Allied Academies invites all the participants from all over the world to attend International Conference on Plasma Chemistry 2017 during November 13-14, 2017 in Paris, France which includes prompt keynote presentations, Oral talks, Poster presentations and Exhibitions.
Plasma Chemistry 2017 is a unique opportunity to discuss best practices within the laboratory research and those in other industries if the people are doing related things getting a variety of viewpoints can help us see where we can change or improve our own ideas and processes. There will be many seminars, workshops and technical sessions take place which will catch the attention of the professionals to attend the conference and it would enormously enrich our knowledge in understanding the current requirements of the global pharmaceutical industry. The expert will get an excellent opportunity to give many presentations and lectures on different topic and will also present their case studies.
In the light of this theme, the allied academies aims to provide a forum for international researchers from various areas of Plasma Chemistry. This conference brings together individuals who are interested in fields of physical Chemistry & Therapeutic approaches for physical Chemistry and researchers from various areas of chemistry, pharmacy, materials science and chemical engineering by providing a platform for critical analysis of new data, and to share latest cutting-edge research findings and results about all aspects of Plasma Chemistry. The meeting will be a multidisciplinary gathering and paving way to explore issues of mutual concern as well as exchange knowledge.
Allied Academies organizes 1000+ Global events every year across the globe with support from 1000+ more scientific societies and Publishes 700 Open access journals which contains over 50000 eminent personalities, reputed scientists as editorial board members.
The market of plasma chemistry across the globe is expected to propel significantly during the forecast period, with value expected to hit 135.6 Million dollars in 2016 to 297.6 Million dollars by 2021, at a CAGR of 14.0% from 2016 to 2021 according to the recent research report. Based on application, the plasma therapy market is segmented into orthopedics, dermatology, dental, cardiac muscle injury, nerve injury, and others. The orthopedic segment is further segmented into arthritis, chronic tendinitis, and bone repair & regeneration. Similarly, the dermatology segment is further segmented into androgenic alopecia and plastic surgery. The dermatology segment is expected to grow at the highest CAGR from 2016 to 2021, owing to the increasing number of dermatological disorders.
Market related to Nanotechnology and medical devices: The global Plasma nanotechnology market is going to reach 90.5 billion dollars by 2021 from 39.2 billion dollars in 2016 at a compound annual growth rate (CAGR) of 18.2%, from 2016 to 2021. The global medical device coating market reached about 6.1 billion dollars in 2013. This market is expected to grow to 6.3 billion dollars in 2014 and 9 billion dollars in 2019, with a compound annual growth rate (CAGR) of 7.3% from 2014 to 2019 and the global market for applied plasma technologies is going to reach 6.5 billion dollars by 2021 from 4.4 billion dollars in 2016 at a compound annual growth rate (CAGR) of 8%, from 2016 to 2021.
Geographically from 2016 professional and in-depth research report on the world's major regional market conditions of the Plasma Display Panel industry, Plasma Mass Spectrometer, focusing on the main regions Europe; UK, France, Germany, Italy, Spain, Netherlands, Belgium, Switzerland, Austria, Portugal, Denmark, Finland, Norway, Sweden, Ireland, Russia, Turkey, Poland, Western Europe, Central and Eastern Europe North America: USA, Canada Asia Pacific: Japan, China, South Korea, Australia, New Zealand. Growth in the global market is primarily driven by the increase in aging population and rise in the number of orthopedic disorders. The report study of Plasma chemistry and treatment System in Europe market, especially in Germany, UK, France, Russia, Italy, Benelux and Spain, focuses on top players in these countries, with sales, price, and revenue and market share for each player in these Countries.
Applied Plasma Technologies:
Applied Plasma Technologies (APT) develops and manufactures plasma assisted combustion systems for reliable ignition, flame control, clean and stable combustion of different fuels in gas turbines, high speed propulsion systems, boilers, technological burners, flare stacks, chemical plants, landfills. APT also conducts research and development in some new fields as gaseous, liquid and solid fuels reformation and hydrogen production, high purity silicon production, waste into power processing, non-equilibrium plasma coating and surface treatment, plasma aerodynamics, air and water treatment, IC engine improvements.
Areas of plasma technology:
Plasma has achieved significant importance in a diversity of research and these plasmas are routinely used to clean and surface treat plastic automotive bumpers, performance textiles and filter media, stainless steel syringe needles, angioplasty balloon catheters, plastic lenses, Golf balls and many other diverse products. In fact, it would be difficult to identify a modern product that has not benefitted from plasma processing at some stage during its fabrication.
Chemistry of Plasma with liquids:
Plasma in liquids usually has high dielectric constants and high dielectric strength than gas phases which are useful in various biological, environmental and medical technologies. The process of using plasma in liquids is followed by electric breakdown of liquids is initiated by the application of high electric field on the electrode, followed by rapid propagation and branching of plasma channels. Typically plasmas are only considered to exist through the ionization of gases and typical production of plasmas in liquids generates bubbles through heating or via cavitation and sustains the plasmas within those bubbles.
Plasma chemistry is the branch of chemistry that studies chemical processes in low-temperature plasma, including the laws that govern reactions in plasma and the fundamentals of plasma chemical technology. Plasmas are artificially produced in plasmatrons at temperatures that range from 103 to 2 × 104 K and pressures that range from 10–6 to 104 atmospheres. Interaction between the reagents in plasma results in the formation of final, or terminal, products; these products can be removed from the plasma by rapid cooling, or quenching. The basic feature of all plasmochemical processes is that reactive particles are generated in significantly higher concentrations than under ordinary conditions of chemical reactions. The reactive particles that are produced in plasma are capable of effecting new types of chemical reactions; the particles include excited molecules, electrons, atoms, atomic and molecular ions, and free radicals. Indeed, some of these particles can only exist in the plasma state.
Plasma is a hot ionized gas consisting of approximately equal numbers of positively charged ions and negatively charged electrons. The characteristics of plasmas are significantly different from those of ordinary neutral gases so that plasmas are considered a distinct "fourth state of matter”. Plasmas are described by many characteristics, such as temperature, degree of ionization, and density, the magnitude of which, and approximations of the model describing them, gives rise to plasmas that may be classified in different ways.
Plasma diagnostics are a pool of methods, instruments, and experimental techniques used to measure properties of plasma, such as plasma components density, distribution function over energy (temperature), their spatial profiles and dynamics, which enable to derive plasma parameters. Plasma diagnostic techniques are also used to observe physical processes that reveal parameters that characterize plasma. These parameters include spatial and temporal distributions of constituent particle densities and temperatures and localized magnitudes of electric and magnetic fields. The techniques used include those that have applications in other areas of science and those that have been developed for their unique applications to plasmas.
Plasma Medicine and Plasma biology:
The number of potential applications of non-equilibrium atmospheric pressure discharges in biology and medicine has grown and activity in this direction lead to the formation of a new field in plasma chemistry titled 'Plasma Medicine'. Some examples of medical applications of plasma are the use of plasma in the treatment of dental cavities, sterilization of various surfaces, treatment of skin diseases, delicate surgeries and many other applications. It is now clear that these plasmas can have not only physical (e.g. burning the tissue) but also medically relevant therapeutic effects; plasmas can trigger a complex sequence of biological responses in tissues and cells. The development of actual commercial tools that will enter the hospital, and in finding novel and perhaps even unexpected uses of these plasmas, an understanding of the mechanisms of interaction of non-equilibrium gas discharges with living organisms, tissues and cells becomes essential.
Plasma Physics and controlled fusion:
Plasma physics is the branch of physics that deals with plasmas and their interactions with electric and magnetic fields of charged particles and fluids interacting with self-consistent electric and magnetic fields. It is a research that has many different areas of application such as space and astrophysics, controlled fusion, accelerator physics and beam storage.
Plasma processing is a plasma-based material processing technology that aims at modifying the chemical and physical properties of a surface. Plasma processing techniques include: Plasma activation, Plasma etching. Plasma processing of materials is also a processing technology which is used in aerospace, automotive, steel, biomedical, and toxic waste management industries it is also been utilized increasingly in the emerging technologies of diamond film and superconducting film growth.
Plasma spectroscopy is a study of electromagnetic radiation emitted from ionized media. The plasma will be considered to have a temperature and degree of ionization sufficiently high so that the radiation is due to atomic rather than molecular processes. In contrast to conventional spectroscopy where it is interested in the atomic structure of an isolated atom, the radiation from plasma depends, not only on the properties of the isolated radiating species, but also on the properties of the plasma in the immediate environment of the radiator. This dependence on the plasma properties is a consequence of the fact that ions and electrons interact with other species via the long-range Coulomb potential.
Plasma nanotechnology is a branch of technology that deals with dimensions and tolerances of less than 100 nanometers, especially the manipulation of individual atoms and molecules. Low-temperature plasmas find numerous applications in growth and processing of nanomaterial’s such as carbon nanotubes, inorganic nanowires and others. Nanotechnology and Nanomaterial’s are also key approaches to improve the performance of energy storage technologies.