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.

Nanomedicine is a field of medical science whose applications are increasing more and more thanks to nanorobots and biological machines, which constitute a very useful tool to develop this area of knowledge. In the past years, researchers have done many improvements in the different devices and systems required to develop nanorobots. This supposes a new way of treating and dealing with diseases such as cancer; thanks to nanorobots, side effects of chemotherapy have been controlled, reduced and even eliminated, so some years from now, cancer patients will be offered an alternative to treat this disease instead of chemotherapy, which causes secondary effects such as hair loss, fatigue or nausea killing not only cancerous cells but also the healthy ones.

  • Track 1-1Toxicology
  • Track 1-2Pharmaceuticals
  • Track 1-3Nano surgery
  • Track 1-4Nano biosensor
  • Track 1-5Nanodrug delivery method
  • Track 1-6Nanomedical devices

Nanoelectronics are based on the application of nanotechnology in the field of electronics and electronic components. Although the term Nanoelectronics may generally mean all the electronic components, special attention is given in the case of transistors. These transistors have a size lesser than 100 nanometers. Visibly, they are very small that separate studies must be made for knowing the quantum mechanical properties and inter-atomic design. As a result, though the transistors appear in the nanometer range, they are designed through nanotechnology. Their design is also very much different from the traditional transistors and usually falls in the category of one dimensional nanotubes/nanowires, hybrid molecular electronics, or advanced molecular electronics. This technology is said to be the next future, but its practicality is near to impossible even now that they may be difficult to emerge soon.

  • Track 2-1Nano microscopy
  • Track 2-2Nano micro machinery
  • Track 2-3Carbon nanotube actuators
  • Track 2-4Nanomotor
  • Track 2-5Nano transistors and Nanowires

The time for a major paradigm shift from nanotechnology to Nano architectonics has come. Scientists in nanoscience and nanotechnology have been creating fine nanomaterials and Nano systems using advanced physical techniques and apparatus, mainly as separate processes. These involve the fabrication of small objects and the observation of their behaviors. However, we are now must construct fine systems from these nanocomponents like the way that carpenters architect house and buildings. Technological efforts at the nanoscale must be organized and converted into the new concept of Nano architectonics

  • Track 3-1Nano architectonics of smart of drug delivery and drug targeting
  • Track 3-2Biomaterials and Nano architectonics
  • Track 3-3Building of nanostructural units
  • Track 3-4Novel techniques used in Nano architectonics

Nanotechnology is all about designing, fabricating and controlling materials and components with dimensions on the nanoscale, i.e. from 1 to 100 nm. During the Master's programme in Nanomaterials and Nanophysics you will learn how nanotechnology can be used in order to develop new optic and electronic components and new materials for use in communications technology, sensor technology or catalysis.

  • Track 4-1Nanoionics
  • Track 4-2Nanolithography
  • Track 4-3Nanofludics
  • Track 4-4Nanostructure

The Nano mechanics investigates mechanical properties of engineered and biological materials at the Nano to macro-scale using experimental, analytical, and computational techniques. MEMS/NEMS (Microelectromechanical system/ Nanoelectromechanical system) devices are sensitive to a wide range of stimuli such as temperature, mass, pressure and are thus extensively used as sensors in cars and mobile phones. The biggest promise of MEMS and NEMS technology is the development of extremely small sensor systems that can be used virtually everywhere and thus can impart intelligence to almost all man-made things.

  • Track 5-1MEMS/NEMS
  • Track 5-2Mechanical Nanometrology
  • Track 5-3Properties of Nanostructures
  • Track 5-4Nanoelectromechanical relay

A nanorobotics is a machine that can build and manipulate things precisely at an atomic level. Imaging a robot that can pluck, pick and place atoms like a kid plays with LEGO bricks, able to build anything from basic atomic building blocks. While some people dismiss the future of nanorobots as science fiction, you should realize that each of us is alive today because of countless nanobots operating within each of our trillions of cells. We give them biological names like a “ribosome,” but they are essentially machines programmed with a function like “read messenger RNA to create a specific protein.”

  • Track 6-1Robotic logging technology
  • Track 6-2Nanobiochips
  • Track 6-3Nano 3D printing
  • Track 6-4Nanometer

Nano chemistry, described the field as "an emerging subdiscipline of solid-state chemistry that emphasizes the synthesis rather than the engineering aspects of preparing little pieces of matter with nanometer sizes in one, two or three dimensions. … The Nano chemist can be considered to work towards this goal from the atom 'up', whereas the nanophysics tends to operate from the bulk 'down'." Today, Nano chemists work in biomedical chemistry, polymer chemistry, product synthesis, and a host of other areas. They use a wide variety of methods to prepare and assemble "little pieces of matter" with novel electronic, magnetic, optical, chemical, and mechanical behaviors that can be attributed to their nanometer-scale size.

 

  • Track 7-1Nonahedron
  • Track 7-2Nanophotonic
  • Track 7-3Immunohistochemistry
  • Track 7-4Chemical vapor deposition
  • Track 7-5Nanocrystal
  • Track 7-6Nano emulsion

Nanotechnologies make use of very small objects or artifacts. Nanomaterials are an increasingly important product of nanotechnologies. They contain nanoparticles, smaller than 100 nanometers in at least one dimension. Nanomaterials are coming into use in healthcare, electronics, cosmetics and other areas. Their physical and chemical properties often they differ from those of bulk materials, so they call for specialized risk assessment. This needs to cover health risks to workers and consumers, and potential risks to the environment.

 

  • Track 8-1Nano biomaterials
  • Track 8-2Nanofabrication
  • Track 8-3Nanoparticles and biocompatibility
  • Track 8-4Toxicity of nanomaterials
  • Track 8-5Nanoprobe

Cell biology today is on the verge of a nanotechnology-driven research era, one in which the availability of sophisticated new experimental techniques and tools of nanotechnology is set not only to emulate more complex, in vivo like extracellular environments, but also monitor dynamic complex biological processes in real time at the single cell level. Ultimately, the goal is to establish a fully integrated knowledge of how the building blocks of humans – cells – work at the molecular level. It is only by a detailed knowledge of how cells work, independently and together, in healthy and diseased states that one will be able to understand and anticipate the onset and effects of disease and create an appropriate and effective means to prevent and treat disease. The unravelling of cellular and molecular mechanisms that could be used to reprogram or instruct cells would enable unprecedented advances in tissue engineering and regenerative medicine.

  • Track 9-1Nanoparticle Sensors
  • Track 9-2Cellular transplants
  • Track 9-3Regenerative processes
  • Track 9-4Nanoscale quantitative measurement
  • Track 9-5Single-cell Nano surgery
  • Track 9-6Nanotechnology for probing, Imaging
  • Track 9-7Nanotechnology Applications

Nanotechnology supporters believe that it has the potential to transform our lives dramatically, while opponents of nanotechnology fear that self-replicating "nanobots" could escape from laboratories and reduce all life on earth. Some ethical discussions have been focused on the field of molecular nanotechnology. The lack of meritorious ethics research proposals may be related to the difficulty in identifying or anticipating ethical issues that are unique to nanobiotechnology, particularly its near-term applications.

  • Track 10-1Nanotechnology safety and health practices
  • Track 10-2Health risk of nanomaterials
  • Track 10-3Nanotoxicology and its preventive measures
  • Track 10-4Nanoparticles as a barrier
  • Track 10-5Healing and preserving the environment
  • Track 10-6Improving health and longevity

Advanced Nanotechnology was founded by industry visionaries to revolutionize systems and delivers a quantum improvement in performance, dramatically reduce power consumption and deliver extreme security. They use patented hardware and proprietary state-of-the-art algorithms to dramatically increases defense against hacking. We leverage the power of 3D & nanotechnology to break the semiconductor interconnect bottleneck – and eliminate the gridlock that limits performance and waste power. 

  • Track 11-1Nanofood technology
  • Track 11-2Case study in nanotechnology and nanobiotechnology
  • Track 11-3Recent techniques used in nanotechnology
  • Track 11-4Methods that contribute to society
  • Track 11-5Nanotechnology in herbal drugs