Track Categories

The track category is the heading under which your abstract will be reviewed and later published in the conference printed matters if accepted. During the submission process, you will be asked to select one track category for your abstract.

Nano Photonics is seen as a crucial technology which is expected to play a complementary role to micro/Nano electronics on chip and extend the capacity of telecommunication networks. Latest research is going on Nano photonics are Stability Formulation for Integrated Opto-mechanic Phase Shifters. Broadband achromatic metalens. From Two-Photon to Three-Photon Absorption. Detection of chemical and biological warfare agents. Fundamental and applied research into flexible electronics. Experimentation in electron beam lithography.

  • Track 1-1 Optoelectronics and Microelectronics
  • Track 1-2 Spectroscopy and Microscopy
  • Track 1-3 Metamaterials
  • Track 1-4 Photonic & plasmonic nanomaterials
  • Track 1-5 Optical properties of nanostructures
  • Track 1-6 Optics and transport on 2D materials
  • Track 1-7 Nano-Opto mechanics
  • Track 1-8 Quantum Nano-optics
  • Track 1-9 Nano scale photo thermal effects
  • Track 1-10 Quantum electronics
Ceramics and glass Materials are inorganic, non-metallic materials consisting of metallic and non-metallic elements. The high strength bonds in Ceramic & Glass Material gives rise to some of its special characteristics. They occupy a unique place in the field of engineered materials offering many desirable alternatives to the metals and polymers in common usage.
 
  • Track 2-1 Ceramic engineering
  • Track 2-2 Bio ceramic Materials
  • Track 2-3 Ceramic & Metal Material
  • Track 2-4 Ceramics Manufacturers and Market Analysis
  • Track 2-5 Applications in Medical Technology
  • Track 2-6Synthesis & Characterization of Nano structured ceramics
  • Track 2-7 Future Advances in Ceramics
The Nano gadgets and Nanostructures have introduced a super exchange of the human race with its Nano way of life gadgets.. Nano scale materials are a broadly defined set of substances that have at least one critical dimension less than 100 nanometers and possess unique optical, magnetic, or electrical properties. Ultrafine particulate matter is a well-known example of nanoscale particles found in the environment
 
  • Track 3-1 Nano Medical Devices
  • Track 3-2 Nano Wires
  • Track 3-3 Magnetic Nano Particles
  • Track 3-4 Nano surface engineering
  • Track 3-5 System integration, NEMS
  • Track 3-6 Modelling and simulation of Nano materials & Nano devices
  • Track 3-7 Nano scale process engineering
  • Track 3-8 Nano device fabrication
  • Track 3-9 Nano manufacturing techniques

Biosensors converts the biological response into an electrical signals thereby the measurement is possible. The bio receptor may be a living organism or biological molecules, especially enzymes or antibodies. Measurement of target analyze without using any reagent is an added advantage of biosensor. New Sensor with a Breathalyzer. Optomechanical Nano sensor .hypoallergenic Electronic Sensor .optical Nano sensor Enhances Accuracy of Brain Mapping

  • Track 4-1 Optical Nano sensors
  • Track 4-2 Biosensor and Bio printing
  • Track 4-3 Bio markers
  • Track 4-4 Nano biosensors
  • Track 4-5 Magnetic Sensors
  • Track 4-6 Muscular Biopolymers
  • Track 4-7 Latest Research & Applications of Nano sensing
  • Track 4-8 Nano sensors Applications in Agriculture & Food Industry
  • Track 4-9 Nano sensors for Chemical and Biological Applications
  • Track 4-10 Nano sensors in Aquaculture

Nano Robotics is a field under continuous development. It involves the construction of robots of the size of 10^-9m. In the last decade many Nano robots have made their way out of the drawing boards to enter into the human body and do things beyond. These robots play a key role in the field of biomedicine particularly used for the removal of kidney stone, treatment of cancer & elimination of defected part in the DNA structure etc. Special networks of stationery Nano robots will be positioned throughout the body which will keep the track of each active Nano robot passes & then report the results. Nanorobotics is also being developed for therapeutic manipulations.

  • Track 5-1 Swarm Robotics
  • Track 5-2 Biochip
  • Track 5-3 NU bots
  • Track 5-4 Robotic vision, localization and navigation
  • Track 5-5 Robotic Cholecystectomy
  • Track 5-6 Robotic Laparoscopy
  • Track 5-7Nano robots in Cancer Detection and Treatment
  • Track 5-8 Nanorobotics in Gene Therapy
  • Track 5-9 Market Approaches

Nano biotechnology is the application of nanotechnology in biotechnology. Applications in molecular diagnostics and pharmaceuticals, which include drug discovery, drug development, and drug delivery, are described. Nano biotechnology has refined the current molecular diagnostics by extending the limits of detection to single molecules. Nanoparticles play an important role in the delivery of biological therapies, which include cell therapy, gene therapy, vaccines, RNA interference, and antisense therapeutics. The most promising application of Nano biotechnology relevant to healthcare is for the development of personalized medicine. The refinement of molecular diagnostics, combination of diagnostics with therapeutics, and targeted drug delivery play important roles in this application. Finally, the safety issues of nanoparticles are discussed including measures to address these. The future prospects of Nano biotechnology are excellent the purpose of this sub track is to show, by selected examples, how biological approaches can contribute to Nano science.

  • Track 6-1 Bio nanotechnology
  • Track 6-2 Diagnostic applications
  • Track 6-3 Therapeutic applications
  • Track 6-4 Cellular Engineering
  • Track 6-5Sparse cell detection
  • Track 6-6 Tissue assisted cell engineering
  • Track 6-7 Lipid Nano technology
  • Track 6-8 Nano viridae
  • Track 6-9 Applications of Nano biotechnology in Plant Virus Diseases
  • Track 6-10 Nanotechnology and Its Applications in Animal Biotechnology
Due to the lack of novel drugs for the diseases, Nano pharmaceutical has appeared as an important new breakthrough for the treatment of neglected diseases like filiarasis, leishmaniasis, leprosy, malaria, onchocerciasis, schistosomiasis, trypanosomiasis, and tuberculosis. New developments in Nano carriers have made promising advances in the treatment of several kinds of diseases with less toxicity, high efficacy and improved bioavailability of drugs with extended release and fewer applications. This deals with the current status of medicines in the treatment of neglected diseases and highlights how it provides key tools for exploring new perspectives in the treatment of a wide range of diseases.
 
  • Track 7-1 Nano Pharmaceutical for drug delivery and therapy
  • Track 7-2 Treatment of neurodegenerative disorders
  • Track 7-3 Nano Pharmaceutical in biological therapy
  • Track 7-4 Nanotechnology tools for drug development
  • Track 7-5 Nanotechnology tools for personalized medicine
  • Track 7-6 Solid lipid nanoparticles
  • Track 7-7 Nanoparticles of biodegradable polymers
  • Track 7-8 Nanozymes
  • Track 7-9 Cancer Treatment
  • Track 7-10 Nano emulsions
  • Track 7-11 Nano Chemistry
  • Track 7-12 Nano Toxicity in phamaceutical
Green nanotechnology integrates the principles of green chemistry and green engineering to produce eco-friendly, safe, nanostructures that do not use toxic chemicals in the synthesis protocol. The parallel development of nanotechnology with green chemistry and potential synergism between the two fields can lead to sustainable methods with reduced environmental impacts, protection of resources and human health. With recent developments in nanostructures, concerns of uncertainty and risk regarding environment, health, and safety (EHS) cannot be ignored. Thus the concept of “green nanotechnology” comes to rescue. The main goal of green nanotechnology is to produce nanostructures without affecting the environment or human health. This can be a viable substitute to the conventional physical and chemical methods of synthesizing nanostructures.
 
  • Track 8-1 Water filtration by Nano technology
  • Track 8-2 Grapheme Nano technology in Solar cells
  • Track 8-3 Greener Techniques to make Nanomaterials
  • Track 8-4 Toxicology and analysis
  • Track 8-5 Social and economic aspects
  • Track 8-6 Environment Applications
  • Track 8-7 Green Nanotechnology Challenges And Opportunities
  • Track 8-8 Barriers to Green Chemistry Innovation
  • Track 8-9 Polymer Science
The first and foremost requirement for the choice of the biomaterial is its adequacy by the human body. A biomaterial used for implant should possess some important properties in order to long term usage in the body without reputation. The thermal stabilities of the polymer chemistry were studied by means of thermogravimetric analysis. The activation energies of the degradation of the polymer chemistry were calculated using the Arrhenius equation. The rates of polymerization of polymers in the absence and in the presence of transition metal were studied.
 
  • Track 9-1 Biomaterials for Tissue Engineering
  • Track 9-2 Thermodynamics of materials
  • Track 9-3 Materials for bone repair and regeneration
  • Track 9-4 Biomaterial Scaffolds
  • Track 9-5 Biomaterials for drug delivery systems
  • Track 9-6 Nanomaterials for Future Applications in Analytical Chemistry
Owing to their unique combination of physical and chemical properties such as high electrical conductivity, high surface area, high thermochemical stability, and adequate corrosion resistance, as well as particular mechanical properties, these materials have been the subject of several scientific studies. Unfortunately, the devoted effort to explore the fundamental physics, chemistry graphene, and carbon nanotubes is not enough to properly modulate in detail all the exceptional properties (including electrical, thermal, mechanical, optical, and long electron mean free paths). 
 
  • Track 10-1 Characteristics of carbon-based nanomaterials
  • Track 10-2 Carbon Nanomaterials for Electronics and Optoelectronics
  • Track 10-3 Carbon nanotubes for electronic and optoelectronic applications
  • Track 10-4 Graphene for electronics and optoelectronics
  • Track 10-5 Carbon Nanomaterials for Photovoltaic Applications
  • Track 10-6 Carbon Nanomaterials for Sensing Applications
  • Track 10-7 Carbon nanotubes in Biomedical Engineering
  • Track 10-8 Environmental Applications of Carbon-Based Nanomaterials
  • Track 10-9 Recent Developments
Nanomedicine, the application of Nano biotechnology in medicine, is a broad term applied to all healthcare applications of Nano biotechnology. Clinical nanomedicine is used in practically all medical specialties and three areas – cancer, neurological disorders, and cardiovascular diseases – are described.
 
  • Track 11-1 Improved Diagnosis, Prevention and Treatment for Disease
  • Track 11-2 Toxicity Issues
  • Track 11-3 Nanoparticles: Health Effects
  • Track 11-4 Current Status of Nanomedicine Research
  • Track 11-5 The future of Nanomedicine

Smart materials are defined as materials with properties engineered to change in a controlled manner under the influence of external stimuli. Some of the external stimuli are temperature, force, moisture, electric charge, magnetic fields and ph. The self-assembly of peptides has enormous applications in the fields of medicine and electronics. Bio-inspired engineered systems have been designed based on the mechanistic perceptions obtained from natural systems for novel self-assembled structures.  In the biological system, each cell type is programmed to display different levels of smartness.

  • Track 12-1 Wet nanotechnology
  • Track 12-2 Green nanotechnology
  • Track 12-3 Nano architectonics
  • Track 12-4 Nano biotechnology
  • Track 12-5 Health impact of nanotechnology
  • Track 12-6 Environmental impact of nanotechnology
  • Track 12-7 Regulation of nanotechnology
  • Track 12-8 Foundations in Nano Engineering
  • Track 12-9 Characterization of Nano Engineering Systems
  • Track 12-10 Computational Modeling of Nano systems
  • Track 12-11 Applications of nanotechnology & Nano engineering
Certain features of nanotechnology have been found that are likely to be important in determining its impact in the future. More importantly, responding to the challenge of nanotechnology will require confronting “philosophical” questions about the sort of society we wish to create and the role that technology might play in creating it.
 
  • Track 13-1 Tackling climate change
  • Track 13-2 Cancer Research
  • Track 13-3 Genetic Therapy and Medicine
  • Track 13-4 Nanoparticle-Filled Ink Conducts Electricity
  • Track 13-5 Gene Therapy and Drug Delivery
  • Track 13-6 Protective Coating for your Skin
  • Track 13-7 Nanomaterials In The Food Supply
  • Track 13-8 Nanotechnology in the Oil Industry
  • Track 13-9 Challenges and risks of nanotechnology