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.

Attraction is a class of physical wonders that are intervened by attractive fields. Electric streams and the attractive snapshots of rudimentary particles offer ascent to an attractive field, which follows up on different ebbs and flows and attractive minutes. The most natural impacts happen in ferromagnetic materials, which are unequivocally pulled in by attractive fields and can be polarized to wind up perpetual magnets, creating attractive fields themselves. Just a couple of substances are ferromagnetic; the most widely recognized ones are iron, nickel and cobalt and their compounds. The prefix ferro-alludes to press, since changeless attraction was first seen in lodestone, a type of common iron mineral called magnetite, Fe3O4.

  • Track 1-1Para magnetism
  • Track 1-2Chemical magnetism
  • Track 1-3Diamagnetism
  • Track 1-4Bio magnetism
  • Track 1-5One dimensional magnetism
  • Track 1-6Molecular magnetism
  • Track 1-7Computational magnetism
  • Track 1-8Non-Magnetic Semiconductors Ferromagnetism
  • Track 1-9Ferrimagnetism
  • Track 1-10Anti-ferromagnetism
  • Track 1-11Highly frustrated magnetism
  • Track 1-12Super Para-magnetism

A magneto is an electrical generator that uses permanent magnets to produce periodic pulses of alternating current. Unlike a dynamo, a magneto does not contain a commutator to produce direct current. It is categorized as a form of alternator, although it is usually considered distinct from most other alternators, which use field coils rather than permanent magnets. Hand-cranked magneto generators were used to provide ringing current in telephone systems. Magnetos were also adapted to produce pulses of high voltage in the ignition systems of some gasoline-powered internal combustion engines to provide power to the spark plugs.

  • Track 2-1Magnetoresistive random-access memory (MRAM)
  • Track 2-2Hetero-structures
  • Track 2-3Half-metallic materials
  • Track 2-4Magneto electric
  • Track 2-5Magnetic oxides
  • Track 2-6Magnetic tunnel
  • Track 2-7Molecular beam epitaxy (MBE)
  • Track 2-8Tunnel magneto resistance
  • Track 2-9Giant magneto resistance
  • Track 2-10Multiferroic materials
  • Track 2-11Complex oxides
  • Track 2-12Sputter growth
  • Track 2-13Chemical sensors
  • Track 2-14Functional oxides
  • Track 2-15Hall effect

The electromagnetic power assumes a noteworthy part in deciding the inside properties of most questions experienced in everyday life. Standard issue takes its frame because of intermolecular powers between singular iotas and atoms in issue, and is an appearance of the electromagnetic power. Electrons are bound by the electromagnetic power to nuclear cores, and their orbital shapes and their effect on adjacent molecules with their electrons is portrayed by quantum mechanics. The electromagnetic power represents the procedures engaged with science, which emerge from associations between the electrons of neighboring iotas. 

  • Track 3-1Magneto-dielectric materials
  • Track 3-2Magnetism and magnetic fields
  • Track 3-3Electric currents in magnetic fields
  • Track 3-4Electromagnetic induction
  • Track 3-5Magneto-electric phenomena
  • Track 3-6Magneto-resistance
  • Track 3-7Magneto-impedance
  • Track 3-8Magnetic sensors
  • Track 3-9Electromagnetic devices
  • Track 3-10Electromagnetic radiation

Spintronics (a portmanteau importance turn transport electronics) otherwise called turn gadgets, is the investigation of the natural turn of the electron and its related attractive minute, notwithstanding its central electronic charge, in strong state devices. Spintronics on a very basic level contrasts from customary hardware in that, notwithstanding charge state, electron turns are abused as a further level of opportunity, with suggestions in the effectiveness of information stockpiling and exchange. Spintronic frameworks are frequently acknowledged in weaken attractive semiconductors (DMS) and Heusler composites and are specifically compelling in the field of quantum figuring

  • Track 4-1Spin frustration
  • Track 4-2Spin effects
  • Track 4-3Graphene and topological insulators
  • Track 4-4Spin injection
  • Track 4-5Quantum spin liquids
  • Track 4-6Spin transfer torques
  • Track 4-7Spin orbitronics
  • Track 4-8Semiconductor spintronics
  • Track 4-9Antiferromagnetic spintronics
  • Track 4-10Spin glasses
  • Track 4-11Spin waves
  • Track 4-12Magnetic skymions
  • Track 4-13Spin structure

The tremendous capability of ultrafast turn control for applications in data stockpiling, preparing and recovery invigorates a developing enthusiasm for the energized states and non-balance properties of attractive structures. The rudimentary quanta of excitations in a requested troupe of attractive minutes are magnons, otherwise called spinwaves when found in the wave picture. An exact learning of the range of spinwave excitations is important for fitting the usefulness of attractive nanostructures

  • Track 5-1Hysteresis modelling
  • Track 5-2Magnetic recording
  • Track 5-3Ultrafast switching
  • Track 5-4Magnetization damping
  • Track 5-5Vortex dynamics
  • Track 5-6Magnetic imaging
  • Track 5-7Magnonics
  • Track 5-8Domain walls
  • Track 5-9Magnetic microscopy

Changeless magnets, or hard attractive materials, emphatically oppose demagnetization once charged. They are utilized, for instance, in engines, amplifiers, meters, and holding gadgets, and have coercivities Hc from a few hundred to a huge number of oersteds (10 to more than 100 kA/m). The majority of business lasting magnets are of the earthenware write, trailed by the Alnicos and the cobalt-samarium, press neodymium, press chromium-cobalt, and extended single-space (ESD) types in diminishing grouping of utilization. The general nature of a perpetual magnet is spoken to by the most noteworthy vitality item (BH)m; however relying upon the plan contemplations, high Hc, high remaining enlistment Br (the attractive acceptance when H is diminished to zero), and reversibility of porousness may likewise be controlling variables

  • Track 6-1Quantum devices
  • Track 6-2Glass materials
  • Track 6-3Intermetallic materials
  • Track 6-4Hard magnet processing
  • Track 6-5Ceramics
  • Track 6-6Rare-earth transition metal borides
  • Track 6-7Magnetic data storage
  • Track 6-8Permanent magnets

These materials are described by their low misfortune and high penetrability. There are an assortment of composites utilized with different blends of attractive properties, mechanical properties, and cost. There are seven noteworthy gatherings of financially imperative materials: iron and low-carbon steels, press silicon amalgams, press aluminum-silicon composites, nickel-press combinations, press cobalt compounds, ferrites, and undefined composites

  • Track 7-1Hysteresis loop
  • Track 7-2Magnetostriction
  • Track 7-3Crystalline alloys
  • Track 7-4Power adaption
  • Track 7-5Magnetic field screening
  • Track 7-6Ferrites and garnets
  • Track 7-7Signal transfer
  • Track 7-8Power conversion
  • Track 7-9Amorphous

Uncommon Magnetic materials are those materials which are considered and utilized essentially for their attractive properties. The attractive reaction of an extraordinary attractive material is to a great extent controlled by the attractive dipole minute related with the characteristic rakish force, or turn, of its electrons. Much as a few materials show ferromagnetic properties, which means they frame changeless magnets, some are known to display ferroelectric properties, where the material has an unconstrained electric polarization. Once in a while, materials have both these properties, and are known as multiferroics

  • Track 8-1Magneto-photonic crystals
  • Track 8-2Cavity opto-magnonics
  • Track 8-3Magneto-caloric materials
  • Track 8-4Millimetres-wave materials
  • Track 8-5Microwave materials
  • Track 8-6Magneto-optics
  • Track 8-7Magneto-elastic materials

Earth's attractive field, is otherwise called the geomagnetic field, is the attractive field that reaches out from the Earth's inside out into space, where it meets the sunlight based breeze, a flood of charged particles exuding from the Sun. Its greatness at the Earth's surface extents from 25 to 65 microteslas (0.25 to 0.65 gauss). Roughly it is the field of an attractive dipole presently tilted at an edge of around 11 degrees regarding Earth's rotational hub, as though there were a bar magnet put at that edge at the focal point of the Earth. The North geomagnetic post, situated close Greenland in the northern side of the equator, is really the south shaft of the Earth's attractive field, and the South geomagnetic post is the north post. The attractive field is created by electric streams because of the movement of convection ebbs and flows of liquid iron in the Earth's external center driven by warm getting away from the center, a characteristic procedure called a geodynamo.

 

  • Track 9-1Thermoremanent magnetization
  • Track 9-2Pale magnetism
  • Track 9-3Magnetosphere
  • Track 9-4Geomagnetic field
  • Track 9-5Archeomagnetism
  • Track 9-6Interplanetary magnetic field
  • Track 9-7Magnetic and mineralogical studies

Basic materials will be materials utilized or considered essentially for their mechanical properties, instead of their electronic, attractive, concoction or optical attributes. This can incorporate a materials reaction to a connected power, regardless of whether this reaction is versatile or plastic, its hardness, and its quality.  Basic materials are characterized presenting to the classification of material, as metallic, nonmetallic, and arrangement materials; rendering to plan, as deformable, cast, sintered, formed, stuck, welded; standing to working conditions, as low-temperature materials and materials impenetrable to warm, crumbling, scrambling, wear, fuel, and oil; and as indicated by strength, as low-and medium-sturdiness materials, with vast speculations of versatility, and high-toughness materials, with unobtrusive ventures of pliancy

  • Track 10-1Exchange bias
  • Track 10-22D and 3D magnetic structures
  • Track 10-3Magnetic anisotropy
  • Track 10-4Thin films and surface effects
  • Track 10-5Multi-layered films and super lattices
  • Track 10-6Electronic structure
  • Track 10-7Patterned films

The expression "nano" isn't new and is only a prefix for 10-9. Be that as it may, it makes the 'universe of materials' exceedingly captivating when the span of materials begins to reach underneath 100 nm. Shockingly, outlandish marvels begin to happen when the measure of material achieves 15-30 nm or beneath. The appearances of nano-impact can be as different as perception of quantum fluorescence in CdSe delineated by an adjustment in the shading from red to violet as the molecule measure diminishes, or fortifying of a heretofore weak artistic framework by support with carbon nanotubes, or interface building to accomplish improved quality in materials, for example, metallic glasses. Regularly, because of size requirements, one needs to utilize particular methods to describe the structure and properties of nanomaterials requiring utilization of complex portrayal instruments, for example, high determination filtering and transmission electron microscopy, nuclear power and examining burrowing microscopy, nano-space and nano-control

  • Track 11-1Advanced nano material’s
  • Track 11-2Synthesis of nano materials and properties
  • Track 11-3Magnetic microscopy and imaging
  • Track 11-4Thin Films, nano tubes
  • Track 11-5Magnetic microscopy and imaging
  • Track 11-6Magneto photonics
  • Track 11-7Nano magnetism
  • Track 11-8Magnetic clusters, nano particles and nano wires
  • Track 11-9Multilayer films and super lattices
  • Track 11-10Nano fibers, Nano rods , Advanced Nano materials
  • Track 11-11Nano electronics
  • Track 11-12Magneto plasmonics
  • Track 11-13Thin Films, nano tubes
  • Track 11-14Nano wires
  • Track 11-15Nano electronics
  • Track 11-16Nano structures and devices
  • Track 11-17Multilayer films and super lattices
  • Track 11-18Nano materials
  • Track 11-19Nano structures and devices
  • Track 11-20Nano photonics
  • Track 11-21Micro magnetic modelling
  • Track 11-22Nano crystalline materials
  • Track 11-23Synthesis of nano material’s and properties
  • Track 11-24Magnetic clusters, nano particles and nano wires
  • Track 11-25Micro magnetic modelling
  • Track 11-26Nano magnetism

Magnetostratigraphy is a geophysical connection method used to date sedimentary and volcanic successions. The technique works by gathering focused examples at estimated interims all through the area. The examples are broke down to decide their trademark remanent polarization (ChRM), that is, the extremity of Earth's attractive field at the time a stratum was stored. This is conceivable in light of the fact that volcanic streams obtain a thermoremanent charge and silt get a depositional remanent polarization, both of which mirror the bearing of the Earth's field at the season of arrangement. This strategy is ordinarily used to date arrangements that for the most part need fossils or interbedded molten shake

  • Track 12-1Magnetization
  • Track 12-2Amperes Law
  • Track 12-3Magnetic Field
  • Track 12-4Magnetic Flux
  • Track 12-5Magnetic Dipole Moment
  • Track 12-6Gauss’s Law
  • Track 12-7Biot-Savart Law

The use of attraction and attractive materials swarms our cutting edge progress as electrical power, correspondences and data stockpiling. The power and significance of such applications are reflected in the multi-billion dollar for every year advertise for attractive materials in three expansive territories: hard magnets, delicate magnets, and attractive recording. Continuous advancement in the field of attractive materials has not, be that as it may, stayed limited to these all around distinguished zones. Frequently classes of attractive materials are found with fascinating usefulness, which fortify the development of new innovation. In this article we talk about some such attractive materials, where a strong to-strong thermodynamic stage change offers ascend to fascinating practical properties with cutting edge applications

  • Track 13-1Magneto-caloric materials and devices
  • Track 13-2Molecular magnets
  • Track 13-3Magneto-photonic crystals
  • Track 13-4Magneto-photonic crystals
  • Track 13-5Cavity opto-magnonics
  • Track 13-6Magneto electronic materials and phenomena
  • Track 13-7Heavy fermion systems
  • Track 13-8Magneto-elastic materials and devices
  • Track 13-9Multifunctional magnetic materials
  • Track 13-10Thin films and surface effects
  • Track 13-11Multi-layered films and super lattices
  • Track 13-12Patterned films
  • Track 13-132D and 3D magnetic structures
  • Track 13-14Magnetic fluids and separations
  • Track 13-15Magnetic anisotropy

Right now there is a typical conviction that the clarification of superconductivity marvel lies in understanding the instrument of the arrangement of electron sets. Matched electrons, be that as it may, can't shape a superconducting condensate unexpectedly. These combined electrons perform messy zero-point motions and there are no power of fascination in their outfit. With a specific end goal to make a bound together troupe of particles, the sets must request their zero-point changes so a fascination between the particles shows up. Because of this requesting of zero-point motions in the electron gas, superconductivity emerges. This model of buildup of zero-point motions makes the likelihood of having the capacity to get gauges for the basic parameters of basic superconductors, which are in acceptable concurrence with the deliberate information. On the another hand, the marvel of superfluidity in He-4 and He-3 can be comparably clarified, because of the requesting of zero-point changes. It is thusly settled that both related wonders depend on the same physical instrument

  • Track 14-1Strongly correlated electrons systems (SCES)
  • Track 14-2Ferro fluids
  • Track 14-3High-Tc cu prates
  • Track 14-4Fe-based superconductivity
  • Track 14-5Superconductivity at Nano scale
  • Track 14-6Magnetic fluids
  • Track 14-7Magnetic superconductors
  • Track 14-8Magnetic superconductors
  • Track 14-9Organic superconductivity
  • Track 14-10Boron-based superconductivity
  • Track 14-11Conductors and insulators
  • Track 14-12Magnetic semiconductors
  • Track 14-13Superconducting materials

Hard magnets are connected in the information stockpiling simple and information stockpiling advanced. Delicate magnets are utilized for the assembling of transformers which are connected in control adaption, flag exchanging and attractive field screening. Extraordinary turn structures in multilayered materials are connected in quantum gadgets through the items like GMR perusing head and MRAM

  • Track 15-1Transformers
  • Track 15-2Sensors
  • Track 15-3Power electronics
  • Track 15-4Inductors
  • Track 15-5Magnetic levitation
  • Track 15-6High frequency devices
  • Track 15-7Power devices
  • Track 15-8Magnetic propulsion
  • Track 15-9Magnetic shielding
  • Track 15-10Low-dimensional systems
  • Track 15-11Heavy fermion systems
  • Track 15-12Magnetic measurements

This year the disclosure of femtosecond demagnetization by laser beats is 20 years of age. Out of the blue this development work by Bigot and associates gave understanding in an immediate manner into the time sizes of infinitesimal communications that interface the turn and electron framework. THz spintronics and all-optical turn control are ending up increasingly plausible. The point of this viewpoint is to call attention to where we can associate the diverse astound bits of understanding accumulated more than 20 years to create utilizations of ultrafast turn material science for ultrafast attraction control: THz spintronic gadgets. This influences the field of ultrafast to turn flow a rising theme open for some, specialists at the present time

  • Track 16-1All optical Switching
  • Track 16-2Novel Applications
  • Track 16-3Current understanding of ultrafast processes
  • Track 16-4Theoretical Perspectives
  • Track 16-5Coarse grained thermal model
  • Track 16-6Ultrafast spin transport
  • Track 16-7Ultimate timescale : Future of Coherent Control