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22nd International Conference and Expo on Nanoscience and Molecular Nanotechnology, will be organized around the theme “Taking Nanotechnology to New Heights through Innovation and Collaboration”

Nanoscience 2017 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Nanoscience 2017

Submit your abstract to any of the mentioned tracks.

Register now for the conference by choosing an appropriate package suitable to you.

 DNA molecules for nanotechnological applications

Nanomedicine can be defined as medical application of nanotechnology. Nanomedicine ranges from the medical applications of nanomaterials and biological devices, Nano electronic devices &biosensors and possible future applications of molecular nanotechnology. Nanomaterials can be functionalised to interface with biological molecules & structures as the size of nanomaterials is comparable to most biological molecules and structures. Nanomaterials can be useful for both in vivo and in vitro biomedical research and applications and integration of nanomaterials with biology has led to the development of advanced diagnostic devices, physical therapy applications, analytical tools, contrast agents and drug delivery vehicles. Nanomedicine strives for delivering valuable set of research tools & clinically useful devices and its industry sales reached $16 billion in 2015, with an average of $3.8 billion investment in nanotechnology R&D every year and increase of 45% per year global funding for emerging nanotechnology

  • Track 2-1Regenerative Medicine & Targeted Drug Delivery
  • Track 2-2Radio Nanomedicine
  • Track 2-3Nano dentistry
  • Track 2-4Nanobiosystems
  • Track 2-5Tissue Engineering
  • Track 2-6Nanoscale Tools and Techniques in Surgery
  • Track 2-7Nanodiagnostics
  • Track 2-8Enabling Personalised Medicine
  • Track 2-9Biology Inspired Nanomaterials
  • Track 2-10Bio-Sensors and Nano-Probes
  • Track 2-11Biocompatibility of Orthopaedic Implants
  • Track 2-12Nanoparticle‐based biologic mimetics
  • Track 2-13Nanocalorimetry
  • Track 2-14AFM for imaging proteins, platelets, Erythrocytes
  • Track 2-15Nanotechnology for Cancer, Cardiology, Theranostics, Respiratory Disease, Infectious Diseases , Neurological Diseases
  • Track 2-16Injectable micro- and nano devices
  • Track 2-17Microneedles for transdermal drug delivery
  • Track 2-18Injectable micro- and nano devices
  • Track 2-19Stents for drug delivery

Nanotechnology has found a vast number of applications in many areas and its market grown at a rapid pace in recent years. This resulted in new horizons in materials science and many exciting new developments. The supply of new Nanomaterials, form the prerequisite for any further progress in this new area of science and technology. Nanomaterials feature specific properties that are characteristic of these materials, and which are based on surface and quantum effects.  The control of composition, size, shape, and morphology of nanomaterials is an essential foundation for the development and application of Nanomaterials and Nano scale devices

  • Track 3-1Borophene and applications
  • Track 3-2Characterization of nanomaterials
  • Track 3-3Organic/ inorganic nanoparticles
  • Track 3-4organic/inorganic hybrid nanomaterials
  • Track 3-5nanomagnetic materials
  • Track 3-6CNT–Metal Nanoparticle Composites
  • Track 3-7Optically Responsive Polymer Nanocomposites
  • Track 3-8Metal Oxide Nanotubes, Chalcogenide Nanotubes
  • Track 3-9Nanocatalysts
  • Track 3-10physicochemical properties of nanomaterials
  • Track 3-11nanomaterial and biological activity
  • Track 3-12Self-Assembling Nanoclusters
  • Track 3-13Photo-Crosslinkable Nano-Objects
  • Track 3-14Block Copolymers as Nanoreactors
  • Track 3-15Complex Inorganic Nanostructures Based on Nanotubes
  • Track 3-16Nano fibers, Nanotubes, Nanoclays, Nanodots, Nanohelices, Nanorods
  • Track 3-17Printed materials & systems
  • Track 3-18Quantam properties of nanostructures

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 4-1Spintronic Nanoengineering
  • Track 4-2organic and molecular electronics and nano-thermoelectrics
  • Track 4-3Quantum electronics
  • Track 4-4spin electronics
  • Track 4-5polymer organic light-emitting diodes
  • Track 4-6Nanostructured Photoelectric Materials
  • Track 4-7CMOS Single Photon Avalanche Diode arrays
  • Track 4-8Metal-polymer nanocomposite sensors
  • Track 4-9Nanoband electrochemical sensing
  • Track 4-10Hybrid organic semiconductor smart pixel arrays
  • Track 4-11Digital 3D holographic display systems
  • Track 4-12Magnetoresistive Random Access Memory (MRAM)
  • Track 4-13Magnetoelectric Random Access Memory(MeRAM)
  • Track 4-14Nanotube-Based Nonvolatile Random Access Memory(NRAM)
  • Track 4-15MEMS/NEMS
  • Track 4-16Visible light communications
  • Track 4-17Lab on Chip devices
  • Track 4-18Smart Wireless Devices and Systems
  • Track 4-19Nanoelectronic devices for (bio)sensing
  • Track 4-20Micro- and Nanosystems Information Storage and Processing Systems
  • Track 4-21CMOS integrated nanomechanical resonators
  • Track 4-22Si based & Non-Si MEMS/NEMS
  • Track 4-23MEMS/NEMS measurement techniques, wafer level testing
  • Track 4-243D Wafer level, integration MEMS+ASIC
  • Track 4-25Micro/ Nano fluidic systems

Nano-fabrication is the configuration and production of gadgets with measurements measured in nanometers. One nanometer is 10 - 9 meters, or a million of a millimeter. Nanofabrication is of enthusiasm to PC engineers since it opens the way to super-high-thickness microchip s and memory chip s. It has been recommended that every information bit could be put away in a solitary iota. Conveying this further, a solitary molecule may even have the capacity to speak to a byte or expression of information. Nanofabrication has additionally gotten the consideration of the restorative business, the military, and the avionic business

  • Track 5-1Top-down & Bottom-up nanofabrication
  • Track 5-2Film deposition, Etching & Bonding
  • Track 5-3Thin film Technologies
  • Track 5-4Electrically induced nanopatterning & Rapid prototyping
  • Track 5-5AFM characterization of nanometer scale devices
  • Track 5-6Atomic Force Microscopy(AFM) & functional AFM probes
  • Track 5-7Molecular self assembly
  • Track 5-8Nanoimprint lithography
  • Track 5-9Electron beam lithography
  • Track 5-10Focused ion beam lithography
  • Track 5-11Colloid monolayer lithography
  • Track 5-12Multiphoton lithography
  • Track 5-13Scanning probe lithography
  • Track 5-14Photolithography & Soft lithography
  • Track 5-15Neutral particle lithography
  • Track 5-16X-ray lithography & Ion projection lithography
  • Track 5-17Laser printing of single nanoparticles
  • Track 5-18Magnetolithography & Nanosphere lithography
  • Track 5-19Proton beam writing & Charged-particle lithography

Researchers and companies consider the graphene, carbon sheets that are only one atom thick viable to be used as material in several fields. Potential applications include Fuel cells, Optoelectronics, Bio-micro robotics, Lower cost solar cells, Transistors, water desalination, sensors etc

  • Track 6-1Synthesis of graphene and new 2D materials
  • Track 6-2Electronic, optoelectronic properties of 2D materials
  • Track 6-3Graphene based nanoelectronic devices
  • Track 6-4Graphene for plasmonics and optics
  • Track 6-5Graphene supercapacitors & graphene polymer batteries
  • Track 6-6Graphene and 2D material sensors
  • Track 6-7Biological and toxicity aspects of graphene ,graphene oxide
  • Track 6-8Synthesis of Patterned Graphene films
  • Track 6-9Graphene-assisted laser desorption/ionization for mass spectrometry
  • Track 6-10Biological interactions of Graphene-family Nanomaterials
  • Track 6-11Spectroscopy, metrology & microscopy of graphene and 2D materials
  • Track 6-12Surface chemistry on graphene and 2D materials
  • Track 6-13Chemical functionalisation of Graphene
  • Track 6-14Controlled functionalisation of graphene oxide through surface modification
  • Track 6-15Characterisation and modelling of Graphene materials in Composites
  • Track 6-16Graphene and Graphene oxides
  • Track 6-17Graphene modification and functionalization
  • Track 6-18Graphene- and 2D materials- based nanocomposites
  • Track 6-19Graphene based nanofluids and nano lubricants

Functional Nano-scale structures frequently involve quite dissimilar materials which are difficult to characterize experimentally and ultimately be assembled, controlled, and utilized by manipulating quantities at the macro-scale a combination of features which puts unprecedented demands on theory, modelling and simulation

  • Track 7-1Multiscale Modelling for the Materials Improvement and Design
  • Track 7-2Nanostructured Metals: manufacturing and modelling
  • Track 7-3Nanostructured Multiphase Alloys
  • Track 7-4Quantum Mechanics for Modelling of Nanomaterials
  • Track 7-5Microstructure-based Models and Dislocation Analysis
  • Track 7-6Mechanics of Nanomaterials
  • Track 7-7Software for Modelling of Nanomaterials
  • Track 7-8Applications of Nanomaterials Modelling
  • Track 7-9Combinational logic and finite-state machines
  • Track 7-10Assembly operations using molecular manipulators
  • Track 7-11Simulation of Organic Semiconductor Devices
  • Track 7-12Atomistic Quantum Transport Simulations
  • Track 7-13Multiscale methods for charge / heat transport for nano-meso scale devices
  • Track 7-14Non-equilibrium Thermodynamics
  • Track 7-15Technologies based on alternative materials

The science and innovation of Nanomaterials has made awesome energy and desires in the most recent couple of years. The following decade is liable to witness significant steps in the arrangement, characterisation and abuse of Nanoparticles, Nanowires, Nanotubes, Nanorods, Nanocrystals, Nanounits and their congregations

  • Track 8-1Nanobioorganic Chemistry
  • Track 8-2QSAR modeling of nanomaterials
  • Track 8-3Biological and environmental surface interactions of nanomaterialssurface interactions of nanomaterials
  • Track 8-4Curvature on the properties of nanomaterials & biomedical applications
  • Track 8-5Biomedical applications of gold nanomaterials
  • Track 8-6Enhanced electrochemical DNA sensing
  • Track 8-7Nanomaterial‐based advanced immunoassays
  • Track 8-8Interactions of nanomaterials with the immune system
  • Track 8-9Lanthanide‐doped hollow nanomaterials
  • Track 8-10Nanomaterials: orthopedic implantable medical devices
  • Track 8-11Virus‐based nanomaterials
  • Track 8-12Nanomagnetic materials and applications
  • Track 8-13Dendrimer‐based nanocarriers
  • Track 8-14DNA‐based plasmonic nanoarchitectures and uses
  • Track 8-15Peptide nanostructures in biomedical technology
  • Track 8-16Membrane proteins as natural nanomachines
  • Track 8-17Direct chemoselective synthesis of glyconanoparticles
  • Track 8-18Structure and function of biological systems on the nanoscale
  • Track 8-19Biosurface engineering
  • Track 8-20G-protein coupled receptor signaling at the nanoscale
  • Track 8-21Prediction of Cell Settling on Nanostructure Arrays
  • Track 8-22Single Domain Antibodies for High Quality Surface Plasmon Resonance Studies
  • Track 8-23Biologically inspired Nano devices
  • Track 8-24Membrane Protein Multiplexed Nano-Arrays
  • Track 8-25Arrays of nanowires for cellular applications
  • Track 8-26Nanostructured bladder tissue replacements
  • Track 8-27Lipid-coated Nanocrystals and applications
  • Track 8-28Vertical nanowire arrays for protein detection and analysis
  • Track 8-29Nanowire Based Cell Impalement Devices and uses
  • Track 8-30Nanowire arrays and Cell Based Biosensing
  • Track 8-31Controlled Self-Assembly of Re-engineered Insulin
  • Track 8-32multifunctional plasmonic nanoparticles: Biomedical applications

Research into hydride materials for vitality applications commonly concentrates on upgrading gravimetric capacity thickness and particle transport of the materials. Then again, the necessities for stationary applications, for example, power devices can be essentially diverse and manageable to a more extensive class of potential materials. Various geophysical and social weights are driving a movement from fossil fills to renewable and practical vitality sources. To impact this change, we should make the materials that will bolster new vitality advances. Sun oriented vitality is the most extreme need to create photovoltaic cells that are productive and financially savvy

  • Track 9-1Nanoparticles
  • Track 9-2Nano sensors for intelligent & flexible grid management
  • Track 9-3Nano optimized heat exchangers
  • Track 9-4Nanostructured electrodes and applications
  • Track 9-5Nano porous materials and applications in micro fuel cells
  • Track 9-6Nano-porous materials and applications in reversible heat storage
  • Track 9-7Nano-catalysts for efficient fuel production
  • Track 9-8Nano composites for reduction of Hydro carbon emissions
  • Track 9-9Nano-porous foams & gels for thermal insulation
  • Track 9-10Applications in Intelligent air conditioning
  • Track 9-11Nanotechnology innovations for energy intensive industrial process
  • Track 9-12Nanotechnology for energy efficient lighting systems
  • Track 9-13Nano-optimized components for wireless power transmission
  • Track 9-14Carbon nanotubes and applications in energy transmission
  • Track 9-15Nanotechnology for loss-less power transmission
  • Track 9-16Nano fillers in electrical isolation systems
  • Track 9-17Soft Nano-magnetic materials for efficient electricity transmission
  • Track 9-18Use of Nano composites in superconducting components
  • Track 9-19Nano catalyst for efficient hydrogen generation
  • Track 9-20Antireflective coatings for photovoltaic cells
  • Track 9-21Nano composites and uses in renewable energy sources
  • Track 9-22Nano-based precision farming & Biomass energy
  • Track 9-23Nano particles for improved efficiency of fossil fuels
  • Track 9-24Nano composites applications in radiation shielding & protection
  • Track 9-25Nanostructured compounds for thermoelectric power generation
  • Track 9-26Nano optimized membranes & energy efficient fuel cells
  • Track 9-27Nano optimized membranes & applications in automobiles, mobile electronics

Nanoelectronics refer to the use of nanotechnology in electronic components. The term covers a diverse set of devices and materials, with the common characteristic that they are so small that inter-atomic interactions and quantum mechanical properties need to be studied extensively.

  • Track 10-1nanotubes/nanowires
  • Track 10-2Nanometrology of structured materials
  • Track 10-3Mechanical nanometrology
  • Track 10-4Thin film nanometrology
  • Track 10-5Chemical nanometrology
  • Track 10-6Dimensional nanometrology
  • Track 10-7Mass and Force Measurement
  • Track 10-8Coordinate Metrology
  • Track 10-9Surface Topography Characterisation
  • Track 10-10Surface Topography Measurement Instrumentation
  • Track 10-11advanced molecular electronics
  • Track 10-12Electrical nanometrology

Nanophotonics is an enabling technology which concerns with  application of photonics at nanoscale dimensions, where field enhancement effects which  result in new optical phenomena offering superior performance or completely new functionalities in photonic devices and  encompasses a wide variety of topics, including metamaterials, plasmonics, high resolution imaging, quantum nanophotonics, functional photonic materials.This technology  potential to impact across a wide range of photonics products such as  high efficiency solar cells to ultra-secure communications to personalized health monitoring devices

  • Track 11-1Infrared Vibrational Nanospectroscopy
  • Track 11-2Stimulated emission depletion (STED) microscopy
  • Track 11-3structured illumination microscopy (SIM)
  • Track 11-4photoactivated localization microscopy (PALM)
  • Track 11-5Ground state depletion-individual molecule return (GSDIM) microscopy
  • Track 11-6Stochastic optical reconstruction microscopy (STORM)
  • Track 11-7Direct stochastic optical reconstruction microscopy (dSTORM)
  • Track 11-8Near-field scanning optical microscopy (NSOM/SNOM)
  • Track 11-9Saturated excitation (SAX) microscopy
  • Track 11-10Surface-enhanced Raman spectroscopy (SERS)
  • Track 11-11Surface-enhanced infrared absorption spectroscopy (SEIRAS)
  • Track 11-12Shell-isolated nanoparticle-enhanced Raman spectroscopy (SHINERS)
  • Track 11-13Stimulated Raman spectroscopy (SRS).
  • Track 11-14Tip-enhanced Raman scattering (TERS) microscopy
  • Track 11-15Tip-enhanced photoluminescence (TE-PL) microscopy
  • Track 11-16Tip-enhanced coherent anti-Stokes Raman scattering (TE-CARS) microscopy
  • Track 11-17Reversible saturable optical fluorescence transitions (RESOLFT) microscopy
  • Track 11-18Single molecule fluoresence spectroscopy
  • Track 11-19Photoemission Electron Microscopy
  • Track 11-20highly efficient photovoltaic (PV) devices
  • Track 11-21photonic integrated circuit
  • Track 11-22Advanced Optical lithography & Microscopy
  • Track 11-23Tetratronics
  • Track 11-24Nanophotonics for Energy Conversion
  • Track 11-25Spectroscopic techniques with (ultra-)high spatial, temporal, and spectral resolution and sensitivity
  • Track 11-26modelling of light-matter-interaction and energy flow at the nanoscale
  • Track 11-27Enabling solar cells with higher efficiencies
  • Track 11-28CMOS Single Photon Avalanche Diode arrays & applications
  • Track 11-29polymer organic light-emitting diodes (P-OLEDs)
  • Track 11-30Efficient nonlinear nanoscale plasmonic sources
  • Track 11-31Nonlinear plasmonic metamaterials
  • Track 11-32Nonlinear approaches to bioimaging
  • Track 11-33Nonlinear plasmonics for sensing
  • Track 11-34Spectroscopic photoemission and low energy electron microscope (SPELEEM)
  • Track 11-35Energy-efficient lighting
  • Track 11-36Visible light data communications
  • Track 11-37X-ray spectroscopy

As nanotechnology is advancing, so is the extension for its business development. The extensive variety of potential items and applications gives nanotechnology its tremendous development prospects. It has been estimated that the worldwide nanotechnology industry will develop to reach US$ 75.8 Billion by 2020. In such a situation, tremendous open door lies for industry members to tap the quickly developing business sector. Significant contributions are expected to environmental and climate protection from Nanotechnological products, processes and applications are expected to by saving raw materials, energy and water as well as by reducing greenhouse gases and hazardous wastes. Usage of nano materials promises certain environmental benefits and sustainability effects

  • Track 12-1Nanoparticles for water purification
  • Track 12-2Industrial Safety measures for workers at the Nano manufacturing hubs
  • Track 12-3Health and safety implications of Engineered Nanomaterials
  • Track 12-4Need & Impact of Global regulations on nanomaterials
  • Track 12-5Nanotoxicity in cells
  • Track 12-6Toxicity screening and intracellular detection of nanomaterials
  • Track 12-7engineered nanomaterials & Biological interactions
  • Track 12-8Potential adverse health impacts of fibrous nanomaterials
  • Track 12-9Inhalation studies for safety assessment of nanomaterials
  • Track 12-10Risk management of nanomaterials
  • Track 12-11Characterization of nanomaterials for toxicity assessment
  • Track 12-12Toxicity of nanomaterials
  • Track 12-13Exposure and risk evaluation of nanomaterials
  • Track 12-14Nanoparticles for nuetralizaion of toxic materials
  • Track 12-15Bioaccumulation, biodegradability of nanomaterials

Nanoscience and Molecular Nanotechnology is the new outskirts of science and innovation in Europe and around the globe, working at the size of individual particles. Top researchers and in addition policymakers overall acclaim the advantages it would convey to the whole society and economy: a large portion of them demand the key part research would play in the quality creation procedure to create exploitable arrangement of innovations by the European business prompting a decision of remarkable applications, items, markets and productive income sources

  • Track 13-1Uses of Nano-materials & components in space exploration
  • Track 13-2Liquid-Repellent materials
  • Track 13-3Light-Seeking Synthetic Nano robot
  • Track 13-4Diamond Nanothreads
  • Track 13-5Nanomedicine for improved HIV drug therapies
  • Track 13-6Self-healable batteries
  • Track 13-7DNA-based single-electron electronic devices
  • Track 13-8smart textiles
  • Track 13-9Brain-inspired devices for artificial systems
  • Track 13-10quantum photonic circuits & applications
  • Track 13-11Multi-function chips
  • Track 13-12Thermoelectric Screen Printing
  • Track 13-13Smarter Self-Assembly
  • Track 13-14Phase-Change Devices and applications
  • Track 13-15Super-powered bionic plants
  • Track 13-16other potenial innovative ideas