Nano Cars Into The Robotics , Seminar Reports | PPT | PDF | DOC | Presentation |








                        Material Science research is now entering a new phase where the structure and properties of materials can be investigated, characterized and controlled at the nanoscale. New and sometimes unexpected material properties appear at the nanoscale, thus bringing new excitement to this research field. In this talk, special emphasis will be given to one-dimensional nanotubes and nanowires because they exhibit unusual physical properties, due to their reduced dimensionality and their enhanced surface/volume ratio. These unusual properties have attracted interest in their potential for applications in novel electronic, optical, magnetic and thermoelectric devices. Another feature of nanotechnology is that it is the one area of research and development that is truly multidisciplinary. Research at the nanoscale is unified by the need to share knowledge on tools and techniques, as well as information on the physics affecting atomic and molecular interactions in this new realm.


So now we are going to introduce the nano technology into the field of robotics to achieve realistic movements which is a real dream of the human for more than 5 years. By introducing this nervous system to the robot we have exactly 2 advantages that is we can pass information same time and we can also the movements at the same time the cars reached the actual part where the movement as be caused. So we need have some knowledge about nano technology and from these we are going to see what the nano cars means and then how we are going to see the introduction of the nano cars into the neuron system. From converting sunlight into power to clean oceans, to monitor thermal environment, and to sensors in the form of biochips built into the human body performing as lifesavers by self-monitoring and guarding, nanotechnology assures us a lot more.


        Stone Age, Bronze Age, Iron Age, Silicon Age, and next what? Nevertheless to say, we are well in to the Nanotech Age, where materials are just getting smarter day by day. There would be sensors embedded in almost all walks of life. Each element would be smart enough to repair itself as and when required. All this would be possible by manipulating matter at the molecular scale.


        Scientists will now like to understand how simple atoms and molecules come together and arrange themselves to form complex systems, such as living cells that make life possible on earth. This approach deals with how complex systems are built from simple atomic-level constituents which result in nanoscience and nanotechnology. In simple, it is the study of properties of a few tens of atoms in a space of less say 50nm. Manufactured products are made from atoms. The properties of those products depend on how those atoms are arranged. If we rearrange the atoms in coal we can make diamond. If we rearrange the atoms in sand we can make computer chips. If we rearrange the atoms in dirt, water and air we can make potatoes. Almost any manufactured product could be improved, often by several orders of magnitude, if we could precisely control its structure at the molecular level. We often want our products to be light and strong.





Nanoscience is emerging as the basic science providing a field which is becoming the focus of attraction of all fundamentals sciences. Physics provides possibility of maneuvering things atom by atom. Chemistry provides way of synthesizing complicated molecules provided clues for building materials on molecular level. Bioscience provides possibility of understanding how nature builds the material as proteins are molecular machines, which routinely manipulate individual atoms. To decipher it one needs mathematics and computer science for modeling and computer simulations. The ultimate aim is to achieve self assembly of devices for various applications. Of course, nanotechnology is a wonderful tool, but what would happen if this technology fell into the wrong hands? One might ask about the legal implications of nanotechnology or even the harmful effects of bioterrorism. The truth is that we simply don’t know where new technologies would lead, and we can never secure against scientific terror. Today’s advances offer tremendous possibilities as also tremendous risks-and we’re just going to learn to live with both.


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