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Chemical Engineering Congress 2020

About Conference


Chemical Engineering Congress is proud to announce that 7th World Congress On Chemical Engineering and Catalysis ,  is going to be held at Florence, Italy during April 20-21, 2020.

On this great gathering, Organizing Committee invites participants from all over the globe to take part in this annual conference with the theme “Exploring the Design, Optimization and Control of Chemical and Industrial Systems” aims at sharing new ideas and new technologies amongst the professionals, industrialists and students from research areas of chemical engineering to share their recent innovations and applications and indulge in interactive discussions and technical sessions at the event. The conference will also have a space for companies and/or institutions to present their services, products, innovations and research results. 

 Chemical Engineering Congress 2020 involves the tracks like chemical engineering, advanced chemical engineering thermodynamics, Physical-organic chemistry, Chemical Reaction Engineering, Biotechnology and Biochemical engineering, Heat transfer and Mass transfer operations, fluid Mechanics, Material Science and Engineering, Polymer Science and  Technology, Nano chemistry and Nanotechnology, Transport Phenomena and IPC, Modelling Simulation And Optimization, Industrial Safety and pollution control, Chemical Industry and Market Analysis.

Importance and Scope:

Chemical Engineering and Catalysis plays a vital role in our lives because of its uniqueness in properties and extended application in various industries. These are the basis of modern science and technology. Chemical Engineering is at the heart of many technological developments that touch our lives and find applications synthetic replacement for those resources as well as materials that are low in supply. In overall, it can be said that chemical engineers will be able to make very crucial contributions to the improvement in addition to the maintenance of the quality of our lives. Chemical Engineering techniques are used to produce usable, high quality products such as fibres, fabrics, paints, medical drugs, biomaterials, gasoline, lubricants etc used in various industries such as textile, food, plastics, automotive, aerospace, petroleum, oil and gas, biomedical, biotechnology and pharmaceuticals, thereby increasing the scope of Chemical Engineering.

Why to attend???

 Chemical Engineering Congress 2020 which is going to be the biggest conference dedicated to Chemical Engineering and Catalysis professionals providing a premier technical forum for reporting and learning about the latest new generation technologies developed during time along with discussing their applications. Events include hot topics presentations from all over the world and professional networking with industries, leading working groups and panels.

Meet Your Objective Business Sector With individuals from and around the globe concentrated on finding out about Chemical Engineering, this is the best chance to achieve the biggest collection of members from everywhere throughout the World. Conduct shows, disperse data, meet with current, make a sprinkle with another product offering, and get name acknowledgment at this occasion. Widely acclaimed speakers, the latest methods, strategies, and the most up to date overhauls in Chemical Engineering are signs of this meeting.

Target Audience:

  • Professors.
  • Scientists.
  • Research Scholars and students
  • Nanotechnology Companies
  • Chemical Related Companies
  • Biotech Related professors
  • Biotech Related Companies
  • Biotech Companies Staff
  • Nanotechnology Associations
  • Advanced Materials and Nanotechnology Engineers
  • Pharma Companies
  • Cement Companies Staff

 

 

 

Tracks/Sessions

Track 1: Chemical Engineering: A Unit Operation

Chemical Engineering is a multi-disciplinary branch of engineering in which Designing, manufacturing and operating plants and machinery for carrying out large-scale industrial, chemical, biological or related processes  or Developing new substances for a wide range of products combines natural and experimental sciences (such as chemistry and physics), along with life sciences (such as biology, microbiology and biochemistry) plus mathematics and economics to design, develop, produce, transform, transport, operate and manage the industrial processes that turn raw materials into valuable products. Many of the processes within chemical engineering involve chemical reactions, and the field takes cues from chemists who are looking for new ways to create products and to investigate the mechanisms within chemical reactions. Chemical engineers then translate this chemical information to formulate designs.

Chemical engineers may be specialized in one or the other subgroup but work from both sides will be required to create a final product. They will need to consider economic viability, management of resources, health and safety, sustainability and environmental impact.

Related societies and associations

Society of Chemical Engineers, Thai Institute of Chemical Engineering and Applied Chemistry, Renewable Fuels Association, World Bioenergy Association, AEBIOM European Bioenergy Association, The Bioenergy Association of Finland.

Recommended Conferences: Chemical Engineering Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 2: Process Heat Transfer

Heat Transfer is the process of transfer of heat from high temperature reservoir to low temperature reservoir. In terms of the thermodynamic system, heat transfer is the movement of heat across the boundary of the system due to temperature difference between the system and the surroundings. The heat transfer can also take place within the system due to temperature difference at various points inside the system. The difference in temperature is ‘potential’ that causes the flow of heat and the heat itself is called as flux.

Heat exchangers are devices built for efficient heat transfer from one fluid to another. They are widely used in engineering processes and include examples such as intercoolers, preheaters, boilers and condensers in power plants. Heat exchangers are becoming more and more important to manufacturers striving to control energy costs.

Related societies and associations

Society of Chemical Engineers, Thai Institute of Chemical Engineering and Applied Chemistry, Renewable Fuels Association, World Bioenergy Association, AEBIOM European Bioenergy Association, The Bioenergy Association of Finland.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 3: Chemical Reaction Engineering and Catalysis

Chemical Reaction Engineering and Catalysis is the field that studies the rates and mechanisms of chemical reactions and the design of the reactors in which they take place. Every industrial chemical process is designed to produce economically a desired product from a variety of starting materials through a succession of treatment steps.

Related societies and associations

Society of Chemical Engineers, Thai Institute of Chemical Engineering and Applied Chemistry, Renewable Fuels Association, World Bioenergy Association, AEBIOM European Bioenergy Association, The Bioenergy Association of Finland.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 4: Mass Transfer as Separation Processes

The driving force for mass transfer is typically a difference in chemical potential, when it can be defined, though other thermodynamic gradients may couple to the flow of mass and drive it as well. A chemical species moves from areas of high chemical potential to areas of low chemical potential. Mass transfer is used by different scientific disciplines for different processes and mechanisms. Mass transfer occurs in many processes, such as absorption, evaporation, drying, Crystallization, membrane filtration, and distillation. Distillation is a widely used method for separating mixtures based on differences in the conditions required to change the phase of components of the mixture. Absorption is the process in which a fluid is dissolved by a liquid or a solid (absorbent). Adsorption is the process in which atoms, ions or molecules from a substance (it could be gas, liquid or dissolved solid) adhere to a surface of the adsorbent.

 Related societies and associations

Brazilian Association of Chemical Engineering, Colombian Association of Chemical Engineering, Environmental and Energy Study Institute, American Biomass Association,  Bioenergy Association of California, American Solar Energy Society (ASES).

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 5: Oil, Gas and Petroleum Refineries

Oil refinery or petroleum refinery is an industrial process plant where crude oil is transformed and refined into more useful products such as petroleum naphtha, gasoline, diesel fuel, asphalt base, heating oil, kerosene, liquefied petroleum gas, jet fuel and fuel oils. Petrochemicals feed stock like ethylene and propylene can also be produced directly by cracking crude oil without the need of using refined products of crude oil such as naphtha.

Related societies and associations

The Royal Australian Chemical Institute, International Plasma Chemistry Society, Belgian Society of Biochemistry  Belgium, Canadian Society for Chemical Technology Canada, Chinese-American Chemical Society China, Society of Chemical Engineers New Zealand.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 6: Green Energy and Biomass

Biomass is an industry term for getting energy by burning wood, and other organic matter. Burning biomass releases carbon emissions but has been classed as a renewable energy source in the EU and UN legal frameworks, because plant stocks can be replaced with new growth. Forest-based biomass has recently come under fire from several environmental organizations, including Greenpeace and the Natural Resources Défense Council, for the harmful impacts it can have on forests and the climate. Greenpeace recently released a report entitled "Fuelling a Biomes" which outlines their concerns around forest-based biomass. Because any part of the tree can be burned, the harvesting of trees for energy production encourages whole-tree harvesting. Green energy comes from natural sources such as sunlight, wind, rain, tides, plants, algae and geothermal heat. These energy resources are renewable, meaning they're naturally replenished. In contrast, fossil fuels are a finite resource that take millions of years to develop and will continue to diminish with use.

Related Societies and Associations

Argentinian Association for Chemical Engineers, Indian Institute of Chemical Engineers (IIChe), Bio Energy Council of India, Central Leather Research Institute (CSIR), Bioenergy Association of New Zealand, Asia-Pacific Biomass Energy Technology

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 7: Chemical Engineering Thermodynamics

In general change of state of a thermodynamic system results from existence of gradients of various types within or across its boundary. Thus, a gradient of pressure results in momentum or convective transport of mass. Temperature gradients result in heat transfer, while a gradient of concentration promotes diffusive mass transfer. Thus, if internal or cross-boundary gradients of any form as above exist with respect to a thermodynamic system it will undergo change of state in time. The result of all such changes is to annul the gradient that in the first place causes the changes. This process will continue till all types of gradients are nullified.

Related Societies and Associations

World Chemical Engineering Council, Brazilian Association of Chemical Engineering, Bio Energy Association, World Biogas Association, Society of Agricultural and Biological Engineers,  America American Chemical Society, America

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 8: Electrochemistry and Electrochemical Engineering

Electrochemical Engineering combines the study of heterogeneous charge transfer at electrode/electrolyte interphases with the development of practical materials and processes. Fundamental considerations include electrode materials and the kinetics of redox species. Electrochemical Engineering is applied in industrial water electrolysis, electrolysis, electrosynthesis, electroplating, fuel cells, flow batteries, decontamination of industrial effluents, electrorefining, electrowinning.

Many natural phenomena are depending on Electrochemical Methods, such as the corrosion of metals, the ability of some sea creatures to produce electrical fields, and the workings of the nervous systems of humans and other animals. They also play an important part in modern Chemical technology, most prominently in the storage of electrical power in batteries, and the electrochemical process called electrolysis is important in modern industry. Neurons use electrochemical processes to transmit data through the nervous system, allowing the nervous system to communicate with itself and with the rest of the body. The electrochemical instruments market is segmented based on products, methodologies, end user, and region. The global electrochemical instruments market was valued at $1,713.0 Million in 2014 and is poised to increase at a CAGR of 5.2% during the forecasted period.

The methods of each Electrochemical instrument are accomplished for a specific purpose they are all bound together by fundamental principles that govern the operation. Collectively known as the principles of Electrochemical Engineering includes transport processes, current and potential distribution phenomena, thermodynamics, kinetics, scale-up, sensing, control, and optimization.

Related Societies and Associations

Federation of European Biochemical Societies, British Plastics Federation, The polymer society, Polymer processing society, American Chemical Society, American Physical Society.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 9: Material Science and Engineering

Material Science and Engineering involves the discovery and design of new materials.  Many of the most pressing scientific problems humans currently face is due to the limitations of the materials that are available and, as a result, major breakthroughs in materials science are likely to affect the future of technology significantly. Materials scientists lay stress on understanding how the history of a material influences its structure, and thus its properties and performance. All engineered products from airplanes to musical instruments, alternative energy sources related to ecologically-friendly manufacturing processes, medical devices to artificial tissues, computer chips to data storage devices and many more are made from materials. 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.

The interdisciplinary field of Materials Science, also commonly termed 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.

Related Societies and Associations

Federation of European Biochemical Societies, British Plastics Federation, The polymer society, Polymer processing society, American Chemical Society, American Physical Society.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 10: Polymer Science and Engineering

Polymer Science and Engineering is an engineering field that designs, analyses, or modifies polymer materialsA Polymer is a large molecule or a macro molecule which essentially is a combination of many sub units. The term polymer in Greek means ‘many parts.

Polymers have the capacity to solve most of the world's complex problems like Water purification, energy management, oil extraction and recovery, advanced coatings, myriad biomedical applications, building materials, and electrical applications virtually no field of modern life would be possible without polymeric materials. Polymer chemistry is combining several specialized fields of expertise. It deals not only with the chemical synthesis, Polymer Structures and chemical properties of polymers which were esteemed by Hermann Staudinger as macromolecules but also covers other aspects of Novel synthetic and polymerization methods, Reactions and chemistry of polymers, properties and characterization of polymers, Synthesis and application of polymer bio conjugation and Polymer Nano composites and architectures. Polymers are a highly diverse class of materials which are available in all fields of engineering from avionics through biomedical applications, drug delivery system, bio-sensor devices, tissue engineering, cosmetics etc. and the improvement and usage of these depends on polymer applications and data obtained through rigorous testing. The application of polymeric materials and their composites are still increasing rapidly due to their below average cost and ease of manufacture.

Related Societies and Associations

Association for the Development of Biomaterials, The Scandinavian Society for Biomaterials, Polymer Division of the Royal Australian Chemical Institute, The polymer society, Polymer processing society

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 11: Nano-Chemistry and Nanotechnology

Nano-Chemistry be characterized by concepts of size, shape, self-assembly, defects and bio-Nano; So, the synthesis of any new Nano-construct is associated with all these concepts. Nano-construct synthesis is dependent on how the surface, size and shape will lead to self-assembly of the building blocks into the functional structures; they probably have functional defects and might be useful for electronic, photonic, medical or bioanalytical problems. Nano Materials and Nanoparticle examination is right now a region of serious experimental exploration, because of a wide range of potential applications in biomedical, optical, and electronic fields. Nanotechnology is helping to considerably develop, even revolutionize, different technology and industry sectors: information technology, Renewable energy, environmental science, medicine, homeland security, food safety, and transportation, among others. Regenerative nanomedicine is one of the medical applications of nanotechnology. It ranges from the medical applications of nanomaterials to Nanoelectronics biosensors, and the future applications of molecular nanotechnology, such as biological machines. Nanomedicine sales reached $16 billion in 2015, with a minimum of $3.8 billion in nanotechnology R&D being invested every year.

Related Societies and Associations

American Coatings Association, American Chemical Society, Nigerian Society of Chemical Engineers, Israel Institute of Chemical Engineers, French Society of Process Engineering, Korean Chemical Society.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 12: Transport Phenomena And IPC

The study of Transport Phenomena concerns the exchange of mass, energy, charge, momentum and angular momentum between observed and studied systems. Transport phenomena involve fluid dynamics, heat transfer and mass transfer, which are governed mainly by momentum transfer, energy transfer and transport of chemical species respectively. Models often involve separate considerations for macroscopic, microscopic and molecular level phenomena. Modelling of transport phenomena requires therefore requires an understanding of applied mathematics. Transport phenomena have wide application. For example, in solid state physics, the motion and interaction of electrons, holes and phonons are studied under "transport phenomena". Another example is in biomedical engineering, where some transport phenomena of interest are thermoregulation, perfusion, and microfluidics. In chemical engineering, transport phenomena are studied in reactor design, analysis of molecular or diffusive transport mechanisms, and metallurgy.

Instrumentation is defined as the art and science of measurement and control of the process variables within a production or manufacturing area. The process variables used in industries are Level, Pressure, Temperature, Humidity, Flow, pH, Force, Speed etc

Control Engineering or control systems engineering is the engineering discipline that applies control theory to design systems with desired behaviours.

Instrumentation and Control plays a significant role in both gathering information from the field and changing the field parameters, and as such are a key part of control loops. The Instrumentation Technology, being an inter-disciplinary branch of engineering, is heading towards development of new & intelligent sensors, smart transducers, MEMS Technology, Blue tooth Technology.

Related Societies and Associations

Polymer Division of the Royal Australian Chemical Institute, Association for the Development of Biomaterials, Biochemical Society, Belgium,, Danish Chemical Society, Korean Chemical Society, Norwegian Chemical Society.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 13: Modelling Simulation and Optimization

Modelling and Simulation is the use of models – physical, mathematical, or otherwise logical representation of a system, entity, phenomenon, or process – as a basis for simulations – methods for implementing a model over time – to develop data as a basis for managerial or technical decision making. Using simulations is generally cheaper, safer and sometimes more ethical than conducting real-world experiments. Simulation-based optimization integrates optimization techniques into simulation analysis. Because of the complexity of the simulation, the objective function may become difficult and expensive to evaluate.

Once a system is mathematically modelled, computer-based simulations provide information about its behaviour. In physics-related problems, Monte Carlo methods are useful for simulating systems with many coupled degrees of freedom, such as fluids, disordered materials, strongly coupled solids, and cellular structures. Agent-based modelling is related to, but distinct from, the concept of multi-agent systems or multi-agent simulation in that the goal of ABM is to search for explanatory insight into the collective behaviour of agents obeying simple rules, typically in natural systems, rather than in designing agents or solving specific practical or engineering problems.

Related Societies and Associations

Biodiesel - America's first advanced biofuel, Advanced Biofuels Association, Bio Energy Association, World Biogas Association, Society of Agricultural and Biological Engineers, American Chemical Society.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

Track 14: Industrial Safety and Pollution Control

Pollution is the introduction of contaminants into the natural environment that cause adverse change. Pollution can take the form of chemical substances or energy, such as noise, heat or light. Pollutants, the components of pollution, can be either foreign substances/energies or naturally occurring contaminants. Some of the more common soil contaminants are chlorinated hydrocarbons (CFH), heavy metals (such as chromium, cadmium–found in rechargeable batteries, and lead–found in lead paint, aviation fuel and still in some countries, gasoline. Pollution prevention describes activities that reduce the amount of pollution generated by a process, whether it is consumer consumption, driving, or industrial production. In contrast to most pollution control strategies, which seek to manage a pollutant after it is formed and reduce its impact upon the environment, the pollution prevention approach seeks to increase the efficiency of a process, thereby reducing the amount of pollution generated at its source. Although there is wide agreement that source reduction is the preferred strategy, some professionals also use the term pollution prevention to include pollution reduction. Few significant classifications of Pollution Control are Air Pollution Control, Air Quality, Emission Tax, Environmental Management, Environmental Policy.  An industrial safety system is a countermeasure crucial in any hazardous plants such as oil and gas plants and nuclear plants. They are used to protect human, industrial plant, and the environment in case of the process going beyond the allowed control margins. As the name suggests, these systems are not intended for controlling the process itself but rather protection. Process control is performed by means of process control systems (PCS) and is interlocked by the safety systems so that immediate actions are taken should the process control systems fail.

Related Societies and Associations

Bio Energy Council of India, Asia-Pacific Biomass Energy Technology, Nigerian Society of Chemical Engineers, Israel Institute of Chemical Engineers, French Society of Process Engineering , Korean Chemical Society.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

 

 

Track 15: Chemical Industry and Market Analysis

In the US there are 170 major chemical companies. They operate internationally with more than 2,800 facilities outside the U.S. and 1,700 foreign subsidiaries or affiliates operating. The U.S. chemical output is $750 billion a year. The U.S. industry records large trade surpluses and employs more than a million people in the United States alone. The chemical industry is also the second largest consumer of energy in manufacturing and spends over $5 billion annually on pollution abatement. In Europe the chemical, plastics and rubber sectors are among the largest industrial sectors. Together they generate about 3.2 million jobs in more than 60,000 companies. Since 2000 the chemical sector alone has represented 2/3 of the entire manufacturing trade surplus of the EU. The chemical industry has shown rapid growth for more than fifty years. The fastest growing areas have involved the manufacture of synthetic organic polymers used as plastics, fibres and elastomers. Historically and presently the chemical industry has 380 3134 13523 Companies Chicago USA Globe been concentrated in three areas of the world, Western Europe, North America and Japan (the Triad). The European Community remains the largest producer area followed by the US and Japan.

Related Societies and Associations

Bio Energy Council of India, Asia-Pacific Biomass Energy Technology, Nigerian Society of Chemical Engineers,  Israel Institute of Chemical Engineers, French Society of Process Engineering , Korean Chemical Society.

Recommended Conferences: Chemical Engineering Conferences | Physical Chemistry Conferences | Computational Chemistry Conferences | Pollution Control and Sustainable Environment | Molecular Medicine and Proteomics Chemistry | Biomass and Green Energy | Spectroscopy and Analytical Techniques

 

 

 

Market Analysis

Chemical production in the European Union is expected to barely grow faster than in 2016. In general, the increase in production will remain modest against the backdrop of a sluggish domestic market. We expect competitive pressure on export markets to remain intense, even though the naphtha-based European chemical industry benefits more from low oil prices than the gas-based production in the United States.

 In the United States, we expect somewhat faster growth in chemical production, at just under 2%, as new production capacity, which will also be used for export, comes onstream. Overall chemical growth is likely to decelerate somewhat in the emerging markets of Asia, mainly due to the slowdown in China, which will affect the other developing countries in the region. In Japan, we presume a weak overall economic environment and minimal growth in chemical production. In South America, the anticipated end of the recession in Argentina and Brazil will result in slight growth in chemical production in the region.

 

                                                             Figure 1: Chemical production Data

Materials Chemistry:

Today, many materials chemists are synthesizing functional device materials, and the discipline is often seen as directed towards producing materials with function—electrical, optical, or magnetic. Material chemistry is involved in the designing and processing of materials. Global market for catalysts is expected to reach $28.5 billion by 2020, growing at a CAGR (2015 to 2020) of over 3%. Asia-Pacific is having the largest market for catalysts accounting for more than 35% share.

 

                                           Figure 2: Growth forecast of material chemistry

 

Global Advanced CBRN Market:

The global chemical, biological, radiological, and nuclear (CBRN) security market is rising at a steady pace globally as demand for effective CBRN protection measures to combat terrorist attacks is at an all-time high. The threat of use of weapons of mass destruction by terrorist organizations have raised alarms to prevent possible attacks with CBRN systems. CBRN security is a rising market to address concerns related to protecting civilian lives and maintenance of economic stability.

In addition, CBRN systems are used for accidental incidents. These include events caused by human or technological errors such as accidental leaks or factory spillage of poisonous gas or liquids. Intentional CBRN incidents occur when CBRN materials are released into the environment with the intention of terrorism or war or when hazardous material is discharged into the environment deliberately.

One of the key factors driving the CBRN security market is increasing demand for CBRN security in developing countries such as India, China, and Brazil among others. In addition, African nations are expected to continue spending incessantly on CBRN surveillance systems to mitigate rising CBRN threats such as Ebola in the regaion. With continual technological advancements and increasing research initiatives worldwide, new-age CBRN security equipment are launched that primarily focus on government organizations, military, and law enforcement agencies.

Transparency Market Research estimates the global CBRN security market to be worth US$15074.8 mn by 2025 increasing from US$9890.0 mn in 2016, expanding at a CAGR of 4.8% between 2017 and 2025. 

 

                                                             Figure 3: Global CNBR Security Market

Global Aroma Chemicals Market:

Aroma is a complex mixture of individual chemicals behaving according to their unique characteristics. These chemicals have several attributes such as polarity, volatility, stability, and surface activity among others. Among them, the chemicals with weight greater than 300 are called aroma chemicals. Perfumers use comprehensive palette of synthetic and natural aroma chemicals along with technical staff to create a peculiar commercial product.

Until a few years back, household care and personal care were the two primary segments exhibiting the demand for aroma chemicals. However, considering the latest research and development activities, the use of aroma chemicals has successfully penetrated medical and food and beverages industries. Spurred by this and efforts taken by the leading manufacturers to bolster product development and diversification, the global aroma chemicals market is forecast to exhibit a CAGR of 6.2% between 2016 and 2024. At this pace, the market’s valuation is expected to reach US$6.57 bn by the end of 2024. In 2015, the market was valued at US$3.85 bn.

 

                                                          Figure 4: Global Aroma Chemicals Report

Global Steam Boiler Systems Market:

 The global market for steam boiler systems is witnessing significant growth in its valuation, thanks to the rising demand for energy across the world. The augmenting need to improve energy efficacy of power plants and power generation process has been fueling the demand for steam boiler systems substantially. The rise in the government initiatives to encourage the usage of steam boiler systems, such as providing rebates and subsidies on their purchase, is also adding to the growth of this market remarkably. However, the high initial, as well as maintenance cost of these systems may limit their uptake, hindering the progress of this market soon.

In 2015, the global steam boiler systems market stood at US$12.0 bn. The opportunity in this market is likely to expand at a CAGR of 5.30% between 2016 and 2024 and is expected to reach US$18.9 bn by the end of 2024.

 

                                                                     Figure 5: Global Steam Boiler Report

 

 

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Conference Date April 20-21, 2020

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