electronics, and energy. By furthering our understanding of this fascinating process, we can unlock the potential of molecular self-assembly to create new materials with unprecedented properties.





Title : Creating materials with a desired refraction coefficient and other applications
Alexander G Ramm, Kansas State University, United States
Title : Pristine graphene coatings on metals: A disruptive approach to remarkable and durable corrosion
Raman Singh, Monash University, Australia