Atomics Physics 2020

Atomics Physics 2020

Conference series LLC Ltd is organizing Atomic Physics Conference in 2020 at Vancouver, Canada. We organize Physics Meetings in the fields related to Atomic Physics, Nuclear Physics, Nanotechnology, Quantum Nuclear Physics, Nuclear Engineering, Atomic Spectroscopy and Atomic Collisions, Quantum Science & Technology.

Conference Name



Atomic Physics  2020

 Vancouver, Canada

 August 24-25, 2020


On this auspicious occasion, Conference Series invites the participants from all over the globe to take part in the Atomic, Molecular and Plasma Physics at Vancouver, Canada August 24-25, 2020.

Importance & Scope:

Atomic Physics is the study of atoms as an isolated system of electrons and an atomic nucleus, whereas nuclear physics studies the constituents (protons and neutrons) and interactions of atomic nuclei. Atomic Physics also describes the physics of molecules and their properties. The essential concerned is with arrangement of electrons around the nucleus and the processes by which these arrangements change which includes ions and neutral atoms. Physics touches every aspect of our lives. It involves the study of matter, energy and their interactions. As such, it is one area of science that cuts across all other subjects. Other sciences are reliant on the concepts and techniques developed through physics. Plasma Physics is the study of a state of matter comprising charged particles. Plasma can only be artificially generated by heating or subjecting a neutral gas to a strong electromagnetic field to the point an ionized gaseous substance becomes increasingly electrically conductive, and long-range electromagnetic fields dominate the behavior of the matter. This is so called Ionization can also be achieved using high power laser light or microwaves. Plasmas are found naturally in stars and in space.

Why to attend?

The conference series aims to disseminate the advancements of research in Atomic, Molecular and Plasma physics to the global community by creating a platform for active participation of industries and academic organizations through exchange of new ideas amongst the of expertise and lateral thinking from researchers, scientists and students through invited plenary lectures, symposia, workshops, oral and poster sessions of unsolicited contributions.

Target Audience:

  • Scientists/Professors in the field of Atomic & Nuclear
  • Research societies and Research Institutes
  • Professors, Students and Technical Staff from Physics and other related disciplines
  • Directors of Physics companies
  • Delegates from Physical Science societies and Associations
  • Advertising and Promotion Agency Executives



Thermal Plasmas/Hot Plasmas:

Thermal plasmas have electrons and the heavy particles at the same temperature, i.e. they are in thermal equilibrium with each other.

Non-Thermal Plasma/Cold Plasmas:

Nonthermal plasmas on the other hand are non-equilibrium ionized gases, with two temperatures: ions and neutrals stay at a low temperature, whereas electrons are much hotter. A kind of common nonthermal plasma is the mercury vapor gas within a fluorescent lamp, where the "electrons gas" reaches a temperature of 10,000 kelvins while the rest of the gas stays barely above room temperature, so the bulb can even be touched with hands while operating.

Active Plasmas:

Active plasma regions: These carry field-aligned currents which give them filamentary or sheet structure with thickness down to a few cyclotron radii (ionic or even electronic). They transmit energy from one region to another and produce electric double layers which accelerate particles to high energies. Active regions cannot be described by hydromagnetic theories. Boundary conditions are essential and may be introduced by circuit theory.

Atomic Physics:

Atomic physics studies about the atoms which isolates the system of electrons and an atomic nucleus. This deals with the properties of atoms, which are mostly due to their electron configuration. Atomic physics is mainly concerned with electrons encircling the nucleus of an atom. It has led to important applications in medicine, lasers, communications, etc. and also providing a testing ground for Quantum Theory, Quantum Electrodynamics and its derivatives.

Passive Plasma:

Passive plasma regions, which can be described by classical hydrodynamic theory. They transmit waves and high energy charged particles but if the field-aligned currents exceed a certain value they are transferred into.


Atomic spectroscopy studies about the electromagnetic radiation absorbed and emitted by atoms. In the determination of elemental compositions the electromagnetic spectrum or mass spectrum is applied that can be distributed by the type of spectroscopy used or with the atomization source. For systematic use the technology of atomic spectroscopy has generated three techniques such as Atomic Absorption, Atomic Emission and Atomic Fluorescence. The transitions involve the relaxation and excitation of the outer or bonding shell electrons of metal ions and atoms and the corresponding photons have energies inside the visible regions of the spectrum and ultraviolet. A decent instance of this is the dark absorption lines in the solar spectrum.

Atomic Collisions:

Atomic collisions are elementary collisions that occur between two atomic particles such as atoms, molecules, electrons or ions. This kind of collisions is two types, they are elastic collisions and inelastic collisions. In an Elastic collision the total energy remains the same before and after the collision, where the directions of motion of the particles are transformed and the kinetic energy is merely distributed among the particles. In an Inelastic collision the internal energy of the colliding particles will change where these particles go through transitions to different energy levels and the electronic state of an atom or a molecule is changed.

Atomic and Nuclear Astrophysics:

Atomic Astrophysics implements atomic physics calculations which use atomic data for reading astronomical observations. Atomic physics plays a main role in the arena of astrophysics because the astronomers get the information about any particular object through the emitted light, as this light will arise through the atomic transitions. Nuclear Astrophysics is a combination of nuclear physics and astrophysics which studies about the nuclear reactions and nuclear-level processes that occur naturally in space.

Laser-Atomic Physics:

Laser stands for Light Amplification by Stimulated Emission of Radiation. The physics of an atom laser is similar to that of an optical laser and the main difference between an optical and an atom laser is that atoms interact with themselves, cannot be created as photons and retain mass whereas photons do not. Main applications of the atom laser are atom holography and atom interferometry.

Cold Atoms and Molecules:

The interaction of an atom and radiation has three processes to analyze. 1) Spontaneous Emission where the classical oscillating charge will radiate spontaneously and an atom can spontaneous transit from an excited higher energy state to a state of lower energy by emitting a photon called quantum of the electromagnetic field. 2) In second state the atom can absorb a photon a beam of radiation and making a move from lower energy state to higher energy sate where the intensity of the applied field is proportional to the rate of absorption. 3) In Stimulated Emission, under the influence of an applied radiation field atoms can also emit photons.


Nanotechnology is the study and application of very small things which is about 1 to 100 nanometers. Nanotechnology is control of matter on a nuclear, sub-atomic and supramolecular scale. Nanotechnology as characterized by size is actually extremely wide, including fields of science as different as surface science, natural science, sub-atomic science, semiconductor material science, micro fabrication, sub-atomic building and so on.

Atomic Periodic table:

Periodic table arranges all the elements basing on their atomic number, electron configurations and recurring chemical properties. The rows of the table are called periods and the columns are called groups. The periodic table can be used to develop interactions between the properties of the elements and calculate the properties of new elements that are to be discovered.

Atomic and Molecular Physics:

Atomic physics is the subfield of AMO that studies atoms as an isolated system of electrons and an atomic nucleus, while Molecular physics is the study of the physical properties of molecules.Atomic physics which deals with the atom as a system consisting of a nucleus and electrons. Molecular physics is concerned with atomic processes in molecules, but it is additionally concerned with effects due to the molecular structure.Molecular Dynamics:

Plasma Physics:

Plasma physics is the study of a state of matter comprising charged particles. Plasmas are usually created by heating a gas until the electrons become detached from their parent atom or molecule. This so-called ionization can also be achieved using high-power laser light or microwaves. Plasmas are found naturally in stars and in space.

Space Physics:

Space physics is the study of plasmas as they arise naturally in the Earth's upper atmosphere. It includes heliophysics which includes the solar physics of the Sun: the solar wind, planetary magnetospheres and ionospheres, cosmic rays. It is an essential part of the study of space weather and has important consequences not only to understand the universe, but also to practical everyday life, and also includes the process of communications and weather satellites. Space physics uses measurements from high altitude rockets and spacecraft.


Several members of the Astrophysics Group are part of the Space Plasma Climate Section. Relevant research in this group includes studies of the formation and evolution of dusty galaxies, studies of the formation of stars and planets, investigations into the habitability of planets forming around stars of varied types, the study of the Sun and Sun-like stars, quantification of the variability of the Sun for use in climate modelling, and the search for signs of biological activity within our own Solar System.

Atomic Physics systems has been increasing due to the developing necessities of the industries as wells as the substantial demand. Atomic Physics market is estimated to reach USD 5.60 Billion by 2020, rising at a CAGR of 6.0% through the calculation period of 2015 to 2020. North America probably is expected to have the largest share, in the upcoming years; the atomic physics market is expected to see the maximum growth rate in the Asia-Pacific region, with accent on India, China and Japan. Some of the key players in the global atomic physics market comprise Agilent Technologies (U.S.), PerkinElmer (U.S.), Thermo Fisher Scientific (U.S.) and Bruker Corporation (U.S.).

The atomic force microscopy market was valued at USD 441 million in 2019 and is projected to reach USD 586 million by 2024; it is expected to grow at a CAGR of 5.8% during the forecast period. The key drivers of atomic force microscopy is committed support from several governments to promote nanotechnology and Nanoscience research and development.

The global molecular spectroscopy market is expected to reach USD 6.85 billion by 2022 from USD 4.98 billion in 2017, at a CAGR of 6.6%. The growth of this market is majorly driven by food safety concerns, the growth of the pharmaceutical and biotechnology industry, technological advancements in molecular spectroscopy and application of molecular spectroscopy in environmental screening.

The rising levels of environmental pollution, coupled with the severe depletion of natural resources, are the major factors that have brought into effect several laws and regulations to monitor environmental pollution levels. For instance, in the U.S., the Safe Drinking Water Act (SDWA), Clean Water Act (CWA), and Resource Conservation and Recovery Act (RCRA) focus on regulating the quality of the environment through the use of analytical tools, such as molecular spectroscopy. In environmental applications, molecular spectroscopy is used in the following areas:

  • Wastewater Treatment: To analyze the changes in the concentration/composition of inlet water
  • Water Safety Analysis: To quantify bacterial concentration levels and the concentration of other constituents in water samples
  • Measurement of PAH (Polycyclic Aromatic Hydrocarbons) Levels in the Environment: To monitor PAH levels, as this substance is shown to cause carcinogenic and mutagenic effects and is a potent immunosuppressant

The global cold plasma market size is projected to reach USD 3.1 billion by 2024 from USD 1.5 billion in 2019, at a CAGR of 15.6%. In the current regulatory climate-where the focus on sustainable techniques has risen-it is expected that the benefits of cold plasma will ensure its greater adoption in the years to come. Innovations in textile production and growing food safety concerns are the major factors driving the growth of this market.

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Conference Date 2020-08-24
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