On behalf of 7th World Congress on Chemistry 2017organizing committee invites analytical expertise, chemistry people in all fields, researchers, professors, scientific communities, delegates, students, business professionals and executives to attend to attend the“7th World Congress on Chemistry” which is to be held during November 13-15,2017 Athens , Greece
Chemistry Conferences is a global platform to discuss and learn about Analytical chemistry, Electrochemistry, Quantum Chemistry, Organometallic chemistry, Physical organic chemistry, Polymer chemistry, Bio inorganic chemistry, Materials chemistry, Environmental chemistry, Supra molecular chemistry, Inorganic Chemistry, Green Chemistry Green chemical principles, Medical Biochemistry, Physical Chemistry, Biological Chemistry, Theoretical Chemistry. Chemistry Meeting would discuss various topics related to Biochemistry, Petrochemicals, Nuclear chemistry, Polymer chemistry, Pharmacognosy & Phytochemistry, Stereochemistry, Clinical chemistry, Medicinal& pharmaceutical chemistry, Industrial chemistry and Environmental Chemistry.
The conference provides the analysis works of chemistry experience from numerous scientific backgrounds and also the same are often perceived by young researchers and students. Chemistry Conferences chiefly aims to promulgate information in analysis and advances in chemical techniques. Each life sciences and chemical sciences want chemical techniques in course of analysis work and thus Chemistry Meeting would be an ideal venue to share and develop information on key chemistry tools.
The Chemistry meeting aims to explore the crown researches in the enormous field of chemistry and allied academies. Chemistry being the basis of life is an integral part in every different science from Life science to Rocket Science. The vast scope of chemistry keeps building every single minute all around the world with a new polymorph or molecule or a synthetic process. These researches when discussed can enlighten many young minds in performing more quality oriented research. Chemistry World 2017 provides a perfect platform to bring out such quality research works.
Allied Academics proudly announces the “7th World Chemistry Conference” during November 13-15, 2017 in Athens, Greece. This includes prompt keynote presentations, Oral talks, Poster presentations and Exhibitions.
Chemistry volumes continue to rise in the U.S. and chemical market expected to contract this year—As a result, chemical industry capital spending in the U.S. surged 12.1% in 2014 and gained 21.0% in 2015, reaching $43.58 billion and accounting for more than one-half of total construction spending by the manufacturing sector. The chemical association representing US-based chemical producers said that US chemical production (excluding pharmaceuticals) is expected to realize overall growth of 1.6% in 2016, followed by 4.1% growth next year, and 5.0% in 2018. Average annual gains of over 8% per year in U.S. Chemical industry capital spending are expected through 2018 with only a minor slowdown in subsequent growth expected. By 2021, ACC expects capital spending to reach $70 billion, contributing to four consecutive years of job growth in the industry. American chemistry revenues will exceed $1.0 trillion by 2020. Chemistry Council stated that more than 275 new chemical production projects had been announced since 2010 with a total value of more than $170 billion, with a full 49% already complete or under construction; 61% of these are foreign direct investment. By 2021, U.S. capital spending by the chemical industry will reach $65 billion—more than triple the level of spending at the start of this prolonged cycle in 2010. The trade surplus in chemicals (excluding pharmaceuticals) will grow to $36 billion this year as exports rise by 2% to $132 billion 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.
The way toward segregating particular mixes, recognizing those mixes, and deciding the amount of the mixes are in an item. Investigative science is utilized as a part of a wide range of zones of science. Systematic science can be partitioned into sub disciplines in light of the kind of tests that are broke down: nuclear, sub-atomic, or organic. Nuclear examination includes the recognizable proof and evaluation of components that regularly happen in complex blends. Expository scientific experts utilize an assortment of synthetic and physical techniques to decide personality and focus. Simply concoction techniques were created in the nineteenth century and in this manner are called traditional strategies. Physical techniques include judgments in view of the measure of light retained or discharged by the analyte or on the quality of an electrical flag made by the analyte at a cathode.
The use of the standards and speculations of science to answer a particular question or take care of a true issue, rather than immaculate science, which is gone for improving learning inside the field. Connected Chemistry gives advancements to applications as well as spreads a basic part of science. We are, consequently, intending to make a novel arrangement of learning by researching and comprehension the major way of materials and to manufacture helpful materials by planning new structures and controlling their properties. At present, as the human culture is more confused, the exploration fields of Applied Chemistry are growing to a more extensive territory.
Chemical education and chemical science:
There is a constant need to update the skills of teachers engaged in teaching chemistry, so chemistry education speaks to this need. There are at least four different philosophical perspectives that describe how the work in chemistry education is carried out. The first is what one might call a practitioner’s perspective, wherein the individuals who are responsible for teaching chemistry (teachers, instructors, professors) are the ones who ultimately define chemistry education by their actions. Chemistry education or chemical education is the study of the teaching and learning of chemistry in all schools, colleges and universities. Topics in chemistry education might include understanding how students learn chemistry, how best to teach chemistry, and how to improve learning outcomes by changing teaching methods and appropriate training of chemistry instructors, within many modes, including classroom lecture, demonstrations, laboratory activities and it also includes Research, reviews of research, in chemistry education Evaluations of effective innovative practice in the teaching of chemistry and In-depth analyses of issues of direct relevance to chemistry education.
Atmospheric Chemistry & Geo chemistry:
Geochemists are increasingly in demand to study The composition and chemistry of the Earth's atmosphere is of importance for several reasons, but primarily because of the interactions between the atmosphere and living organisms. The composition of the Earth's atmosphere changes as result of natural processes such as volcano emissions, lightning and bombardment by solar particles from corona. It has also been changed by human activity and some of these changes are harmful to human health, crops and ecosystems. Examples of problems which have been addressed by atmospheric chemistry include acid rain, ozone depletion, photochemical smog, greenhouse gases and global warming.
Biochemistry is closely related to molecular biology, the study of the molecular mechanisms by which genetic information encoded in DNA is able to result in the processes of life. Depending on the exact definition of the terms used, molecular biology can be thought of as a branch of biochemistry, or biochemistry as a tool with which to investigate and study molecular biology The present and the future role of biochemistry in the search for a new therapeutic agent is reviewed. It is stated that the great importance of the various disciplines of biochemistry, including patho-biochemistry and pharmacological biochemistry, is presently recognized, and the involvement of biochemistry in drug research is increasing.
Chemistry and water treatment:
Water is perhaps the most important nutrient in our diets. In fact, a human adult needs to drink approximately 2 litters (8 glasses) of water every day to replenish the water that is lost from the body through the skin, respiratory tract, and urine. But some water sources cannot safely be used to meet our requirement for drinking water. In fact, 99.7% of the Earth's water supply is not usable by humans. This unusable water includes saltwater, ice, and water vapour in the atmosphere. Only freshwater, which is contained in rivers, lakes, and underground sources, can be used for human consumption. Furthermore, many freshwater sources are not suitable for humans to drink. Many serious diseases, such as cholera, are caused by drinking water that contains parasitic microorganisms. Water containing large amounts of industrial waste or agricultural chemicals (e.g., pesticides) can also be toxic and unfit for drinking. Hence, humans have a great need for a reliable source of clean freshwater for drinking. Water treatment is a process of making water suitable for its application or returning its natural state. Thus, water treatment required before and after its application. The required treatment depends on the application. For example, treatment of grey water (from bath, dish and wash water) differs from the black water (from flush toilets). Composting toilet is not allowed in urban dwelling. Yet, composting toilets are used in a 30,000-square-foot office complex at the Institute of Asian Research, University of British Columbia. Water treatment involves science, engineering, business, and art. The treatment may include mechanical, physical, biological, and chemical. As with any technology, science is the foundation, and engineering makes sure that the technology works as designed. The appearance and application of water is an art.
Clinical chemistry is that field of clinical pathology involved with analysis of body fluids. The discipline originated within the late nineteenth century with the use of simple chemical tests for diverse elements of blood and waste product. After this, totally different clinical biochemistry techniques were applied at the side of the use and live of catalyst activities, spectrophotometry, action, and biological assay. Endocrine pathology is that the subspecialty of surgical pathology that deals with the diagnosing and characterization of growth and non-neoplastic diseases of organs of the system, as well as the thyroid, parathyroid gland, secreted exocrine gland, and adrenal glands
Electrochemistry is the study of chemical processes that cause electrons to move. This movement of electrons is called electricity, which can be generated by movements of electrons from one element to another in a reaction known as an oxidation-reduction reaction. The chemical industry makes use of electrolysis, which is the most important process for the production of chlorine, alkalis, many oxidizing agents, fluorine, and organo-fluorine compounds.
Food chemistry and agricultural chemistry:
Food chemistry is the study of the chemical composition, processes and interactions of all biological and non-biological components of foods. It includes macro- and micronutrients, and the essential nutritional factors that determine the nutritional and energy value of food raw materials and foods. It also includes reactions related to amino acids, peptides and proteins, fats and other lipids, carbohydrates, vitamins, mineral substances and water which are responsible for odour, taste and colour that determine the quality of food materials and foods. Agricultural chemistry must be considered within the context of the soil ecosystem in which living and non-living components interact in complicated cycles that are critical to all living things. Carbon inputs from photosynthetic organisms ultimately provide the fuel for many soil organisms to grow and reproduce. Soil organisms, in turn, promote organic carbon degradation and catalyze the release of nutrients required for plant growth.
Industrial Chemistry is the branch of chemistry which applies physical and chemical processes towards the transformation of raw materials into products that are of benefit to humanity. The design of chemical processes and improving the conditions for production. It's about taking projects from inception as a research proposal, through product development and on to commercialisation and manufacture. Industrial chemists make use of their broad understanding of chemistry and environmental sustainability at pharmaceutical companies, in polymer manufacturing, petrochemical processing, in the manufacturing industries and in food science. Yet they can also be found in the most unexpected places; like challenging the norm in cutting edge research. Polymers and plastics, especially polyethylene, polypropylene, polyvinyl chloride, polyethylene terephthalate, polystyrene and polycarbonate comprise about 80% of the industry’s output worldwide These materials are often converted to fluoropolymer tubing products and used by the industry to transport highly corrosive materials. Chemicals are used to make a wide variety of consumer goods, as well as thousands of inputs to agriculture, manufacturing, construction, and service industries. The chemical industry itself consumes 26 percent of its own output. Major industrial customers include rubber and plastic products, textiles, apparel, petroleum refining, pulp and paper, and primary metals. Chemicals are nearly a $3 trillion global enterprise, and the EU and U.S. chemical companies are the world's largest producers.
Materials science and engineering, involves the discovery and design of new materials, with an emphasis on solids. The intellectual origins of materials science stem from the Enlightenment, when researchers began to use analytical thinking from chemistry, physics, and engineering to understand ancient, phenomenological observations in metallurgy and mineralogy. Materials science still incorporates elements of physics, chemistry, and engineering. As such, the field was long considered by academic institutions as a sub-field of these related fields. Materials scientists emphasize understanding how the history of a material (its processing) influences its structure, and thus the material's properties and performance. Materials science is also an important part of forensic engineering and failure analysis - investigating materials, products, structures or components which fail or which do not operate or function as intended, causing personal injury or damage to property. Such investigations are key to understanding, for example, the causes of various aviation accidents and incidents. The basis of materials science involves studying the structure of materials, and relating them to their properties. Once a materials scientist knows about this structure-property correlation, they can then go on to study the relative performance of a material in a given application. The major determinants of the structure of a material and thus of its properties are its constituent chemical elements and the way in which it has been processed into its final form. These characteristics, taken together and related through the laws of thermodynamics and kinetics, govern a material's microstructure, and thus its properties.
Medicinal chemistry deals with the design, optimization and development of chemical compounds for use as drugs. It is inherently a multidisciplinary topic beginning with the synthesis of potential drugs followed by studies investigating their interactions with biological targets to understand the medicinal effects of the drug, its metabolism and side-effects. At the biological interface, medicinal chemistry combines to form a set of highly interdisciplinary sciences, setting its organic, physical, and computational emphases alongside biological areas such as biochemistry, molecular biology, pharmacognosy and pharmacology, toxicology and veterinary and human medicine; these, with project management, statistics, and pharmaceutical business practices, systematically oversee altering identified chemical agents such that after pharmaceutical formulation, they are safe and efficacious, and therefore suitable for use in treatment of disease.
It is the field of organic chemistry, the definition of natural products is usually restricted to mean purified organic compounds isolated from natural sources that are produced by the pathways of primary or secondary metabolism. The art or practice of using herbs and herbal preparations to maintain health and to prevent, alleviate, or cure disease and a plant or plant part or an extract or mixture of these used in herbal medicine by the Plant extraction method of drug formulation. Herbal and drug interaction and evaluation, in which the herbal drug is used to diagnose, cure, treat, or prevent disease. Drug therapy is an important part of the medical field and relies on the science of pharmacology for continual advancement and on pharmacy for appropriate management of Herbal drugs/compounds discovery and development. A pharmacological study of Natural herbal products is a method of using natural herbs and plants to promote physical, emotional, and spiritual health. Individuals interested in studying herbal pharmacology at the clinical level of alternative medicine.
Neurochemistry is the study of neurochemicals, including neurotransmitters and other molecules such as psychopharmaceuticals and neuropeptides, that influence the function of neurons. This field within neuroscience examines how neurochemicals influence the operation of neurons, synapses, and neural networks. Neuro chemists analyze the biochemistry and molecular biology of organic compounds in the nervous system, and their roles in such neural processes as cortical plasticity, neurogenesis, and neural differentiation. The market analysis of neurology speaks to the largest and untapped market in medicine sector. This estimated market analysis is depends on probability of approval and sales of products in late stage improvement, demographic trends and promoting of product. Emerging and developing markets once again helps to boost revenues. CNS therapeutics involves roughly 15% of aggregate pharmaceutical deals, about $30 billion around the world.
Compounds used as medicines are most often organic compounds, which are often divided into the broad classes of small organic molecules (e.g., atorvastatin, fluticasone, clopidogrel) and "biologics" (infliximab, erythropoietin, insulin glargine), the latter of which are most often medicinal preparations of proteins (natural and recombinant antibodies, hormones, etc.). Inorganic and organometallic compounds are also useful as drugs (e.g., lithium and platinum-based agents such as lithium carbonate and cis-platin as well as gallium)
Physical chemistry & theoretical chemistry:
It provides explanations to the chemical and physical observations of molecules. For example, some theoretical methods, such as density functional theory, may not be appropriate to solve magnetic coupling or electron transitions properties Physical chemistry is the study of macroscopic, atomic, subatomic, and particulate phenomena in chemical systems in terms of the principles, practices and concepts of physics such as motion, energy, force, time, thermodynamics, quantum chemistry, statistical mechanics, analytical dynamics and chemical equilibrium
Polymer chemistry is concerned with the chemical synthesis and chemical properties of polymers. Polymer chemistry is a multidisciplinary science that deals with the chemical synthesis and chemical properties of polymers which were considered as macromolecules. Polymers are huge macromolecules composed of repeating structural units. While polymer in popular usage suggests plastic, the term actually refers to a large class of natural and synthetic materials.
Sustainable chemistry and chemical engineering:
Sustainable chemistry is a scientific concept that seeks to improve the efficiency with which natural resources are used to meet human needs for chemical products and services. Sustainable chemistry encompasses the design, manufacture and use of efficient, effective, safe and more environmentally benign chemical products and processes. Chemistry and chemical engineering focused on the designing of products and processes that minimize the use and generation of hazardous substances . industry will reach $65 billion—more than triple the level of spending at the start of this prolonged cycle in 2010. The trade surplus in chemicals (excluding pharmaceuticals) will grow to $36 billion this year as exports rise by 2% to $132 billion 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.