Nanotechnology is currently a wide field of research and applications in fields ranging from biology to semiconductor fabrication. An example in biology is the design and fabrication of extremely small and sensitive chemical sensors. An example in semiconductors is the lithographic creation of IC chips.
Nanotechnology is better than biotechnology as nanotechnology can be applied to different career fields like electronics, medical, robotics, engineering and agriculture. So students from diverse fields can enter it. Biotechnology is limited to agriculture and pharmaceuticals. Salary, employment benefits and future growth prospects are very high as compared to Biotechnology.
nanotechnology is high demand in India or in usa.
Nanotechnology is a bunch of tiny robots.
Center for Responsible Nanotechnology was created in 2002.
i need some information of nanotechnology and how it is useful in the field of medicine. then what is stem cell nanotechnology and what is the application of stem cell nanotechnology.
Nanotechnology will not only expand our already impressive scientific field, but also help develop new ideas and devices.
yes nanotechnology does come under the mechanical engineering field but it also has other fields as the eligibility criteria.
To conduct research in nanotechnology, start by determining your research question or goal. Then, review existing literature, collaborate with experts in the field, and secure funding for your research. Experimentation, data collection, and analysis are essential steps in conducting nanotechnology research.
Some exaggerated ideas about nanotechnology include the belief that it can create self-replicating robots ("nanobots") that will destroy humanity, or that it will lead to instant cures for all diseases. In reality, the field of nanotechnology is still evolving and faces challenges in terms of scalability, reproducibility, and safety.
Some recent advancements in nanotechnology include the development of nano-sized drug delivery systems for targeted cancer therapy, advancements in nanomaterials for improved energy storage devices, and the use of nanosensors for detecting environmental pollutants. Researchers continue to explore new applications and ways to harness the unique properties of nanomaterials for various fields.
Nanotechnology has the potential to revolutionize cancer treatment by delivering targeted therapy directly to cancer cells, increasing treatment effectiveness while minimizing damage to healthy tissue. While nanotechnology is a promising field for cancer treatment, it is important to note that curing cancer involves a multifaceted approach that may also include surgery, radiation therapy, and other treatments depending on the type and stage of cancer.
The formulae used in the formation of nanotechnology are decades old, and were developed coolaboratively by the scientific community, especially those in the field of chemistry.
Nanotechnology began to emerge as a field of study in the 1980s with the development of the scanning tunneling microscope. This enabled researchers to manipulate individual atoms and molecules, leading to the exploration of nanoscale materials and phenomena.
Hydrophilic spheres are nanoparticles that attract water molecules. They have properties that make them useful in drug delivery, imaging, and environmental remediation in nanotechnology. Their ability to interact with water allows them to be easily dispersed in aqueous solutions, making them ideal for various applications in the field.
Some potential disadvantages of using nanotechnology in dentistry include concerns about nanoparticle toxicity, limited research on long-term effects, and the high cost of implementing nanotechnology-based treatments. Additionally, there may be regulatory challenges related to the use of nanomaterials in dental products.
Nanotechnology is utilized in semiconductors to improve performance and reduce size by manipulating materials at the nanoscale level. This technology enables the development of smaller, faster, and more energy-efficient semiconductor devices. Techniques such as quantum dots, nanowires, and nanopatterning are commonly used in semiconductor nanotechnology research and production.