Sessions

  • The present generation with faster and smaller electronics is the result of advancements in the research. Nowadays research on graphene is a hot topic owing to its unique and excellent properties. Graphene can be produced from mechanical exfoliation, chemical vapor deposition, plasma enhanced chemical vapor deposition, electrochemical synthesis and molecular beam epitaxy so on methods. Electrolysis of graphene is generally carried out to get graphene with high purity. In electronics, graphene is used to make electrodes for touch screens, transparent memory chips, integrated circuits with graphene transistors. The main energy-related areas which depend on graphene are solar cells, supercapacitors, lithium batteries and catalysis for fuel cells.
    •    Benefits of 2D Materials
    •    2D materials beyond Graphene
    •    2D Topological Materials
    •    Chemical functionalization of Graphene
     

  • Graphene was the first 2D material to be isolated. Graphene and other two-dimensional materials have a long list of unique properties that have made it a hot topic for intense scientific research and the development of technological applications. These also have huge potential in their own right or in combination with Graphene. The extraordinary physical properties of Graphene and other 2D materials have the potential to both enhance existing technologies and also create a range of new applications. Pure Graphene has an exceptionally wide range of mechanical, thermal and electrical properties. Graphene can also greatly improve the thermal conductivity of a material improving heat dissipation. In applications which require very high electrical conductivity, Graphene can either be used by itself or as an additive to other materials. Even in very low concentrations, Graphene can greatly enhance the ability of electrical charge to flow in a material. Graphene’s ability to store electrical energy at very high densities is exceptional. This attribute, added to its ability to rapidly charge and discharge, makes it suitable for energy storage applications.
    •    Battery Testing
    •    Progress in Materials Analysis
    •    Atomistic Modeling of Materials Failure
    •    Materials Synthesis and Characterization
    •    Advanced Structural and Functional Materials
    •    Photorefractive Effects and Materials
    •    Microscopy of Semiconducting Materials
    •    Practical Materials Characterization
    •    Nondestructive Characterization of Materials
    •    Powder Characterization
    •    Coatings Characterization
    •    Dispersions Characterization
    •    Formability of Metallic Materials
    •    Materials with Internal Structure
    •    Characterization of Advanced Materials
    •    Materials Characterisation and Mechanism of MicroCutting
    •    Nanoscale Imaging and Characterisation
    •    Hydrogen Storage Materials
    •    Nanoscale Characterisation of Ferroelectric Materials
    •    Failure analysis
    •    Material comparisons
    •    Deformulation
    •    Reverse engineering
    •    Crystallographic Texture of Materials
    •    Phase Change Materials
    •    D printed organs
    •    Ultrasonic Testing of Materials

  • 3D printing is the process of creating three- dimensional structure of biomaterials by means of computer control. With respect to the nano-scale dimensions the biomaterials are classified into three types as- Nano-particle (3D), Nano-fiber(2D) and Nano-sheet (1D). 3D bioprinting is the formation of numerous cell patterns by using printing techniques along with the layer-by-layer method to produce tissue mimetic structures without any harm in cell function that can be further used in tissue engineering. Electrospinning technology means deposition of polymer nanofibers on an object by using high voltage to a liquid polymer solution. Bioprinting helps in the research of drugs and pills by printing tissues and organs.  It is also used for micro devices and microarrays. The 3D printing materials market is expected to reach USD 1,809.5 Million by 2021 from USD 530.1 Million in 2018, at a CAGR of 23.40%.

  • Biomaterials are constituents that are intended to interrelate with the biological system either as a part of medical device or to replace or repair any injured organs or tissues. Biomaterials can be derived either naturally or synthetically. Some of the natural Biomaterials are silk, gelatin, etc. While the Synthetic ones are the various forms of polymers, ceramics and composites. Bioceramics like Alumina, Bioglass, Zirconia are used to reestablish injured portions of musculoskeletal system and used in dental and orthopaedic fields. Biocomposites are designed by using resin and natural fibres. It can be non-wood natural fibres (rice, wheat, coconut, etc.) Or wood fibres (magazines, soft and hard woods). Metals are mostly a choice of biomaterials in fields of dental, orthopaedic, cardiac implants. As metals can lead to wear, corrosion, so surface coating and modification of metals are essential for medical applications.
    •    Carbon dots
    •    D Materials heterostructures and superstructures
    •    Graphene analogues
    •    Hydrogen Technologies
    •    Solar thermal Energy
    •    Chemical functionalization of Graphene
    •    Graphene based products
    •    Applications of Carbon in Energy
    •    Carbon nanotubes and grapheme
    •    Semiconductor Materials and Nanostructures Optical Properties of Advanced Materials
    •    Applied Nano Electromagnetics
    •    Nonlinear Super Resolution Nano-Optics and Applications
    •    Nano Electronic Devices
    •    Nano Optics and Nano photonics
    •    Progress in Nonlinear Nano Optics
    •    Biomedical Optical Instrumentation and Laser Assisted Biotechnology
    •    Atomic, Molecular, Optical & Plasma Physics
    •    Lasers in Manufacturing and Materials Processing
    •    Imaging, microscopy, adaptive optics
    •    Photonics
    •    Laser beam delivery and diagnostics
    •    Lasers in medicine and biology
    •    Optical nanomaterials for photonics/biophotonics
    •    Advanced spintronic materials
    •    Dielectric materials and electronic devices
    •    Engineering applications of spectroscopy

  • Material characterization is the process of measuring and determining physical, chemical, mechanical and microstructural properties of materials.
    Materials Characterization and Applications are below mentioned
    •    Failure analysis
    •    Material comparisons
    •    De-formulation
    •    Reverse engineering
    •    Crystallographic Texture of Materials
    •    Phase Change Materials
    •    Aerospace
    •    Defense materials
    •    3D printed organs
    •    Pharmaceutical delivery system
    •    Ultrasonic Testing of Materials
    •    Dental implants
    •    Nanoscale Characterisation of Ferroelectric Materials
    •    Hydrogen Storage Materials
    •    Nanoscale Imaging and Characterisation
    •    Materials Characterisation and Mechanism of Micro-Cutting
    •    Characterization of Advanced Materials
    •    Materials with Internal Structure
    •    Formability of Metallic Materials
    •    Formability of Metallic Materials
    •    Progress in Materials Analysis
    •    Atomistic Modeling of Materials Failure
    •    Materials Synthesis and Characterization
    •    Advanced Structural and Functional Materials
    •    Photorefractive Effects and Materials
    •    Microscopy of Semiconducting Materials
    •    Practical Materials Characterization
    •    Nondestructive Characterization of Materials
    •    Powder Characterization
    •    Coatings Characterization
    •    Dispersions Characterization
    •    Battery Testing

  • Advanced Materials is a weekly peer-reviewed scientific journal covering materials science. It includes communications, reviews, and feature articles on topics in chemistry, physics, nanotechnology, ceramics, metallurgy, and biomaterials.
    •    Nanolithography
    •    Self-healing Fibre Composites
    •    Advanced Carbons
    •    Advanced Non-Oxide Ceramics
    •    Advanced Optical Ceramics
    •    Advanced Electro-ceramics
    •    Advanced Bio and Medical Ceramics
    •    Advanced Ceramic Coating
    •    Thermal and environmental barrier coatings Ceramic
    •    Gel casting
    •    Cellular ceramics
    •    Solid oxide fuel cell materials
    •    Oxide ferroelectrics
    •    Oxide multi-ferroics
    •    Hybrid and Hierarchical Composite Materials
    •    Mechanical Properties of Glass
    •    Functional Ceramics
    •    Stronger Materials/Higher Strength Composites
    •    Ceramic Metal Oxides
    •    Bio inert Materials
    •    Bio Ceramics
    •    Composite Ceramics
    •    Solid Oxide Fuel Cells
    •    Ceramic materials for solid oxide fuel cells
    •    Ultra high temperature composites
    •    Bioceramics
    •    Applications of Porous Ceramics
    •    Ceramics for body and vehicular armour
    •    Glassceramic
    •    Advanced Ceramics
    •    Biocomposites

  • The relationships which exist between the performance of electrical, optical, and magnetic devices and the microstructural characteristics of the materials from which they are constructed. The class uses a device-motivated approach which emphasizes emerging technologies. Device applications of physical phenomena are considered, including electrical conductivity and doping, transistors, photodetectors and photovoltaics, luminescence, light emitting diodes, lasers, optical phenomena, photonics, ferromagnetism, and magnetoresistance.
    •    Nano/Micro Structured Materials for Energy and Biomedical Applications
    •    functional scaffolds to provide extracellular microenvironment
    •    nonintrusive monitoring and analysis of functional biological substitutes
    •    subtle micromanipulation of extracellular cues
    •    high performance purification and stem cell proliferation systems
    •    Biological interactions with nanomaterials
    •    Biosensing and bioimaging
    •    Drug and DNA targeting delivery
    •    Biosensing and bioimaging
    •    Multiscale Materials Modelling
    •    Biomaterials and Biominerals
    •    Methodology Development
    •    Silicon Nanobiotechnology
    •    Tissue engineering and regenerative medicine
    •    bioprocess synthesis, optimization and simulation
    •    cheap & scalable bioprocesses
    •    design and construct novel “programmable” cells
    •    novel bio-products & bioreactors
    •    Biotechnology and Molecular Bioscience
    •    Restorable biomaterials
    •    Biochemical System and Processes
    •    Biomimetic materials
    •    Surface properties of biomaterials
    •    Surface properties of biomaterials
    •    Bioinorganic nanomaterials
    •    Computational studies of biomaterials
    •    Soft materials
    •    Biophysics

  • Carbon materials such as graphite and coke are usual components of friction materials. Graphite can be either natural or synthetic, but all types converge to the flake morphology, at least at the microscopic level. The lubricant properties of graphite are intensified by metal sulfides, especially antimony trisulfide. Small particles increase the positive benefits of graphite rather than large particles. The synergy between graphite and metal sulfide can be due to a direct interaction between the two materials by means of bonds involving dangling bonds or oxygen atoms of graphite edges, which may prevent oxidation and anchor graphite basal plane to the contact disk surface.
    •    Custom Materials Synthesis
    •    Super hydrophobic Surface Treatments
    •    Hard, Scratch Resistant Barrier Coatings
    •    Additive Manufacturing of Emerging Materials
    •    Biofilm and Materials Science
    •    Current Trends of Surface Science and Catalysis
    •    Experimental Innovations in Surface Science
    •    Surface Analysis Methods in Materials Science
    •    Theoretical Surface Science
    •    Protection of Metals and Physical Chemistry of Surfaces
    •    Coatings Technologies
    •    Applied Adhesion Science
    •    Surface Engineering and Tribology
    •    Fundamentals of surface engineering
    •    Surface coating and modification
    •    Catalysis and electrochemistry
    •    Nanoscale surface modifications
    •    Corrosion and heat treatment

  • A substance which has a molecular structure built up chiefly or completely from a large number of similar units bonded together, e.g. Many synthetic organic materials used as plastics and resins.
    •    Hydrogen Energy
    •    Modern Piezoelectric Energy Harvesting Materials
    •    Thermal Energy Storage Using Phase Change Materials
    •    High Energy Density Materials
    •    Neutron Applications in Materials for Energy
    •    Nanostructured Materials for Next Generation Energy Storage and Conversion
    •    Energy from Organic Materials
    •    Recent Advancements in Materials and Systems for Thermal Energy Storage
    •    Materials, Energy and Environment Engineering
    •    Materials for Chemical Sensing
    •    Materials for Advanced Energy Systems
    •    Solar Energy Materials
    •    Eco and Renewable Energy Materials
    •    Lithium ion batteries
    •    Fuel cell materials
    •    Solar energy materials
    •    Thermoelectric materials
    •    Photovoltaic devices
    •    Semiconductor materials
    •    Cryogenic materials
    •    Piezoelectric Nano-generators as fuel cells
    •    D batteries for microelectronics
    •    Organic batteries and photo voltaic
    •    Super capacitors and batteries
     

  • Ceramic engineering is the science and technology of creating objects from inorganic, non-metallic materials. This is done either by the action of heat, or at lower temperatures using precipitation reactions from high-purity chemical solutions.
    •    Nanomaterial Applications using Nanowires
    •    Rubber Nano Blends
    •    Nano, Quantum and Molecular Computing
    •    Smart MaterialsBased Actuators at the Micro/NanoScale
    •    Nano Convergence
    •    Quantum NanoPhotonics
    •    Micro and Nano Fabrication Technology
    •    Nano and Biotech Based Materials
    •    Nanosize Polymers
    •    Redox Systems Under NanoSpace Control
    •    NanoOptoelectronics
    •    Nanomaterial Applications using Nanoparticles
    •    Nanomaterial Applications using Nanofibers
    •    Nanomaterial Applications using Nanocomposites
    •    Nanomaterial Applications using Graphene
    •    Nanophysics
    •    Emissive Materials  Nanomaterials
    •    Molecular and NanoTubes
    •    Micro/Nano Cell and Molecular Sensors
    •    Fracture of Nano and Engineering Materials and Structures
    •    Metallic Micro and Nano Materials
    •    Nanomaterial Applications using Carbon Nanotubes
    •    Nano Manipulation
    •    Nano Devices and Interfaces
    •    Nanomaterials and Nanoengineering
    •    Colloids for Nano and Biotechnology
    •    Nanomaterials and Nanosystems for Biomedical Applications
    •    Glassy, Amorphous and NanoCrystalline Materials
    •    Micro and Nano Machining of Engineering Materials
    •    Nanomaterials
    •    Nanocomposites
    •    Nanoparticles
    •    Computational Nanoscience
    •    Nanophotonics
    •    Nanomedicine
    •    Quantum dots
    •    Nanofabrication
    •    Nanobiomaterials
    •    Nanodrug delivery
    •    Biomolecular Integrated Circuits
    •    Photonics Innovation

  • surface science and engineering including tribology, but with a special emphasis on the research and development in friction, wear, coatings and surface modification processes such as surface treatment, cladding, machining, polishing and grinding, across multiple scales from nanoscopic to macroscopic dimensions. High-integrity and high-performance surfaces of components have become a central research area in the professional community whose aim is to develop highly reliable ultra-precision devices.
    •    Smart materials applications
    •    Nuclear Engineering
    •    Waste Development and Characterisation
    •    Advanced Nuclear Materials Cements@Sheffield
    •    DPrinted Materials and Systems
    •    Thermal Spray Technology
    •    Materials for Energy Infrastructure
    •    Information Materials
    •    Ferrous & Non ferrous Materials
    •    Developments in Polymer Characterisation
    •    Materials Syntheses
    •    MATERIALS SYNTHESIS AND PROCESSING
    •    Shapememory alloys for biomedical implants
    •    Multicomponent alloys for lightweight vehicles or hightemperature engines
    •    Intermetallic alloys for hydrogen storage
    •    Advanced characterization by electron microscopy or atom probe of alloys with nanoscale precipitates
    •    Smart materials and structures
    •    Sustainable Construction Materials
    •    Advanced Structural Materials
    •    advanced manufacturing
    •    materials efficiency
    •    solidstate physics
    •    hybridizing metallurgy
    •    Materials for Green Technology
    •    Materials for Green Technology
    •    Physics and Chemistry of Materials
    •    Biosensing and bioimaging
    •    Metals and alloys
    •    renewable and sustainable energy
    •    Composite materials
    •    Graphene and fullerenes
    •    Quasi crystals
    •    Thin films and coatings
    •    Conductive materials
    •    Semiconductor alloy system
    •    Metals, Mining, Metallurgy and Materials

  • 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.

    • Highly efficient photovoltaic (PV) devices
    • photonic integrated circuit
    • Advanced Optical lithography & Microscopy
    • Tetratronics
    • Nanophotonics for Energy Conversion
    • Spectroscopic techniques with (ultra)high spatial, temporal, and spectral resolution and sensitivity
    • modelling of lightmatterinteraction and energy flow at the nanoscale
    • Enabling solar cells with higher efficiencies
    • CMOS Single Photon Avalanche Diode arrays & applications
    • polymer organic lightemitting diodes (POLEDs)
    • Efficient nonlinear nanoscale plasmonic sources
    • Nonlinear plasmonic metamaterials
    • Nonlinear approaches to bioimaging
    • Nonlinear plasmonics for sensing
    • Spectroscopic photoemission and low energy electron microscope (SPELEEM)
    • Energyefficient lighting
    • Visible light data communications
    • Infrared Vibrational Nanospectroscopy
    • Reversible saturable optical fluorescence transitions (RESOLFT) microscopy
    • Tipenhanced coherent antiStokes Raman scattering (TECARS) microscopy
    • Photoemission Electron Microscopy
    • Single molecule fluoresence spectroscopy
    • Stimulated emission depletion (STED) microscopy
    • structured illumination microscopy (SIM)
    • photoactivated localization microscopy (PALM)
    • Ground state depletionindividual molecule return (GSDIM) microscopy
    • Stochastic optical reconstruction microscopy (STORM)
    • Direct stochastic optical reconstruction microscopy (dSTORM)
    • Nearfield scanning optical microscopy (NSOM/SNOM)
    • Saturated excitation (SAX) microscopy
    • Surfaceenhanced Raman spectroscopy (SERS)
    • Surfaceenhanced infrared absorption spectroscopy (SEIRAS)
    • Shellisolated nanoparticleenhanced Raman spectroscopy (SHINERS)
    • Stimulated Raman spectroscopy (SRS)
    • Tipenhanced Raman scattering (TERS) microscopy
    • Tipenhanced photoluminescence (TEPL) microscopy
    • Xray spectroscopy

  • Materials science is important for the development of technology and has been or thousands of years. Different materials have different strengths and weaknesses and are uses for different purposes. Materials Science and Engineering is the study of all materials, from those we see and use every day such as a glass or a piece of sport equipment to those used in aerospace and medicine, through that understanding how materials work, can create new materials for new applications as well as develop existing materials to improve performance. They can control the structure of a material, from an atomic level up.
    •    Superparamagnetism
    •    Composite Materials
    •    Ceramic Matrix Nanocomposites
    •    Metal Matrix Nanocomposites
    •    Polymer Matrix Nanocomposites

  • Nano composites are materials that incorporate nanosized particles into a matrix of standard material. The result of the addition of nanoparticles is a drastic improvement in properties that can include mechanical strength, toughness and electrical or thermal conductivity

  • Nano materials 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 Nano scale. 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, Nano clays 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.
    •    Molecular Electronics
    •    Nano Radios
    •    Optoelectronic Devices
    •    Nano Fabrications
    •    Nanoionics

  • Nanoelectronics is the term used in the field of nanotechnology for electronic components and research on improvements of electronics such as display, size, and power consumption of the device for the practical use. This includes research on memory chips and surface physical modifications on the electronic devices.
    •    Background.
    •    Applications.
    •    Next-Generation Computer Chips.
    •    Kinetic Energy (KE) Penetrators with Enhanced Lethality.
    •    Better Insulation Materials.
    •    Phosphors for High-Definition TV.
    •    Low-Cost Flat-Panel Displays.
    •    Tougher and Harder Cutting Tools.
     


  • Nanoparticles are particles that exist on a nanometre scale (i.e., below 100 nm in at least one dimension). They can possess physical properties such as uniformity, conductance or special optical properties that make them desirable in materials science and biology. And Molecular nanotechnology (MNT) is a technology based on the ability to build structures to complex, atomic specifications by means of mechanosynthesis. This is distinct from nanoscale materials.
    •    Molecular assembler
    •    Mechanosynthesis
    •    Molecular engineering & Molecular machine
    •    Aerospace Transportation & Molecular Aero technology

  • nanophysics is the physics of structures and artefacts with dimensions in the nanometer range or of phenomena occurring in nanoseconds and Nanoscience and nanotechnology are all about relating and exploiting phenomena for materials having one, two or three dimensions reduced to the nanoscale.
    •    Nano Medicinal Chemistry
    •    Quantum dot imaging
    •    Life Cycle of Nanomaterials & Applications
    •    Nanostructured materials
    •    Nanochemical biology
    •    Organic Materials in Nanochemistry
    •    Green Nanochemistry
    •    Polymer Nanotechnology
    •    Cancer Chemistry
    •    Neurochemistry
    •    Nano Pharmaceutical chemistry
    •    Nanocrystals and Clusters
     

  • Nanochemistry is the combination of chemistry and nanoscience. Nanochemistry is associated with synthesis of building blocks which are dependent on size, surface, shape and defect properties.
    •    Nanoparticles for water purification
    •    Industrial Safety measures for workers at the Nano manufacturing hubs
    •    Health and safety implications of Engineered Nanomaterials
    •    Need & Impact of Global regulations on nanomaterials
    •    Nanotoxicity in cells
    •    Toxicity screening and intracellular detection of nanomaterials
    •    engineered nanomaterials & Biological interactions
    •    Potential adverse health impacts of fibrous nanomaterials
    •    Inhalation studies for safety assessment of nanomaterials
    •    Risk management of nanomaterials
    •    Characterization of nanomaterials for toxicity assessment
    •    Toxicity of nanomaterials
    •    Exposure and risk evaluation of nanomaterials
    •    Nanoparticles for nuetralizaion of toxic materials
    •    Bioaccumulation, biodegradability of nanomaterials

  • 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.
    •    Nanotubes/nanowires
    •    Electrical nanometrology
    •    Nanometrology of structured materials
    •    Mechanical nanometrology
    •    Thin film nanometrology
    •    Chemical nanometrology
    •    Dimensional nanometrology
    •    Mass and Force Measurement
    •    Coordinate Metrology
    •    Surface Topography Characterisation
    •    Surface Topography Measurement Instrumentation
    •    Surface Topography Measurement Instrumentation
    •    Displacement Measurement
    •    advanced molecular electronics
    •    Biological nanometrology

  • Nanoelectronics refers 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. And Nanometrology is a subfield of metrology, concerned with the science of measurement at the nanoscale level. Nanometrology has a crucial role in order to produce nanomaterials and devices with a high degree of accuracy and reliability in nanomanufacturing.
    •    Nanoparticles
    •    Nanoporous foams & gels for thermal insulation
    •    Nanotechnology innovations for energy intensive industrial process
    •    Nanotechnology for energy efficient lighting systems
    •    Antireflective coatings for photovoltaic cells
    •    Nano composites and uses in renewable energy sources
    •    Nano composites and uses in renewable energy sources
    •    Nanobased precision farming & Biomass energy
    •    Nano particles for improved efficiency of fossil fuels
    •    Nano composites applications in radiation shielding & protection
    •    Nanostructured compounds for thermoelectric power generation
    •    Nano optimized membranes & energy efficient fuel cells
    •    Nano composites for reduction of Hydro carbon emissions
    •    Nanocatalysts for efficient fuel production
    •    Nanoporous materials and applications in reversible heat storage
    •    Nano catalyst for efficient hydrogen generation
    •    Use of Nano composites in superconducting components
    •    Soft Nanomagnetic materials for efficient electricity transmission
    •    Nano fillers in electrical isolation systems
    •    Nanotechnology for lossless power transmission
    •    Carbon nanotubes and applications in energy transmission
    •    Nanooptimized components for wireless power transmission
    •    Nano sensors for intelligent & flexible grid management
    •    Nano optimized heat exchangers
    •    Nanostructured electrodes and applications
    •    Nano porous materials and applications in micro fuel cells
    •    Nano optimized membranes & applications in automobiles, mobile electronics
     

  • Nanotechnologies provide essential improvement potentials for the development of both conventional energy sources (fossil and nuclear fuels) and renewable energy sources like geothermal energy, sun, wind, water, tides or biomass. Nano-coated, wear resistant drill probes, for example, allow the optimization of lifespan and efficiency of systems for the development of oil and natural gas deposits or geothermal energy and thus the saving of costs. Further examples are high-duty nanomaterials for lighter and more rugged rotor blades of wind and tidepower plants as well as wear and corrosion protection layers for mechanically stressed components (bearings, gear boxes, etc.). Nanotechnologies will play a decisive role in particular in the intensified use of solar energy through photovoltaic systems. In case of conventional crystalline silicon solar cells, for instance, increases in efficiency are achievable by antireflection layers for higher light yield.
    •    Nanostructured bladder tissue replacements
    •    Nanomaterials: orthopedic implantable medical devices
    •    Virus?based nanomaterials
    •    Nanomagnetic materials and applications
    •    Dendrimer?based nanocarriers
    •    DNA?based plasmonic nanoarchitectures and uses
    •    Peptide nanostructures in biomedical technology
    •    multifunctional plasmonic nanoparticles: Biomedical applications
    •    Nanobioorganic Chemistry
    •    Structure and function of biological systems on the nanoscale
    •    Biosurface engineering
    •    Gprotein coupled receptor signaling at the nanoscale
    •    Prediction of Cell Settling on Nanostructure Arrays
    •    Single Domain Antibodies for High Quality Surface Plasmon Resonance Studies
    •    Biologically inspired Nano devices
    •    Membrane Protein Multiplexed NanoArrays
    •    Lanthanide?doped hollow nanomaterials
    •    Interactions of nanomaterials with the immune system
    •    Lipidcoated Nanocrystals and applications
    •    Vertical nanowire arrays for protein detection and analysis
    •    Nanowire Based Cell Impalement Devices and uses
    •    Nanowire arrays and Cell Based Biosensing
    •    Controlled SelfAssembly of Reengineered Insulin
    •    Direct chemoselective synthesis of glyconanoparticles
    •    Membrane proteins as natural nanomachines
    •    QSAR modeling of nanomaterials
    •    Biological and environmental surface interactions of nanomaterialssurface interactions of nanomaterials
    •    Curvature on the properties of nanomaterials & biomedical applications
    •    Biomedical applications of gold nanomaterials
    •    Enhanced electrochemical DNA sensing
    •    Nanomaterial?based advanced immunoassays
    •    Arrays of nanowires for cellular applications
     

  • Recent Applications of Nanotechnology and Nanoparticles in Fisheries and Aquaculture

  • 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, characterization and abuse of Nanoparticles, Nanowires, Nanotubes, Nano rods, Nanocrystals, Nanounits and their congregations.
    •    Background.
    •    Applications.
    •    Next-Generation Computer Chips.
    •    Kinetic Energy (KE) Penetrators with Enhanced Lethality.
    •    Better Insulation Materials.
    •    Phosphors for High-Definition TV.
    •    Low-Cost Flat-Panel Displays.
    •    Tougher and Harder Cutting Tools.
     

  • 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.
    •    Thin films charecterisation & processing
    •    Colloid monolayer lithography
    •    Multiphoton lithography
    •    Scanning probe lithography
    •    Photolithography & Soft lithography
    •    Neutral particle lithography
    •    Xray lithography & Ion projection lithography
    •    Laser printing of single nanoparticles
    •    Magnetolithography & Nanosphere lithography
    •    Focused ion beam lithography
    •    Electron beam lithography
    •    Topdown & Bottomup nanofabrication
    •    Film deposition, Etching & Bonding
    •    Thin film Technologies
    •    Electrically induced nanopatterning & Rapid prototyping
    •    AFM characterization of nanometer scale devices
    •    Atomic Force Microscopy(AFM) & functional AFM probes
    •    Molecular self-assembly
    •    Nanoimprint lithography
    •    Proton beam writing & Charged particle lithography
     

  • Spectroscopy of multiply ionized atoms.This branch of spectroscopy deals with radiation related to atoms that are stripped of several electrons, trends which correlates Space and Astronomy with Nanoparticles

  • 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.Nanoengineering is the application extension of Nanotechnology, which is a collective term for a range of new technologies that involve the manipulation of matter at small scales, typically 0.2-100 nanometres.
    •    Spintronic Nanoengineering
    •    MEMS/NEMS
    •    Visible light communications
    •    Lab on Chip devices
    •    Smart Wireless Devices and Systems
    •    photonic integrated circuit
    •    Nanoelectronic devices for (bio)sensing
    •    Micro and Nanosystems Information Storage and Processing Systems
    •    CMOS integrated nanomechanical resonators
    •    Si based & NonSi MEMS/NEMS
    •    MEMS/NEMS measurement techniques, wafer level testing
    •    D Wafer level, integration MEMS+ASIC
    •    NanotubeBased Nonvolatile Random Access Memory(NRAM)
    •    Magnetoelectric Random Access Memory(MeRAM)
    •    organic and molecular electronics and nanothermoelectrics
    •    Quantum electronics
    •    spin electronics
    •    polymer organic lightemitting diodes
    •    Nanostructured Photoelectric Materials
    •    CMOS Single Photon Avalanche Diode arrays
    •    Metalpolymer nanocomposite sensors
    •    Nanoband electrochemical sensing
    •    Hybrid organic semiconductor smart pixel arrays
    •    Digital D holographic display systems
    •    Magnetoresistive Random Access Memory (MRAM)
     

  • 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.
    •    Borophene and applications
    •    Printed materials & systems
    •    Complex Inorganic Nanostructures Based on Nanotubes
    •    Nano fibers, Nanotubes, Nanoclays, Nanodots, Nanohelices, Nanorods
    •    Complex Inorganic Nanostructures Based on Nanotubes
    •    Block Copolymers as Nanoreactors
    •    PhotoCrosslinkable NanoObjects
    •    SelfAssembling Nanoclusters
    •    nanomaterial and biological activity
    •    physicochemical properties of nanomaterials
    •    Nanocatalysts
    •    Metal Oxide Nanotubes, Chalcogenide Nanotubes
    •    Optically Responsive Polymer Nanocomposites
    •    CNT–Metal Nanoparticle Composites
    •    nanomagnetic materials
    •    organic/inorganic hybrid nanomaterials
    •    Organic/ inorganic nanoparticles
    •    Characterization of nanomaterials
    •    Quantam properties of nanostructures

  • Nanomedicine is a branch of medicine that applies the knowledge and tools of nanotechnology to the prevention and treatment of disease. Nanomedicine involves the use of nanoscale materials, such as biocompatible nanoparticles and nanorobots, for diagnosis, delivery, sensing or actuation purposes in a living organism. And Nanobiotechnology is a discipline in which tools from nanotechnology are developed and applied to study biological phenomena. For example, nanoparticles can serve as probes, sensors or vehicles for biomolecule delivery in cellular systems.

    •    Nanostructured compounds for thermoelectric power generation
    •    Biology Inspired Nanomaterial’s
    •    Biosensors and Nano Probes
    •    Biocompatibility of Orthopaedic Implants
    •    Nanoparticle based biologic mimetic
    •    Nanocalorimetry
    •    AFM for imaging proteins, platelets, Erythrocytes
    •    Nanotechnology for Cancer, Cardiology, Respiratory Disease, Infectious Diseases
    •    Neurological Diseases
    •    Injectable micro and nano devices
    •    Micro needles for transdermal drug delivery
    •    Stents for drug delivery
    •    Enabling Personalised Medicine
    •    Nano diagnostics
    •    Nanoscale Tools and Techniques in Surgery
    •    CNT–Metal Nanoparticle Composites
    •    Characterization of nanomaterials
    •    Nanomaterials: orthopedic implantable medical devices
    •    Graphene based nanofluids and nano lubricants
    •    Nanoband electrochemical sensing
    •    Regenerative Medicine & Targeted Drug Delivery
    •    Radio Nanomedicine
    •    Nano dentistry
    •    Nanobiosystems
    •    Tissue Engineering
    •    Risk management of nanomaterials
     

+1-315-902-2237