Track Categories

The track category is the heading under which your abstract will be reviewed and later published in the conference printed matters if accepted. During the submission process, you will be asked to select one track category for your abstract.

This Chemical Engineering Conference provides exposure to the on-going researches in Catalysis & Chemical Engineering and other related fields of science. It will also provide insight to the inventions and techniques. And Catalysis Conference is very beneficial for the students and fellowship owners because of the knowledge it provides about the field. It also gives opportunities to the companies to showcase their products and have face to face meetings with scientists.

This Catalysis Conference is a platform for Chemical students, faculty, deans, researchers, and leaders to collaborate on topics affecting Chemical Engineering. Attendees can: Take advantage of opportunities to learn about Chemical Engineering education research from a variety of oral and poster presentations.

  • Track 1-1Heat & Mass Transfer
  • Track 1-2Energy and Environment
  • Track 1-3Chemical Reaction Engineering
  • Track 1-4Thermodynamics
  • Track 1-5Material Science & Engineering
  • Track 1-6Computing and Simulation
  • Track 1-7Technology of Synthesis of Pharmaceutical Chemicals
  • Track 1-8Unit Operation & Unit Process

Catalysis is the expansion in the rate of a synthetic response because of the cooperation of an extra substance called a catalyst. As a rule, responses happen speedier with a catalyst since they require less enactment vitality. Moreover, since they are not expended in the catalysed response, impetuses can keep on acting over and over. Frequently just little sums are required on a basic level. A portion of the biggest scale chemicals is delivered by means of reactant oxidation, frequently utilizing oxygen.

Cases incorporate nitric corrosive (from alkali), sulfuric corrosive (from sulphur dioxide to sulphur trioxide by the loading procedure), terephthalic corrosive from p-xylene, and acrylonitrile from propane and smelling salts. Many fine chemicals are readied by means of catalysis; techniques incorporate those of overwhelming industry and additionally more specific procedures that would be restrictively costly on a vast scale. Cases incorporate the Heck response and Friedel-Crafts responses. Since most bioactive mixes are chiral, numerous pharmaceuticals are created by enantioselective catalysis (synergist Hilter kilter amalgamation).

  • Track 2-1Nature of Catalysts
  • Track 2-2Catalyst Formulation & Preparation Methods
  • Track 2-3Catalysis & Nanotechnology
  • Track 2-4Design of Catalysts & Simulation Techniques
  • Track 2-5Mechanism of Catalytic Reactions
  • Track 2-6Pore Volume Distribution of Catalysts

This field of study amalgamates facet of organic, organometallic, and inorganic chemistry. Synthesis forms a considerable component of most programs in this area. Mechanistic scrutiny is often undertaken to discover how an unexpected product is formed or to rearrange the recital of a catalytic system. Because synthesis and catalysis are essential, to the construction of new materials, Catalysts are progressively used by chemists busy in fine chemical synthesis within both industry and academia. Today, there prevail huge choices of high-tech catalysts, which add enormously to the repertoire of synthetic possibilities. However, catalysts are intermittently fickle, sometimes gruelling to use and almost always require both skill and experience in order to achieve optimal results.

  • Track 3-1Catalyst for Organic Synthesis Reaction
  • Track 3-2CBS Catalysts for Chemical Synthesis
  • Track 3-3Safety and Reliability
  • Track 3-4Risk Management
  • Track 3-5Advanced Oxidation Process

In chemistry, homogeneous catalysis will be catalysis in a solution by a solvent catalyst. Entirely, homogeneous catalysis alludes to catalytic reactions where the catalyst is in the same stage from the reactants.

Homogeneous catalysis applies to reactions in the gas stage and even in solids. Control over the local chemical environment condition of a particle can be accomplished by encapsulation in supramolecular host systems. In supramolecular catalysis, this control is utilized to gain preferences over established homogeneous catalysis in bulk arrangement. Two of the fundamental points concerns impacting reactions as far as substrate and product selectivity. Because of size and additionally shape recognition, substrate selective transformation can be figured out.

  • Track 4-1Supra-Molecular Catalysis
  • Track 4-2Molecular Thermodynamics
  • Track 4-3Acid Catalysis
  • Track 4-4Forms of Homogeneous Catalysis
  • Track 4-5Carbonation & Oxidation

A catalyst is another substance than reactants products added to a reaction system to alter the speed of a chemical reaction approaching a chemical equilibrium. It interacts with the reactants in a cyclic manner promoting perhaps many reactions at the atomic or molecular level, but it is not consumed. Another reason for using a catalyst is that it promotes the production of a selected product.

A catalyst that is in a separate phase from the reactants is said to be heterogeneous, or contact, catalyst. Contact catalysts are materials with the capability of adsorbing molecules of gases or liquids onto their surfaces. An example of heterogeneous catalysis is the use of finely divided platinum to catalyse the reaction of carbon monoxide with oxygen to form carbon dioxide. This reaction is used in catalytic converters mounted in automobiles to eliminate carbon monoxide from the exhaust gases. 

  • Track 5-1Adsorption
  • Track 5-2Surface Reactions
  • Track 5-3Separation Processes
  • Track 5-4Zone Refining
  • Track 5-5Different States of Catalysis Reaction
  • Track 5-6Catalyst Design
  • Track 5-7Catalyst Deactivation

Polymerization is the process of combination of many small biochemical molecules known as monomers into a covalently bonded chain. During the polymerization process, few chemical groups may be lost from each monomer. Polymer Technology is nothing but the manufacture, processing, analysing and application of long-chain molecules. Plastics, paints, rubber, foams, adhesives, sealants, varnishes are the materials that are said to be polymers.

Nowadays all these polymer products became very essential as we depend on these polymers for our daily day to day life. The industries that make use of the polymers are information technology, aerospace, music, clothing, medical, motor manufacturing, building, packaging, etc.

  • Track 6-1Emerging trends in Polymer Synthesis
  • Track 6-2Polymer design for 3D/4D printing
  • Track 6-3Polymeric Materials & Composites
  • Track 6-4 Medical Applications
  • Track 6-5Recent progress in Polymer Materials
  • Track 6-6Polymer Rheology & Compounding

Process engineering focuses on the design, operation, control, optimization and intensification of chemical, physical, and biological processes. The application of systematic computer-based methods to process engineering is "process systems engineering". Recent innovation in the field of Chemical Process Engineering furnishes the 

In engineering, a process is a series of interrelated tasks that, together, transform inputs into Automation system. It can be defined as the system of providing chemical or biochemical processes and equipment that required to turn raw materials into an end product. It is a vital part of the all the stages of manufacturing industry. New and innovative processes and equipment can be designed by the process engineers for a new facility, or they can modify and optimize the existing one.

  • Track 7-1Techniques in Process design
  • Track 7-2Process Optimization
  • Track 7-3Process simulation
  • Track 7-4Effective methods of Process Control

The scientific study with the aspect of chemistry which deals with the structure, properties and reactions of the organic matter which is nothing but the matters which contains at least one carbon atoms in their chemical structure. Organic chemistry is useful in the field of medicine, pesticides, textiles, petroleum, etc. Organic chemistry is key which enables us to analyse a substance to its elemental stage. It helps to test a compound for impurities and processes like chromatography and to completely analyse a substance.

Not only for the artificial compounds we produce, but also to synthesize naturally occurring substances in large quantities, Organic Chemistry enables us to recreate the required substance in quantities we need with various processes.

  • Track 8-1Structure and Bonding
  • Track 8-2Alkanes, Alkenes and Alkynes
  • Track 8-3Aromatic Compounds
  • Track 8-4Stereochemistry
  • Track 8-5Amines, Ethers and Aldehydes
  • Track 8-6Acid-Base Chemistry

In the chemical industry and industrial research, catalysis assumes an essential part. Distinctive catalysts are inconsistent advancement to satisfy financial, political and natural requests. When utilizing catalysts, it is conceivable to replace a contaminating chemical reaction with a more environmentally friendly alternative.

Today, and in the future, this can be crucial for the chemical industry. For an organization, a new and improved catalyst can be an enormous preferred standpoint for a competitive assembling cost. It's amazingly costly for an organization to shut down the plant because of a blunder in the catalyst, so the right choice of a catalyst or another change can be critical to industrial achievement.

  • Track 9-1Catalyst for a green industry
  • Track 9-2High temperature Shift (HTS) catalyst
  • Track 9-3Low Temperature Shift (LTS) Catalyst
  • Track 9-4Carbon Monoxide
  • Track 9-5Volumetric Properties
  • Track 9-6Catalyst Deactivation

Catalytic reactions lie at the centre of numerous chemical processes and biochemical procedures. The test research in designing the catalyst is to expand its viability and soundness. A substance response building is the capacity to judiciously outline and control synthetic responses. In this way, one ought to comprehend the reactor plan, catalysis, and divisions. Seeing how to control the profitability and selectivity of responses for chemical production, contamination decrease, restorative combination, and so forth, is basic for present day ventures and for the change of the human conditions.

  • Track 10-1Steps of Catalytic Reactions
  • Track 10-2Rate Limiting Step
  • Track 10-3Type of Catalyst Deactivation
  • Track 10-4Chemical Vapour Deposition
  • Track 10-5Special Reactors
  • Track 10-6Process Intensification

Zeolites are the most important heterogeneous catalysts with numerous large-scale applications including cracking, petrochemistry, fine chemical synthesis, and environmental protection. This themed issue evidences the significant impact of zeolites in catalysis, new trends in catalytic applications of zeolites and their potential in catalysis.

Zeolites are used as catalysts in petrochemical industries for cracking of hydrocarbons and isomerization. An important zeolite catalyst used in the petroleum industry is ZSM-5. It converts alcohol directly into gasoline (petrol) by dehydrating them to give a mixture of hydrocarbons. Electron microscopic investigations of zeolites are reviewed. Scanning electron microscopy can show the appearance of zeolite crystals, e.g. their sizes and morphologies, and can also be used to look into the cores of crystals revealing any abnormal microstructures, which often help us to elucidate actual crystal growth mechanisms.

High-resolution transmission electron microscopy is a powerful tool to directly image many pore systems and local defects in zeolites.

  • Track 11-1Disruptive Catalysis by Zeolites
  • Track 11-2Two-Dimensional Zeolites
  • Track 11-3Hierarchical Zeolites
  • Track 11-4Zeolites in Industrial Catalysis
  • Track 11-5Zeolite Membranes in Catalysis

It has turned into a substitute technique for decision for the creation of fine synthetic substances at exceptional returns and incredible selectivity under mellow response condition. The effect of biocatalysts, later, will be the augment of capacity to utilize compounds to catalyse substance responses in mechanical procedures, including the production of drug material, flavours, fragrances, electronic chemicals, polymer chemicals that actually affect relatively every feature of your life. In embracing biocatalysts as a standard innovation for synthetic generation, it is presenting an innovation that is greener, diminishes contamination and cost, and makes more noteworthy maintainability Environmental catalysis and Nano Catalysis.

Biotransformation is a substance alteration (or changes) of concoction mixes, for example, supplements amino acids, poisons and medications in the body by a creature finishing off with the generation of mineral mixes like CO2, NH4+, H2O or water solvent mix so it can be effortlessly killed from the body.

  • Track 12-1Green Energy
  • Track 12-2Photo-Electronic Devices & Materials
  • Track 12-3Energy Devices
  • Track 12-4Electrocatalysts
  • Track 12-5Enzymes & Bio-Catalysts
  • Track 12-6Energy Processing

The renewable energy source is vitality that is gathered from renewable resources, which are normally renewed on a human timescale, for example, daylight, wind, rain, tides, waves, and geothermal heat. Renewable energy source frequently gives vitality in four vital regions: electricity generation, air, and water heating /cooling, transportation, and rural energy services. Rapid deployment of renewable energy and energy efficiency is bringing about significant energy security, environmental change relief, and economic benefits. Renewable energy source frameworks are quickly ending up more productive and less expensive.

  • Track 13-1Wind Power
  • Track 13-2Geothermal Energy
  • Track 13-3Solar Energy
  • Track 13-4Wind Power Development
  • Track 13-5Hydropower

Nanotechnology and Nanoscience include the capacity to see and to control individual particles and atoms. Everything on Earth is comprised of atoms—the food we eat, the garments we wear, the buildings and houses we live in, and our own bodies. Catalysts, heterogeneous, homogeneous and chemical, are generally nanoparticles. Enthusiasm for nanoscience and in nanotechnology as of late cantered consideration around the chance to create catalysts that display 100% selectivity for the required item, hence removing by-products and wiping out waste. Regenerative nanomedicine is one of the medical applications of nanotechnology. It ranges from the medical applications of nanomaterials to Nanoelectronics biosensors, and the future uses of sub-atomic nanotechnology, for example, natural machines. Nanomedicine deals came to $16 billion out of 2015, with at least $3.8 billion in nanotechnology R&D being contributed each year.

  • Track 14-1Diffusion in Nanocatalysis
  • Track 14-2Liquid-Phase Synthesis of Nanocatalysts
  • Track 14-3Nano-Oxide Mesoporous Catalysts in Heterogeneous Catalysis
  • Track 14-4Oxidations with Nanocatalysis
  • Track 14-5Nano Materials
  • Track 14-6Nanomedicine
  • Track 14-7Nanocatalysis in the fast Pyrolysis of Lignocellulosic Biomass

Catalysts are the materials that must fulfil many criteria on multiple scales, in order to be successfully used in catalytic processes. There are different types of catalysis processes like photocatalysis, Thermo catalysis, and, etc. Heterogeneous catalysts in a different phase than the reactants. The R&D exercises in the Department are gone for the change of existing and production of new mechanical procedures. An essential reason for existing is the improvement of the physicochemical premise of reactant advancements and the operation of new catalysts.

  • Track 15-1Catalysis for Sustainable Systems
  • Track 15-2Chemical Intermediates
  • Track 15-3Hydrogenation
  • Track 15-4Structured Catalysts
  • Track 15-5Methane Aromatization

Petrochemicals are chemical products developed from Petroleum. Some chemical compounds made from Petroleum are also obtained from fossil fuels, such as coal or natural gas, and renewable sources such as corn or sugar cane. The most common petrochemicals are olefins and aromatics (including benzene, toluene and xylene isomers), Synthesis gas. Petroleum refining processes are nothing, but Chemical Engineering processes used in petroleum refineries to change crude oil into useful products such as Liquefied Petroleum Gas (LPG), gasoline (petrol), kerosene, jet fuel, diesel oil, and fuel oils.

  • Track 16-1Fuels & Refining
  • Track 16-2Catalysts in Petroleum Refining
  • Track 16-3Coastal Engineering
  • Track 16-4Petroleum Economy
  • Track 16-5Environmental Hazards & Safety Measures

The branch that deals with the technological methods of large-scale chemical production and manufacturing of products from raw materials using chemical processes. The usage of chemical technology leads to a lot of innovations in various fields such as nanotechnology, fuels in aerospace, biomedical, etc. Chemical technology is also used for medicinal purposes such as delivering drugs to specific tissues and cells, to treat damaged tissues, etc. Plastics that are highly efficient and lightweight are employed in the field of aerospace. The touch screens that are daily used in mobiles, LCD's and computers are enabled by plastics, adhesives and 0ther chemical products.

  • Track 17-1Applications in Drugs and Pharmacy
  • Track 17-2Alternative Fuels
  • Track 17-3Food Processing and Preservation Technology
  • Track 17-4Nanomaterials and Aerospace Materials