Biochemical engineering is a combination of Chemical Engineering and Biological Engineering that manages the outline and development of unit operations that include natural life forms or molecules, for example, bioreactors. This will help in recognising the organic or biochemical phenomena of these frameworks. Biochemical Engineering additionally manages the kinetics of growth, demise and digestion, maturation, agitation, mass exchange and enzyme technology. Biochemical has many scopes in the field of petrochemical, food, pharmacy, biotechnology, and water treatment ventures.
Nanotechnology is the engineering of practical systems at the subatomic scale. This spreads both current work and ideas that are further developed. In its unique sense, nanotechnology suggests the expected ability to fabricate things from the base up, utilizing methods and instruments being created today to make finish, elite items. Nanomaterials research adopts a materials science-based strategy to nanotechnology, impacting propels in materials metrology and union which have been created on the side of microfabrication explore.
Thermodynamics is a division of material science comprising with heat and temperature with their connection to energy and work. Thermodynamic balance is one of the imperative ideas of thermodynamics. Thermodynamics is an extensive type of subject in science and engineering, predominantly physical chemistry, chemical engineering and mechanical engineering. A thermodynamic operation is more often about thermodynamic process of exchange of mass or energy that alters the condition of the system, and this transfer is based on the laws of thermodynamics.
Nanotechnology has applications in clinical medicine and diagnostics. As an example, nanotechnology-based diagnostic devices can be used to accurately test blood for disease markers. Nanorobotics is a developing field wherein machines are engineered from Nanoscale components. In the field of Nanomedicine, Nanorobots have been used to carry out some interesting operations. Harvard and MIT scientists attached RNA strands to nanoparticles loaded with a chemotherapy drug, creating a Nanomachine that could target and kill cancer cells. In another example, Nanorobots were used to work with white blood cells to repair tissue.
Polymers will be the material of the new millennium and the production of polymeric parts i.e. green, energy-efficient, high quality, low-priced and high sustainability, etc. will assure the accessibility of the finest solutions round the globe. Synthetic polymers have since a long time played a relatively important role in present-day medicinal practice. Polymers are now a major materials used in many industrial applications. The prediction of their behavior depends on our understanding of these complex systems. Polymerization and polymer processing techniques thus requires molecular modeling techniques.