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International Conference on Atomic and Nuclear Physics, will be organized around the theme ““Moving to Master Physics at Atomic Level””

Atomic Physics 2016 is comprised of 13 tracks and 185 sessions designed to offer comprehensive sessions that address current issues in Atomic Physics 2016.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

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Nuclear and sub-atomic material science it the investigation of the properties, flow and collaborations of the essential (however not major) building pieces of matter. A pivotal segment of this is understanding the conduct of the electrons that encompass the nuclear core; these elements command the way iotas and atoms communicate with their surroundings.
  • Track 1-1Fundamental particles
  • Track 1-2Atomic and nuclear structure
  • Track 1-3Atomic astrophysics
  • Track 1-4Radiation
  • Track 1-5Nuclear stability
  • Track 1-6Atom- photon interactions
  • Track 1-7 Metastable atoms and molecules
  • Track 1-8Ground state of phosphorus
  • Track 1-9Exchange interaction
  • Track 1-10Spin-orbit interaction
  • Track 1-11Hyperfine structure and zeeman effect in hydrogen
  • Track 1-12Hydrogenic ions
  • Track 1-13Geonium
  • Track 1-14Hyperfine-interaction-induced mixing of states of different J
  • Track 1-15Nanoparticles and Nanotechnology
  • Track 1-16Parity nonconservation in atoms
  • Track 1-17Parity nonconservation in anti-atoms
  • Track 1-18The anapole moment
  • Track 1-19Mass and energy
  • Track 1-20Electron density inside the nucleus
  • Track 1-21Radioactive decay
  • Track 1-22Binding energy

The analysis of the effect of magnetic and electrical external field on atoms favors a deep understanding of quantum properties of matter. Futhermore, magnetic or electrical fields are tools currently used in several experimental studies. The Stark effect is the shifting and splitting of lines of atoms and particles because of energy of an outside electric field. The measure of part or moving is known as the Stark part or Stark move. When all is said in done, one recognizes first-and second-request Stark impacts. The principal request impact is straight in the connected electric field, while the second-request impact is quadratic in the field.The Stark impact is in charge of the weight expanding (Stark widening) of ghastly lines by charged particles. At the point when the split/moved lines show up in ingestion, the impact is known as the opposite Stark effect.The Stark impact is the electric simple of the Zeeman impact where an otherworldly line is part into a few segments because of the vicinity of an attractive field.

  • Track 2-1Atom optics
  • Track 2-2Electric polarizability of the hydrogen ground state
  • Track 2-3Polarizabilities for highly excited atomic states
  • Track 2-4Using stark shifts to measure electric fields
  • Track 2-5Larmor precession frequencies for alkali atoms
  • Track 2-6Magnetic field inside a magnetized sphere
  • Track 2-7Classical model of magnetic resonance
  • Track 2-8Energy level shifts due to oscillating fields
  • Track 2-9Spin relaxation due to magnetic field inhomogeneity
  • Track 2-10Electric-field shifts of magnetically split Zeeman sublevels
  • Track 2-11Geometric (Berry’s) phase

Nuclear innovation will be development that incorporates the reactions of atomic centers. Among the wonderful nuclear progressions are nuclear reactors, nuclear arrangement and nuclear weapons. It is moreover used, notwithstanding different things, in smoke locators and weapon sights. Nuclear legitimate sciences is the examination of nuclear materials to find affirmation for example the source, the trafficking, and the headway of the material. Nuclear fuel is a material that can be "blasted" by nuclear part or mix to deduce nuclear imperativeness. Nuclear fuel can imply the fuel itself, or to physical things (for occasion packs made out of fuel posts) made out of the fuel material, mixed with essential, neutron-coordinating, or neutron-reflecting materials. Restorative Physics is the exploratory journal of the American Association of Physicists in Medicine and is an official science journal of the Canadian Organization of Medical Physicists, the Canadian College of Physicists in Medicine, and the International Organization for Medical Physics (IOMP).

  • Track 3-1Quantum mechanics
  • Track 3-2Two-level system under periodic perturbation
  • Track 3-3Quantization of the electromagnetic field
  • Track 3-4Emission of light by atoms
  • Track 3-5Absorption of light by atoms
  • Track 3-6Resonant absorption cross-section
  • Track 3-7Absorption cross-section for a doppler-broadened line
  • Track 3-8Saturation parameters
  • Track 3-9Angular distribution and polarization of atomic fluorescence
  • Track 3-10Change in absorption due to optical pumping
  • Track 3-11Optical pumping and the density matrix
  • Track 3-12Cascade decay
  • Track 3-13Coherent laser excitation
  • Track 3-14Transit-time broadening
  • Track 3-15A quiz on fluorescence and light scattering
  • Track 3-16Two-photon transition probability
  • Track 3-17Vanishing raman scattering
The least complex case in which to consider the collaboration in the middle of particles and light is that of a two-level iota driven by an intelligible optical field. This framework has been comprehensively concentrated on, uncovering a scope of sound impacts, for example, Rabi motions and catching because of the optical dipole power. Ordinarily, the energized state in the two-level framework has a limited lifetime because of unconstrained emanation back to the ground state. On one hand this rot is worthwhile, as it permits particles to be cooled by radiation weight. Then again, the defenselessness is along these lines ruled by a huge, absorptive segment . The determined two-level framework is along these lines ineffectively suited to applications in non-straight optics at the single-photon level.However, the expansion of a third level and a second optical field offers ascend to a scope of sound marvels including electromagnetically actuate straightforwardness which smothers the full assimilation. The outcome is a vast dispersive optical non-linearity which can be utilized to control the engendering of light through the medium.

 

  • Track 4-1Resonant faraday rotation
  • Track 4-2Kerr effect in an atomic medium
  • Track 4-3The hanle effect
  • Track 4-4Stark-induced transitions
  • Track 4-5Magnetic deflection of light
  • Track 4-6Classical model of an optical-pumping magnetometer
  • Track 4-7Searches for permanent electric dipole moments

Atomic collisions is developed on the premise of the relations for binary collisions and also for the Coulomb impacts inferred in the research center arrangement of directions. Developed as an estimation in light of the double impacts, i.e., the free combine connections of the individual components of the impacting frameworks, the hypothesis, with its monstrous straightforwardness, not just allows an unmistakable subjective translation of the nuclear crashes, additionally depicts well their quantitive viewpoint. Regarding that hypothesis, a larger part of essential inelastic procedures going with the nuclear impacts are broke down. Specifically, estimations are made for the accompanying: (i) ionization of atoms and particles by light particles (electrons), and by overwhelming particles (protons, deuterons), including inward shell ionization and twofold ionization; (ii) excitation of single and triplet lines (excitation with trade and without trade); (iii) catch of electrons in circle; (iv) backing off of substantial charged particles (with thought of the catch process and of the communication with the Coulomb field of the core); (v) inelastic scrambling of electrons on molecules and atoms. By hypothesis added to, the "diffraction" of basic particles on nuclear frameworks is clarified on the premise of corpuscular mechanics; it is demonstrated that the discrete vitality conditions of the scatterer electrons—and the anisotropy in the space introduction of their speeds on account of gems—are in charge of the primary elements of the diffraction design. Having available to us a straightforward hypothesis with no self-assertive parameters aside from those depicting the objective framework, we discover it a helpful instrument for the examination of nuclear structure.

  • Track 5-1High energy physics
  • Track 5-2Spectral line broadening due to phase diffusion
  • Track 5-3Dicke narrowing
  • Track 5-4Basic concepts in spin exchange
  • Track 5-5Spin radiation effects
  • Track 5-6Electron-randomization collisions
  • Track 5-7Larmor precession under conditions of rapid spin exchange
  • Track 5-8Penning ionization of metastable helium atoms
  • Track 5-9Collisions in a buffer gas
  • Track 5-10The spin-temperature limit

Cold atoms are particles that are kept up at temperatures close to 0 kelvin (supreme zero), typically underneath temperatures of some place in the scope of tenths of microkelvins (µK). At these temperatures the molecule's quantum-mechanical properties get the opportunity to be important.To reach such low temperatures, a blend of a couple of frameworks must be used. In the first place particles are by and large gotten and pre-cooled by method for laser cooling in a magneto-optical trap. To accomplish the most decreased possible temperature, further cooling is performed using evaporative cooling as a part of an alluring or optical trap.Experiments with ultracold particles are crucial for understanding quantum stage move and focusing on Bose–Einstein development (BEC), bosonic superfluidity, quantum fascination, various body turn progress, Efimov states, Bardeen-Cooper-Schrieffer (BCS) superfluidity and the BEC-BCS crossover.we study the relationship of particles with particles or iotas and their diffusing properties (e.g., their spreading lengths or their inelastic effects), ultracold atoms in optical matrices (e.g. the superfluid-Mott spread move in bosonic tests), non-direct effects (e.g., in moderate light and EIT frames), the course of action of ultracold atoms(e.g., using photoassociation close Feshbach resonances). We test ultracold atomic examples of Rb particles to control their scrambling properties, and to for ultracold iotas (Rb2 and KRb). We inquire about ultracold particles by procuring careful spectra that reveal their internal structure. We in like manner focus on their correspondence with outside field and among themselves. These will incite examining savage sub-nuclear gases.

  • Track 6-1Ultracold Interactions and their Control
  • Track 6-2Laser cooling: Basic ideas
  • Track 6-3Zeeman slower
  • Track 6-4Bose-Einstein condensation
  • Track 6-5Bose-Einstein condensation from an optical lattice
  • Track 6-6Cavity cooling
  • Track 6-7Cavity cooling for many particles: Stochastic cooling
  • Track 6-8Matter-wave vs. optical sagnac gyroscopes
  • Track 6-9Fermi energy for a harmonic trap
  • Track 6-10Amplitude of molecular vibrations
  • Track 6-11Vibrational constants for the morse potential
  • Track 6-12Centrifugal distortion
  • Track 6-13Relative densities of atoms and molecules in a vapor
  • Track 6-14Isotope shifts in molecular transitions
  • Track 6-15Electric dipole moments of polar molecules
  • Track 6-16Scalar coupling of nuclear spins in molecules
  • Track 6-17Spin Radiation Effects
  • Track 6-18Magneto-optical traps

Experimental method is the utilization of controlled perceptions and estimations to test theories.The theory part treats quantifiable frameworks for data examination. experimental methods vary from discipline to discipline anf from simple experiments and perceptions. The hypothesis part treats statistical techniques for information investigation. In the exploratory part the understudy gets preparing in arranging and performing tests, in examining trial information with factual, the computer based strategies assessing measurable and systematic uncertainties, and in documentation and presentation, oral and also composed.

  • Track 7-1Reflection of light from a moving mirror
  • Track 7-2Laser heating of a small particle
  • Track 7-3Laser Spectroscopy
  • Track 7-4Frequency doubling of modulated light
  • Track 7-5Ring-down of a detuned cavity
  • Track 7-6Transmission through a light guide
  • Track 7-7Quantum fluctuations in light fields
  • Track 7-8Noise of a beamsplitter
  • Track 7-9Photon shot noise in polarimetry
  • Track 7-10Light-polarization control with a variable retarder
  • Track 7-11Pile-up in photon counting
  • Track 7-12Photons per mode in a laser beam
  • Track 7-13Tuning dye lasers
  • Track 7-14Femtosecond laser pulses and frequency combs
  • Track 7-15Magnetic field fluctuations due to random thermal currents
  • Track 7-16Quantum electrodynamics
  • Track 7-17Diatomic Molecules of Astrophysical Interest
  • Track 7-18Exploring quantum Interferences with few atoms and photon
  • Track 7-19Degenerate quantum gases
  • Track 7-20Spectrum of frequency-modulated light

Atomic material science is the field of physical science that studies atomic centers and their constituents and correspondences. The most normally known use of nuclear physical science is nuclear power time, however the examination has incited applications in various fields, including nuclear arrangement and appealing resonation imaging, nuclear weapons, molecule implantation in materials building, and radiocarbon dating in geology and archaeology.The field of particle physical science created out of nuclear physical science and is routinely taught in cozy association with nuclear physics.The history of nuclear material science as a request specific from atomic material science starts with the disclosure of radioactivity by Henri Becquerel in 1896, while inquiring about gleam in uranium salts.The divulgence of the electron by J. J. Thomson a year later was an indication that the atom had inside structure. Around the begin of the twentieth century the recognized model of the particle was J. J. Thomson's "plum pudding" model in which the particle was a firmly blamed pack for smaller conflictingly charged electrons introduced inside it.

  • Track 8-1The atomic nucleus
  • Track 8-2The nuclear many-body problem
  • Track 8-3The fundamental forces
  • Track 8-4The elementary particles
  • Track 8-5Neutrino physics
  • Track 8-6Particle detectors
  • Track 8-7Nuclear energy
  • Track 8-8Nuclear reactions
  • Track 8-9Nuclear fusion
  • Track 8-10Physics of uranium and nuclear energy
  • Track 8-11Reactor physics
  • Track 8-12Nuclear reactors
  • Track 8-13Metal corrosion in nuclear reactors
  • Track 8-14Nuclear interactions
Nuclear physics  is advancing rapidly at the precision wild, where estimations of nuclear observables are trying best in class nuclear models. A huge responsibility is joined with the extending availability of revived light outflows particles made using the isotope separation on-line technique. These advances have come as an entwined unit with tremendous progression in the change of high-profitability pointer systems and improved target developments which are invaluable in mishandling these columns to their full advantage.A overpowering center can contain numerous nucleons. This infers with some estimation it can be managed as a set up system, instead of a quantum-mechanical one. In the consequent liquid drop illustrate, the center has an essentialness which rises most of the way from surface weight and not entirely from electrical abhorrence of the protons. The liquid drop model can copy various segments of centers, including the general example of tying essentialness with respect to mass number, and the wonder of nuclear fission.Other more jumbled models for the center have also been proposed, for instance, the teaming up boson model, in which joins of neutrons and protons interface as bosons, comparably to Cooper arrangements of electrons.Few mojor moves in nuclear material science are Nuclear decay, Nuclear blend, Nuclear part, Production of "considerable" segments (atomic number more conspicuous than five).
 
  • Track 9-1Nuclear structure and dynamics
  • Track 9-2Elementary modes of excitation
  • Track 9-3Giant electric and spin vibrations
  • Track 9-4Deltas in nuclei
  • Track 9-5Macroscopic nuclear dynamics
  • Track 9-6Resonances in heavy-ion system
  • Track 9-7The three-nucleon nucleus and infinite nuclear matter
  • Track 9-8Expanding the traditional many- body theory
  • Track 9-9Fundamental forces in the nucleus
  • Track 9-10The physics of hypernuclei
  • Track 9-11Quantum cromodynamics at lower energies
  • Track 9-12Nuclei under extreme conditions
  • Track 9-13Nuclei at high temperatures and density
  • Track 9-14The heaviest elements and new transfermium elements
  • Track 9-15Highly unstable nuclei
  • Track 9-16Nuclei with extremely high spin

Nuclear physics science is ubiquitous in our lives: Detecting smoke in our homes, testing for and treating development, and checking payload for goods are just a part of the ways that nuclear physical science and the frameworks it has created have any sort of impact in our wellbeing, wellbeing, and security. Some of today's most basic progressions in medication, materials, imperativeness, security, climatology, and a wide range of sciences radiate from the wellspring of essential inventive work in nuclear physical science. Answers to irrefutably the most basic request facing our planet will start from nuclear science, interdisciplinary tries in essentialness and air, and business focus advancements. The monetary impact of the uses of Nuclear material science is significant.Nuclear Physics determinedly affects our step by step lives, through advances in development, security, wellbeing, and energy creation, however then is every now and again misinterpreted by the general population.

  • Track 10-1Nuclear astrophysics
  • Track 10-2Nuclear safety
  • Track 10-3Supernova explosions and neutron star formation
  • Track 10-4The solar neutrino problem
  • Track 10-5Stellar evolution
  • Track 10-6Relativistic hydrodynamics
  • Track 10-7Nuclear Imaging of Disease
  • Track 10-8Nuclear Medicine
  • Track 10-9New Radioisotopes
  • Track 10-10Nuclear reactions in stars

Nuclear physics is the field of material science that studies the constituents and correspondences of atomic centers. The most normally known employments of nuclear material science are nuclear power time however the investigation has given application in various fields, joining those in nuclear arrangement and appealing resonation imaging, nuclear weapons, molecule implantation in materials planning, and radiocarbon in topography and archaeology.The present unsettled regions of nuclear physical science fuse major and quickly making issues. One is understanding the structure and lead of unequivocally collaborating matter likewise as its vital constituents, quarks and gluons, over a wide arrangement of conditions—from typical atomic matter to the thick centers of neutron stars, and to the Big Bang that was the beginning of the universe.Another is to outline quantitatively the properties of focuses, which are at the focuses of all particles in our reality, regarding models got from the properties of the solid connection.

  • Track 11-1Approaching the quark-gluon plasma
  • Track 11-2States of nuclear matter
  • Track 11-3Achieving quark deconfinement
  • Track 11-4Detecting the quark-gluon plasma
  • Track 11-5Additional relativistic heavy-ion physics
  • Track 11-6Quark in neulei
  • Track 11-7Changing descriptions of nuclear matter
  • Track 11-8Mesons and baryon resonances in nuclei
  • Track 11-9Nuclear properties under extreme conditions
  • Track 11-10Nuclear science and technology
  • Track 11-11Nuclear power
  • Track 11-12Energy technology
  • Track 11-13Nuclear and radiation medicine
  • Track 11-14Materials modification and analysis
  • Track 11-15Ground-level ozone

Nuclear physics addresses the method for matter making up 99.9 percent of the mass of our consistent world. It explores the nuclear reactions that fuel the stars, including our Sun, which gives the essentialness to all life on Earth. The field of nuclear material science joins some place in the scope of 3,000 exploratory and theoretical pros who work at schools and national labs over the United States, and what's more the trial workplaces and establishment that allow these examiners to address the wonderful coherent request going up against us. This report gives a layout of the boondocks of nuclear material science as we enter the accompanying thousand years, with phenomenal attentiveness in regards to the state of the science in the United States.Discoveries in nuclear material science—new ponders connected with the piece of quarks and gluons in the center, the structure and advance of centers, the nuclear physical study of the universe, and the purposes of repression of the Standard Models are within compass in light of our late hobbies in new workplaces and instrumentation. With CEBAF having started on its examination venture of the quark-gluon structure of matter, RHIC going to leave on the examination of matter at the limits of imperativeness thickness, and with other late advances in specific capacities, a rich exploratory harvest is confined by truly obliged spending arranges. The admonitory gathering endorses the nearby term task of advantages anticipated that would comprehend these novel trial and theoretical open door.

  • Track 12-1Accelerators in nuclear physics
  • Track 12-2The planned continuous electron beam accelerator facility
  • Track 12-3The next major initiative: the relativistic nuclear collider
  • Track 12-4Nuclear instrumentation
  • Track 12-5Nuclear theory
  • Track 12-6Accelerators research and development
  • Track 12-7Enriched stable isotopes
  • Track 12-8Nuclear data compilation
  • Track 12-9Applications of atomic and nuclear physics
  • Track 12-10Nuclear medical facilities and medical physics
  • Track 12-11Nuclear materials and nuclear fuels
  • Track 12-12Nuclear forensics
  • Track 12-13Quantum Control
  • Track 12-14Quantum gases as simple systems for many-body physics
  • Track 12-15Parity Violation in Atoms

Physics has unmistakable sorts of controversies.In every class, the most Controversial focuses are subjects on which, amongst scientists, different conclusions exist. Then again, the once-over you make shows up not to contain an extensive segment of these things. They appear to rather contain two remarkable classes: things on which a broad accord exists that they are FALSE, and things on which a broad understanding exists that they are TRUE. In the blink of an eye, clearly, for about every subject, you can find a few people who induced of the converse, however then, skirting on every declaration is a faulty decree (since you'll for the most part find two or three crazy people who claim it is unmistakable, for all intents and purposes "religious" reasons), Cold Fusion, Free imperativeness/Perpetual development, Qualifiying traits of a planet (What makes a planet?), Blackholes, Wormholes, Riemman's Hyp. (would it have the capacity to be exhibited or not?), Big Bang (static universe?), Evolution, Embryonic Stem Cell Research.

  • Track 13-1Precession of a compass needle?
  • Track 13-2Ultracold neutron polarizer
  • Track 13-3Exponentially growing/decaying harmonic field
  • Track 13-4The magic angle
  • Track 13-5Understanding a Clebsch-Gordan coefficient selection rule
  • Track 13-6The Kapitsa pendulum
  • Track 13-7Visualization of atomic polarization
  • Track 13-8Units, conversion factors, and typical values
  • Track 13-9Spectroscopic notation for atoms and diatomic molecules
  • Track 13-10Euler angles and rotation matrices