Chemistry & Water Conferences- On behalf of Industrial Chemistry organizing committee, we warmly welcome analytical expertise researchers, professors, scientific communities, delegates, students, business professionals and executives to attend "21st International Conference on
Industrial Chemistry and Aqua Technology " which is to be held during November 23-24, 2020 at London, UK.
Industrial Chemistry 2020 is an international platform for presenting research about chemistry and related fields thus contributes to the dissemination of knowledge for the benefit of both the academia, chemical and water treatment business. This event brings together the top professionals in the chemistry and chemical engineering field along with the highly affiliated professors to explore the advancements and latest applications achieved in the field of Industrial chemistry, Water Treatment technology and reverse osmosis membrane technology. Industrial Chemistry 2020 discusses various fields of chemistry employed in Petroleum and Organic Industrial Chemistry, Industrial Polymers, Metals and Composites Chemistry, Industrial Processes, White biotechnology and Green Chemistry, Metallurgy and Material Science in Industrial Chemistry, Applied chemistry, Industrial Photo Chemistry, Pharmaceutical Chemistry, Clean water technology, Water Solutions and Strategies in chemical Industry, Reverse Osmosis and Nano filtration, Domestic Water Treatment, Desalination, Ultrapure Water Production, Industrial Water and Waste Water treatment, Boiler Water Treatment and Cooling Water Treatment, Applied Membranes and Nano membrane technology and chemical science fields which mark the support for the advanced and much needed research by their study on various topics. The scientific program will focus on current advances in the research in water treatment and use of chemistry and related with particular focus on its roles and applications in various fields and industries.
In the light of this theme, the Conference Series LLC Ltd aims to provide a forum for International Chemistry researchers from various areas of chemistry, pharmacy, water technologies and life science by providing a platform for critical analysis of new data, and to share latest cutting-edge research findings and results about all aspects of Industrial chemistry. Chemistry conferences provide a platform to detail the research work of expertise from various scientific backgrounds and the same can be perceived by young researchers and students.
Track 1: Industrial Chemistry
Industrial chemistry continues with the progress in science and technology. It incorporates other arise disciplines such as biotechnology, microelectronics, and pharmacology and material science. It deals with physical and chemical processes towards the transformation of raw materials into products that are of useful to humanity. Chemicals or commodity chemicals are a broad chemical category including polymers, bulk petrochemicals and intermediates, other derivatives and basic industrials, inorganic chemicals, and fertilizers. Major industrial customers include rubber and plastic products, textiles, apparel, petroleum refining, pulp and paper, and primary metals.
For more information, please visit Industrial Chemistry and Aqua Technology | Industrial Chemistry 2020
Track 2: Inorganic Chemistry
Inorganic chemistry is the study of the structures, properties, and behaviours of all chemical compounds, except the myriad organic compounds and behaviour of inorganic and
organometallic compounds. It is the study of the formation, synthesis and properties of chemical substances that do not having C-H bonds. Inorganic chemistry is related to other areas like materials sciences, mineralogy, thermodynamics, physical chemistry, spectroscopy, earth sciences and crystallography.
Track 3: Medicinal Chemistry
Medicinal chemistry in its most common practice on small organic molecules encompasses synthetic organic chemistry, aspects of natural products and computational chemistry in close combination with chemical biology, enzymology and structural biology, together aiming at the discovery and development of new therapeutic agents.Medicinal chemistry is focused on drug design, chemical synthesis and deals with the design, optimization and development of chemical compounds for use as drugs.
For more information, please visit Medicinal Chemistry | Industrial Chemistry 2020
Track 4: Analytical Chemistry
Analytical chemistry consists of classical, wet chemical methods and modern, instrumental methods. Classical qualitative methods use separations such as precipitation, extraction, and distillation. It is also focused on improvements in experimental design, chemo-metrics, and the creation of new measurement tools. Analytical chemistry plays an increasingly important role in the pharmaceutical industry. All chemical manufacturing produces waste products in addition to the desired substances, and waste disposal has not always been carried out carefully. The techniques of analytical chemistry are relied on heavily to maintain a benign environment.
For more information, please visit Analytical Chemistry | Industrial Chemistry 2020
Track 5: Organometallic Chemistry
Organometallic chemistry combines aspects of inorganic chemistry and organic chemistry. It is the study of compounds containing metal-element bonds that are largely covalent in character. Organometallic chemistry deals with the chemical compounds containing bonds between carbon and metal atoms. Metal-organic frameworks (MOFs) are materials in which metal-to-organic ligand interactions yield porous coordination networks with record-setting surface areas surpassing activated carbons and zeolites. De-localization of orbitals within the complex substances form conjugated systems of materials which lead to the derivation of chromophores used in synthetic processes. Diamond and carbon materials are widely used in the applications of organic synthesis from novel materials. Organometallic chemistry is the study of chemical compounds containing bonds between carbon and metal atoms.
For more information, please visit Organometallic Chemistry | Industrial Chemistry 2020
Track 6: Industrial Photochemistry
Photochemistry is the branch of chemistry concerned with the chemical effects of light. Synthesize photo stable compounds that are capable of converting absorbed light into heat with a high degree of efficiency. Industrial applications of photochemistry have so far been in the fields of freeâ€radical chlorination, sulfochlorination, sulfoxidation, and nitrosation. Photochemical reactions are being utilized on an increasing scale for the synthesis of vitamins, drugs, and fragrances.
For more information, please visit Industrial Photochemistry | Industrial Chemistry 2020
Track 7: Ultrapure Water Production
Ultra-pure water contains by definition only H20, and H+ and OH- ions in equilibrium. Therefore, ultrapure water conductivity is about 0,054 us/cm at 25oC, also expressed as resistivity of 18, 3 MOhm. Ultrapure water production often has to be done in 2 steps. For example, from tap water or fresh groundwater, the water should first be demineralized by membrane filtration or ion exchange to reach the ultimate conductivity of 10 us/cm. The demineralized water is then processed through a high performance Mixed Bed or by Electrodionisation. Ultra-pure water is mainly used in the semiconductor and pharmaceutical industry.
For more information, please visit Ultrapure Water Production | Industrial Chemistry 2020
Track 8: White Biotechnology and Green Chemistry
White Biotechnology can be regarded as Applied Bio catalysis, with enzymes and microorganisms, aiming at industrial production from bulk and fine chemicals to food and animal feed additives. White Biotechnology supports new applications of chemicals produced via biotechnology. The use of plant-based resources is one of the foundations of the concept of “green chemistry”. Many green chemistry processes make use of white biotechnology tools, and light will be shed on the importance of this technological synergy within the context of industry and factories in the future. In fact, biotechnology is a way of using biomass or its waste material renewably to produce molecules with high added value for different applications, ranging from pharmaceuticals, agro-food, and cosmetics to plastics, materials and energy.
For more information, please visit White Biotechnology and Green Chemistry | Industrial Chemistry 2020
Track 9: Petroleum and Polymer Processing
Petroleum geology is the study of origin, natural occurrence, movement, gathering and exploration of hydrocarbon fuels, especially oil or petroleum. Petroleum geology is a branch of stratigraphy that deals with the relationship between rock layers and the way they can move or shift. The movement of rock layers can affect the site of petroleum deposits, well as the removal of the petroleum. The major disciplines of include Source rock analysis, Basin analysis, exploration stage, Appraisal Stage, Production stage, Reservoir Analysis. Petroleum geologists study and explore the oil deposits and oil production. There are a variety of different processing methods used to convert resins into finished products. Some include: Extrusion Profile and Sheet extrusion, Pipe extrusion, Cast film extrusion, Blown film extrusion.
For more information, please visit Petroleum and Polymer Processing | Industrial Chemistry 2020
Track 10: Solid State Physics
Solid state physics is the study of rigid matter or solids, through methods such as quantum mechanics, crystallography and electromagnetism. It is the largest division of condensed matter physics. Solid-state physics studies how the large-scale properties of solid materials result from their atomic-scale properties. Thus, solid-state physics forms a theoretic basis of materials science.
For more information, please visit Solid State Physics | Industrial Chemistry 2020
Track 11: Biopolymers and Bio plastics
Polymeric biomolecules or
biopolymers are polymers fabricated by living organisms. Polynucleotides, Nucleotides and Polypeptides are the three main classes of polymers those are called long polymers. It also have short polymer of amino acids and polysaccharides which are frequently linear bonded polymeric carbohydrate structure for example examples: rubber, melanin and lignin. The difference between biopolymer and synthetic
polymer can be found in their structure .compare to biopolymer synthetic polymer has much simplest structure. This fact shows to a molecular mass distribution that is missing in biopolymers. All biopolymers are alike that they all contain the similar sequences and numbers of
monomers and thus all have the same mass.
Track 12: Lead Drug Discovery
The method by which a drug is delivered can have a significant effect on its efficacy. To minimize drug degradation and loss, to prevent harmful side-effects and to increase drug bioavailability and the fraction of the drug accumulated in the required zone, various drug delivery and drug targeting systems are currently under development. Attempts are being made to develop therapeutic proteins for cancer, hepatitis, and autoimmune conditions, but their clinical applications are limited, except in the cases of drugs based on erythropoietin, granulocyte colony-stimulating factor, interferon-alpha, and antibodies, owing to problems with fundamental technologies for protein drug discovery. Technologies profiled include those used for biomarker and target discovery such as high throughput screening, signal transduction, micro array, RNAi, metabolomics, toxicogenomics, biosensors and nanotechnology.
For more information, please visit Lead Drug Discovey | Industrial Chemistry 2020
Track 13: Nano Materials in Water Treatment
The most promising and well-developed environmental applications of
nanotechnology has been in water remediation and treatment where different nanomaterials can help purify water through different mechanisms including adsorption of heavy metals and other pollutants, removal and inactivation of pathogens and transformation of toxic materials into less toxic compounds. It highlights the uses of nanotechnology to purify water, including separation and reactive media for water filtration, as well as nanomaterial’s and nanoparticles for use in water bioremediation and disinfection. The most extensively studied nanomaterial; zero-valent metal
nanoparticles (Ag, Fe, and Zn), metal oxide nanoparticles (TiO2, ZnO, and iron oxides),
carbon nanotubes (CNTs), and nanocomposites.
Track 14: Desalination
Water desalination processes separate dissolved salts and other minerals from water. Seawater desalination has the potential to reliably produce enough potable water to support large populations located near the coast. The most common desalination methods employ reverse-osmosis in which salt water is forced through a membrane that allows water molecules to pass but blocks the molecules of salt and other minerals. Thermal desalination uses heat, often waste heat from plants or refineries, to evaporate and condense water to purify it. The cost is very high and so it cannot be afforded by everyone who needs it, but because the desalinisation technology is improving fast, so the costs are beginning to fall, making it more affordable to countries and islands that need it. Desalination techniques are also being developed on a much smaller scale. Portable desalination kits are a prime example. Desalination is becoming more economically viable as the technology improves. Desalination plants can be provided in a wide range of outputs to cater for small isolated communities or to contribute substantially to water supplies for large cities and even for irrigation.
For more information, please visit Desalination | Industrial Chemistry 2020
Track 15: Allotrope of Carbon
Graphene is a thin layer of pure carbon; it is a single, tightly packed layer of carbon atoms that are bonded together in a hexagonal honeycomb lattice. In more complex terms, it is an allotrope of carbon in the structure of a plane of sp2 bonded atoms with a molecule bond length of 0.142 nanometres. Layers of graphene stacked on top of each other form graphite, with inter planar spacing of 0.335 nanometres. Furthermore, the quality of the graphene that was separated by using this method was sufficiently high enough to create molecular electronic devices successfully. While this research is very highly regarded, the quality of the graphene produced will still be the limiting factor in technological applications. Once graphene can be produced on very thin pieces of metal or other arbitrary surfaces (of tens of nanometres thick) using chemical vapour disposition at low temperatures and then separated in a way that can control such impurities as ripples, doping levels and domain size whilst also controlling the number and relative crystallographic orientation of the graphene layers, then we will start to see graphene become more widely utilized as production techniques become more simplified and cost-effective.
For more information, please visit Allotrope of Carbon | Industrial Chemistry 2020
Track 16: Polymer Science
Polymer science is an interdisciplinary area comprised of chemical, physical, engineering, processing and theoretical aspects. It also has enormous impact on contemporary materials science. Its goal is to provide the basis for the creation and characterization of polymeric materials and an understanding for structure/property relationships. Polymer science is of increasing importance for everyone's daily life. Many modern functional materials, gears, and devices have polymers as integral parts. Not surprisingly, roughly 30% of all scientists in the chemical industry work in the field of polymers.
For more information, please visit Polymer Science | Industrial Chemistry 2020
Our Conference will provide a perfect platform addressing:
• Remarkable talks by the top-notch of the global scientific community
• Notable workshop sessions
• Significant awards and global recognition to meritorious researchers
• Global networking with 80+ countries
• Novel techniques to enhance your research
For more information drop a mail on industrialchemistry@brainstormingmeetings.com
Benefits for Delegates:
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Participation certification
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Opportunity of obtaining special waiver if they are attending the conference in group from same organization
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Networking and B2B meetings with the academic people attending the conference
Benefits of Attending Industrial Chemistry 2020:
1) Meet Experts & Influencers Face to Face
2) Networking Opportunities
3) New Tools, Innovation and ideas
4) Learning in a New Space
5) Break Out of Your Comfort Zone
6) New Tips & Tactics
7) The Serendipity of the Random Workshop
8) Invest In Yourself
For registration kindly visit: https://industrialchemistry.chemistryconferences.org/registration.php
Chemists
Professors in Chemistry
Associate and Assistant Professors in Chemistry
Post doctorals and Researchers in Chemistry
Heads of Chemical Departments
Post Graduates and Graduates in Chemistry
Pharmacologist
Laboratory Chemists
Chemical Scientists working on Materials
Experts in the development of Nanostructures
Industrial Polymer Companies
Pharmaceutical Companies
Junior/Senior research fellows of Pharmaceutical/Materials Science/ Nanotechnology/ Polymer Science
Chemistry Conferences: The global market analysis for chemicals and water treatment should reach $38.2 billion by 2021 from $28.5 billion in 2019 at a compound annual growth rate (CAGR) of 6.1%, from 2017 to 2021.
In 2019 market analysis for alternative U.S chemical end-use product market is expected to increase from $149.9 billion to an estimated $345.6 billion by 2021. In 2026 it should reach $884.1 billion, with a compound annual growth rate of 19.4% for the period of 2019-2026.
USA Industrial Chemistry: U.S. chemistry output is expected to rise 1.6% in 2019 and 3.7% in 2020. Chemical production will continue to grow across over all United States of America during 2019. In next five years, growth will occur in the Gulf Coast region, followed by the Ohio Valley. American chemistry revenues will more than $1.0 trillion by 2020.
USA chemical production-excluding production of the pharmaceuticals segment, which is expected to contract this year-will expand 2.7% this year, in 2017 4.1% and in 2018 5.0%. Including pharmaceuticals, the chemical industry will expand this year at a slightly lower 1.6%. In 2019 growth in production volumes will accelerate and the industry will expand 3.7% and In 2018 by another 4.5%. Capacity utilization is expected to tighten to 73.5% in 2018 and further to 73.3% in 2019.
Effects of renewed competitiveness from shale gas is experienced by U.S. basic chemicals, inorganic chemicals, petrochemicals, resins, synthetic rubber, Plastic, and manufactured fibres. Basic chemicals production is anticipated to grow 3.1% in 2019 and 4.9% in 2020. Production volume growth will exceed 5.0% per year during 2019 and 2020 by new capacity coming, followed by smaller gains in 2021 and 2022. Basic major role in expanding production play by chemicals, led by petrochemicals and organics as well as plastic resins. There will be strength in the production of inorganic chemicals, synthetic rubbers and manufactured fibres as well.
In the specialties chemicals segment, production will pick up by 1.5% in 2019, after contracting last year, and grow further by 3.4% in 2020.
USA Water Treatment: This statistic represents the revenue of the water utility industry in the United States between 2000 and 2010. In 2000, this particular industry generated revenue of approximately 29.9 billion U.S. dollars. Water is a prerequisite for economic development. Water as a resource for production focuses on the economic value of the natural resource water. Different types of industries demand different quantities of water resources, and produce and dispose of different kinds of wastewater. Agriculture uses 69% of the world's water withdrawal - including irrigation, livestock watering and cleaning, and aquaculture. The production of energy also requires water in processes such as thermal power plant cooling systems or lowering the water table for raw materials extraction.
FAO reports that global water withdrawal increased from 600 km3/year in 1900 to almost 4,000 km3/year in 2010. According to the OECD "Environmental Outlook to 2050", global demand for water is projected to increase by 55% between 2000 and 2050, mainly driven by a 400% increase in demand from the manufacturing sector. Proper water management for production purposes is getting more and more important as the manufacturing sector is just one of many stakeholders dependent on this natural resource. The report explores the main policy responses governments should consider to address the challenges of increased water demand.
Jobs:
Chemical industry adding jobs in the industry’s expansion continues to reverse a falling trend in employment. In 2016 0.8% growth was expected in the chemical industry employment. This trend is in contrast to continuous decline in employment from 1999 to 2011. Because chemical industry workers are among the highest paid in the manufacturing sector, growing payrolls will strengthen local economies.
Chemical industry capital spending in the U.S. surged 12.1% in 2014 and gained 21.0% in 2015, reaching $43.58 billion. During 2015, chemistry accounted for one-half of total construction spending by the manufacturing sector. Despite the hindrance of slow global growth, uncertainty and U.S. tax policies that discourage business investment, these strong gains in capital spending for American chemistry are expected to continue. U.S. chemical industry capital spending will increase by 10.4% this year; 7.8% in 2017; 7.2% in 2017; and the year-over-year gains will remain above 6.0% until 2020.
Expansions will continue and investments to improve operating efficiencies will play a role as well. By 2021, Chemical industry will reach $65 billion by U.S. capital spending—more than triple the level of spending at the start of this prolonged cycle in 2010.
Capital spending for bulk petrochemical and for organic intermediates, along with spending for plastic resins, will advance from less than 29% of the total to 52% in 2021.
By rising 2% to $132 billion, the trade excess in chemicals (excluding pharmaceuticals) will grow to $36 billion in this year and imports hold steady at $96 billion. Two-way trade between the U.S. and its foreign partners will reach $227 billion this year and will grow steadily over the coming years.
Societies Associated with Industrial Chemistry and Aqua Technology:-
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Food and Agriculture Organization of the United Nations, USA
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Andalusia Centre for Marine Science and Technology, Spain
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International union of Crystallography
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International Organisation of Materials
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Metals and Minerals Societies
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Japan Society for Composite Materials
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National Oceanic and Atmospheric Administration
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Society for Biomaterials
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Society for Advancement of Material and process Engineering
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Food and Agriculture Organization of the United Nations, USA
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American Ceramic Society
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American Composites Manufacturers Association
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Fisheries Research Services Marine Laboratory, UK
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Australasian Society for Biomaterials and Tissue Engineering
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Aquaculture Association of Canada,
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Canadian Biomaterials Society
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Federation of European Materials Societies
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Korea Institute of Maritime and Fisheries Technology, South Korea
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International Union of Crystallography
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International Organization of Materials
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Metals and Minerals Societies
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Egyptian Aquaculture Society, Egypt
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Spanish Aquaculture Association (SEA), Spain
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China Society of Fisheries, China
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Aquaculture Association of S. Africa, South Africa
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European Aquaculture Society, Europe
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Brazilian Aquaculture Society (AQUABIO), Brazil
