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24th World Nano Conference , will be organized around the theme “Invention and Innovation of New Concepts in the Field of Nanotechnology”

Nano 2018 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Nano 2018

Submit your abstract to any of the mentioned tracks.

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Nano Science is a technology conducted at the Nano scale. It is the applications and study related to extremely small things that can be used around all the other fields of science, like chemistry, biology, physics, engineering and Materials sciences. These particles have the ability to control individual atoms and molecules. Nanotechnology has a huge potential to provide technological solutions to many problems in science, energy, physics, environment al and medical fields.

  • Track 1-1Nanostructured Metals: Manufacturing and Modelling
  • Track 1-2Exposure Scenarios
  • Track 1-3Nano Magnetics
  • Track 1-4Nanospinitronics
  • Track 1-5Biogenic Nanoparticles
  • Track 1-6Nonlinear Optical Microscopy
  • Track 1-7Quantum Field Model for Graphene Magnetism

Nano Medicine the application of technology to do everything from drug delivery to repairing of cells. It is the application of tiny machines to the treatment and prevention of disease. Nano robots are advancements in Nano medicine as miniature surgeons. These machines help repair damaged cells they replicate themselves, correct genetic deficiencies by replacing or altering DNA molecules. For example artificial antibodies, antiviral, Nano robots, artificial white and red Blood cells. These Nano machines could affect the behaviour of individual cells. Hormones or Dispense drugs as needed in people with deficiency states or chronic imbalance can be solved using implanted Nanotechnology devices.

  • Track 2-1Drug Delivery
  • Track 2-2Biocompatibility
  • Track 2-3Sensing
  • Track 2-4Nanomedicine in Theranostics
  • Track 2-5Nano Imaging
  • Track 2-6Medical Devices
  • Track 2-7Blood Purification
  • Track 2-8Cancer Treatment
  • Track 2-9Personalized Nanomedicine
  • Track 2-10Regenerative Medicine
  • Track 2-11Dentifrobots

Nano electronics holds few answers for how we might increase the capabilities of electronics devices when we reduce their weight and power consumption. Nano electronics and technology are widely used in all aspects of modern life. Life Safety, Healthcare, Transportation, Computing, Energy and Telecommunications are some of the major fields benefiting from the growth of Nano electronic applications.

  • Track 3-1Nanofabrication
  • Track 3-2Nanomaterials Electronics
  • Track 3-3Molecular Electronics
  • Track 3-4Nanoionics
  • Track 3-5Nanoelectronic Devices
  • Track 3-6Flexible Electronic circuits
  • Track 3-7Magnetoresistive Random Access Memory (MRAM)
  • Track 3-8Magnetoelectric Random Access Memory (MeRAM)

The association of nanoparticles in a thin film shape is regularly important to render these utilitarian and operational. Two critical synthetic strategies. One is high-temperature warm disintegration and second is fluid interface response, reasonable for planning movies of numerous metal and metal oxide nanoparticles. Moreover, the use of a high-vitality ball processing and start plasma sintering process for the arrangement and preparing of nano composite powders into mass magnets are additionally highlighted.

  • Track 4-1Size Dependence of Properties
  • Track 4-2Shape-Controlled Synthesis
  • Track 4-3Characterization and Optical Properties of Silver Nanostructures
  • Track 4-4Nanostructured Materials
  • Track 4-5Microscopy and Spectroscopic Methods of Measurement at the Nanoscale
  • Track 4-6Nano Particles
  • Track 4-7Materiomics
  • Track 4-8Nanomaterials Manufacturing Technologies
  • Track 4-9Applications of Nano materials and Devices

Nanotechnology is the science which deals with the processes that occur at molecular level and of nanolength scale size. The major studies in the nanotechnology include nanosized particles, their function and behaviour with respect to other systems. The tremendous capabilities of nanoparticles have changed the perspective and scope of nanotechnology towards development into an adjuvant field for the remaining fields of life sciences. Nanotechnology is the ability to understand and control materials at the very smallest scales, from around 100 nm to the dimensions of single atoms; At this Nano scale the properties of these nanosized particles are vary from the conventional medicines

  • Track 5-1Nanoliposome
  • Track 5-2NanoPharmaceuticals from the bench to Scale up
  • Track 5-3Challenges and advances in Nano Pharmaceuticals
  • Track 5-4Nano Pharmaceutical Industry and Market
  • Track 5-5Novel Drug Delivery Systems
  • Track 5-6Smart Drug Delivery Technology
  • Track 5-7Drug Delivery Research
  • Track 5-8Pharmacytes
  • Track 5-9Drug Targeting
  • Track 5-10Synthesis of Nanoparticles for Drug Delivery
  • Track 5-11Design of Nanodrugs
  • Track 5-12Future aspects of Nano Pharmaceuticals

The interdisciplinary field of materials science, also commonly termed materials science and engineering, involves the discovery and design of new materials, with an emphasis on solids. The intellectual origins of materials science stem from the Enlightenment, when researchers began to use analytical thinking from chemistry, physics, and engineering to understand ancient, phenomenological observations in metallurgy and mineralogy.  Materials science still incorporates elements of physics, chemistry, and engineering. As such, the field was long considered by academic institutions as a sub-field of these related fields. Beginning in the 1940s, materials science began to be more widely recognized as a specific and distinct field of science and engineering, and major technical universities around the world created dedicated schools of the study. Materials science is a syncretic discipline hybridizing metallurgy, ceramics, solid-state physics, and chemistry. It is the first example of a new academic discipline emerging by fusion rather than fission.

  • Track 6-1Computational Materials Science
  • Track 6-2Engineering applications of materials
  • Track 6-3Forensic engineering
  • Track 6-4Tribology
  • Track 6-5Emerging materials and applications
  • Track 6-6Platform for comprehensive projects
  • Track 6-7Research support
  • Track 6-8Global materials science market
  • Track 6-9Teaching and technology transfer in materials science
  • Track 6-10Products and Services
  • Track 6-11Engineering applications of materials

Nanotechnology refers to a broad range of tools, techniques and applications that simply involve particles on the approximate size scale of a few to hundreds of nanometers in diameter. Particles of this size have some unique physicochemical and surface properties that lend themselves to novel uses. Indeed, advocates of nanotechnology suggest that this area of research could contribute to solutions for some of the major problems we face on the global scale such as ensuring a supply of safe drinking water for a growing population, as well as addressing issues in medicine, energy, and agriculture.

  • Track 7-1Nanomaterials and water filtration
  • Track 7-2Nanotechnologies for water remediation
  • Track 7-3Bioactive nanoparticles for water disinfections
  • Track 7-4Self-assembled monolayer on mesoporous supports (SAMMS)
  • Track 7-5Nanoscale semiconductor photocatalysts
  • Track 7-6Bimetallic iron nanoparticles

Nanomaterials are characterized as materials with no less than one outside measurement in the size extent from around 1-100 nanometers. Nanoparticles are items with each of the three outside measurements at the nanoscale. Nanoparticles that are normally happening (e.g., volcanic powder, ash from woodland fires) or are the accidental side effects of ignition procedures (e.g., welding, diesel motors) are generally physically and synthetically heterogeneous and frequently termed ultrafine particles. Built nanoparticles are deliberately delivered and planned with particular properties identified with shape, size, surface properties and science. These properties are reflected in mist concentrates, colloids, or powders. Regularly, the conduct of nanomaterials might depend more on surface region than molecule arrangement itself. World interest for nanomaterials will rise more than more than two times to $5.5 billion in 2016. Nanotubes, nanoclays and quantum dabs will be the quickest developing sorts. The vitality stockpiling and era and development markets will offer the best development prospects. China, India and the US will lead picks up among countries.This study dissects the $2 billion world nanomaterial industry. It presents recorded interest information for the years 2001, 2006 and 2011, and gauges for 2016 and 2021 by material (e.g., metal oxides, chemicals and polymers, metals, nanotubes), market (e.g., social insurance, gadgets, vitality era and capacity, development), world area and for 15 nations.

  • Track 8-1Recent Studies of Spin Dynamics in Ferromagnetic Nanoparticles
  • Track 8-2Novel Magnetic-Carbon Biocomposites
  • Track 8-3Gold Nanoparticles and Biosensors
  • Track 8-4Industrially Relevant Nanoparticles
  • Track 8-5Novel Dielectric Nanoparticles (DNP) Doped Nano-Engineered Glass Based Optical Fiber for Fiber Laser
  • Track 8-6ZnO Nanostructures for Optoelectronic Applications
  • Track 8-7Thin Film and Nanostructured Multiferroic Materials
  • Track 8-8Hyperthermia
  • Track 8-9Emerging Multifunctional Nanomaterials for Solar Energy Extraction

Carbon nanotubes (CNTs) are allotropes of carbon with a cylindrical nanostructure. These cylindrical carbon molecules have unusual properties, which are valuable for nanotechnology, electronics, optics and other fields of materials science and technology. Owing to the material's exceptional strength and stiffness, nanotubes have been constructed with length-to-diameter ratio of up to 132,000,000:1, significantly larger than for any other material. In addition, owing to their extraordinary thermal conductivity, mechanical, and electrical properties, carbon nanotubes find applications as additives to various structural materials. For instance, nanotubes form a tiny portion of the material(s) in some (primarily carbon fibre) baseball bats, golf clubs, car parts or Damascus steel.

  • Track 9-1Types of carbon nanotubes and related structures
  • Track 9-2Carbon nanotechnology to Bio nanotechnology
  • Track 9-3C60 and carbon nanotube sensors
  • Track 9-4Biological activity of pristine fullerene C60
  • Track 9-5Functionalization and applications of carbon nanotubes
  • Track 9-6Functionalization and applications of [60] fullerene
  • Track 9-7Fabrication of fullerene nanostructures
  • Track 9-8Solid-state formation of carbon nanotubes
  • Track 9-9Synthesis, growth mechanism and processing of carbon nanotubes
  • Track 9-10Carbon nanotube chemistry
  • Track 9-11Properties of carbon nanotubes
  • Track 9-12Separation of metallic and semiconducting single-walled carbon nanotubes

Various geophysical and social weights are changing a move from fossil energizes to renewable and manageable vitality sources. To impact this progression, we should make the materials that will bolster developing vitality advancements.

  • Track 10-1Novel nanomaterials and devices
  • Track 10-2Green Nanotechnology
  • Track 10-3Environment, human health, and safety issues of nanotechnology
  • Track 10-4Nanotechnology for water treatment, decontamination, in-door air purification, air pollution, and so forth
  • Track 10-5Nanotechnology for hydrogen production and storage
  • Track 10-6Nanotechnology for electrochemical conversion and energy storage
  • Track 10-7Energy and environment relevant nanotechnology
  • Track 10-8Nanomaterials for environment protection or improvement
  • Track 10-9Nanostructures for phase-change materials
  • Track 10-10Nanomaterials for solar cells, fuel cells, batteries, and so forth
  • Track 10-11Nanomaterials for energy conversion
  • Track 10-12Nanomaterials for building and construction
  • Track 10-13Recent trends in Nanotechnology

Bionanotechnology is the term that refers to the juncture of nanotechnology and biology. This discipline aids to indicate the fusion of biological research with several fields of nanotechnology. Concepts that are improved through nanobiology are comprises with Nano scale, nanodevices , and nanoparticles phenomena that occurs within the discipline of nanotechnology.

  • Track 11-1Bioluminescent magnetic nanoparticles
  • Track 11-2Surface modified polystyrene nanoparticles
  • Track 11-3Nano systems
  • Track 11-4Target specific drug delivery
  • Track 11-5Disease diagnosis
  • Track 11-6Nano ink

Nanostructured Materials for Biomedical Applications serves as a unique source for the rapidly growing biomaterials community on topics at the interface of biomaterials and nanotechnology. The book covers an extensive range of topics related to the processing, characterization, modeling, and applications of nanostructured medical device materials and biological materials.

  • Track 12-1Classes of Nanostructured Biomaterials
  • Track 12-2Types of Nanostructured Biomaterials
  • Track 12-3Processing and Characterization of Nanostructured Biomaterials
  • Track 12-4Biomedical Applications and Translational Aspects of Nanomaterials
  • Track 12-5Hierarchical Organisation in Biological Systems
  • Track 12-6Commercialisation and Exploitation of Nanoscience and Nanotechnology

Nanotoxicology is the combinational study of the toxicity of nanomaterials.  Due to quantum size effects and large surface area to volume ratio, nanomaterials have distinct properties compared with their larger counterparts. Nanotoxicology is a branch of bionanoscience which includes the study and application of toxicity of nanomaterials. Nanomaterials, even when prepared of inert elements like gold, become highly active at nanometer dimensions. Nanotoxicological studies are planned to determine whether and to what level these properties may pose a risk to the environment and to human beings.  For example, Diesel nanoparticles have been studied to harm the cardiovascular system in a mouse model.

  • Track 13-1Toxicity of Nanomaterials
  • Track 13-2Complications with Nanotoxicity Studies
  • Track 13-3Tolerogenic Nanoparticles
  • Track 13-4Medical Toxicology
  • Track 13-5Occupational Toxicology
  • Track 13-6Immunotoxicity
  • Track 13-7Cytotoxicity
  • Track 13-8Ecotoxicology
  • Track 13-9Genotoxicity
  • Track 13-10Regulation and Risk Management

Nano photonics is where photonics merges with Nano science and nanotechnology, and where spatial confinement considerably modifies light propagation and light-matter interaction.

  • Track 14-1General Introduction
  • Track 14-2Review of Fundamentals of Lasers
  • Track 14-3Optical Devices
  • Track 14-4Description of Light as an Electromagnetic Wave
  • Track 14-5Quantum Aspect of Light
  • Track 14-6Definition of Photon
  • Track 14-7Active Materials Bulk, Quantum Well, Wire Dot and Quantum Dot
  • Track 14-8Fabrication of Photonic Devices, Quantum Dot Materials

Molecular Nanotechnology is a technological revolution which seeks nothing less than perfectibility. Molecular manufacturing technology can be clean and self-contained. Molecular Nano manufacturing will slowly transform our connection towards matter and molecules as clear as the computer changed our relationship to information and bits. It will help accurate, inexpensive control of the structure of matter.

  • Track 15-1Positional Assembly
  • Track 15-2Potential social impacts
  • Track 15-3Phased-array optics
  • Track 15-4Utility fog
  • Track 15-5Medical nanorobots
  • Track 15-6Replicating nanorobots
  • Track 15-7Smart materials and Nanosensors
  • Track 15-8Molecular Manufacturing
  • Track 15-9Molecular Electronics
  • Track 15-10Microelectromechanical Devices
  • Track 15-11Massive Parallelism
  • Track 15-12Technical issues and criticism

Nanotechnology is a powerful tool for combating cancer and is being put to use in other applications that may reduce pollution, energy consumption, greenhouse gas emissions, and help prevent diseases. NCI's Alliance for Nanotechnology in Cancer is working to ensure that nanotechnologies for cancer applications are developed responsibly.  As with any new technology, the safety of nanotechnology is continuously being tested. The small size, high reactivity, and unique tensile and magnetic properties of nanomaterials—the same properties that drive interest in their biomedical and industrial applications—have raised concerns about implications for the environment, health, and safety (EHS).

  • Track 16-1Risk Assessment and Management
  • Track 16-2Health Impact of Nanotechnology
  • Track 16-3Societal Impact of Nanotechnology
  • Track 16-4Environmental Impact of Nanotechnology
  • Track 16-5Regulation of Nanotechnology

Tissue engineering is the use of a grouping of cells, engineering and materials methods, and appropriate biochemical and physicochemical factors to increase or replace biological tissues. Tissue engineering includes the use of a scaffold for the creation of innovative viable tissue for a medical determination. While it was once characterized as a sub-field of biomaterials, having developed in scope and importance and it can be considered as a field in its own.

  • Track 17-1Tissue Engineering
  • Track 17-2Nanotechnology and Tissue Engineering
  • Track 17-3Applications of Nanotechnology In Stem Cell Research
  • Track 17-4Nano biotechnology: From Stem Cell, Tissue Engineering to Cancer Research
  • Track 17-5Regulation on Advanced Therapy Medicinal Products/ Tissue Engineering

Nanotechnology applications are being researched currently, tested and in some cases already applied across the entire scope of food technology, from agriculture to food processing, packaging and food supple.

  • Track 18-1Nanotechnology in Agriculture
  • Track 18-2Nanotechnology in Food Industry
  • Track 18-3Nanotechnology in Food Microbiology
  • Track 18-4Nanotechnology for Controlled Release
  • Track 18-5Nanotechnology Research - Agriculture and Food Industry
  • Track 18-6Nanotechnology and Risk Assessment
  • Track 18-7Regulatory Approaches to Nanotechnology in the Food Industry

Nanofluidics is the study of the behavior, manipulation, and control of fluids that are confined to structures of nanometer (typically 1–100 nm) characteristic dimensions (1 nm = 10−9 m). Fluids confined in these structures exhibit physical behaviors not observed in larger structures, such as those of micrometer dimensions and above, because the characteristic physical scaling lengths of the fluid, (e.g. Debye length, hydrodynamic radius) very closely coincide with the dimensions of the nanostructure itself.

  • Track 19-1Nanofluidic circuitry
  • Track 19-2Nanofluidic structures
  • Track 19-3Tuneable Microlens Array
  • Track 19-4Membrane Science
  • Track 19-5Microfluidic cell sorting and Analysis
  • Track 19-6Nanofluidic Devices for DNA Analysis

Development of Nanotechnology and creating of Nanomaterials opened new perspectives for a number of areas of industry. These materials explain enlarged strength, toughness, biocompatibility, and can ensure higher service properties, reliability and systems.

  • Track 20-1Multiscale Modelling for the Materials Improvement and Design
  • Track 20-2Nanostructured Multiphase Alloys
  • Track 20-3Quantum Mechanics for Modelling of Nanomaterials
  • Track 20-4Microstructure-based Models and Dislocation Analysis
  • Track 20-5Mechanics of Nanomaterials
  • Track 20-6Software for Modelling of Nanomaterials
  • Track 20-7Industrial Applications of Nanomaterials Modelling

Nanocomposite is a multiphase solid material where one of the phases has one, two or three dimensions of less than 100 nanometers (nm), or structures having nano-scale repeat distances between the different phases that make up the material. In the broadest sense this definition can include porous media, colloids, gels and copolymers, but is more usually taken to mean the solid combination of a bulk matrix and nano-dimensional phases differing in properties due to dissimilarities in structure and chemistry. The mechanical, electrical, thermal, optical, electrochemical, catalytic properties of the nanocomposite will differ markedly from that of the component materials. Size limits for these effects have been proposed, <5 nm for catalytic activity, <20 nm for making a hard magnetic material soft, <50 nm for refractive index changes, and <100 nm for achieving super paramagnetism, mechanical strengthening or restricting matrix dislocation movement.

  • Track 21-1Superparamagnetism
  • Track 21-2Composite Materials
  • Track 21-3Ceramic Matrix Nanocomposites
  • Track 21-4Metal Matrix Nanocomposites
  • Track 21-5Polymer Matrix Nanocomposites

Nanoengineering is the practice of engineering on the nanoscale. It derives its name from the nanometre, a unit of measurement equalling one billionth of a meter. Nanoengineering is largely a synonym for nanotechnology, but emphasizes the engineering rather than the pure science aspects of the field.

  • Track 22-1Branches of nanotechnology
  • Track 22-2Risks of nanotechnology
  • Track 22-3Applications of nanotechnology
  • Track 22-4Devices
  • Track 22-5Notable organizations in nanotechnology
  • Track 22-6Notable figures in nanotechnology

Graphene is an atomic-scale honeycomb lattice made of carbon atoms. Graphene is undoubtedly emerging as one of the most promising nanomaterials because of its unique combination of superb properties, which opens a way for its exploitation in a wide spectrum of applications ranging from electronics to optics, sensors, and biodevices.

  • Track 23-1Graphene Synthesis
  • Track 23-2Chemistry and biology studies of graphene
  • Track 23-3Graphene modification and functionalization
  • Track 23-4Large scale graphene production and characterization
  • Track 23-5Applications of graphene in energy
  • Track 23-6Applications of graphene in biomedical
  • Track 23-7Graphene Companies and Market