Call for Abstract

2nd International Conference on Advances in Chemical Engineering & Technology, will be organized around the theme “Exploring the latest trends in Chemical Engineering”

Euro Chemical Engineering 2017 is comprised of 19 tracks and 66 sessions designed to offer comprehensive sessions that address current issues in Euro Chemical Engineering 2017.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

Register now for the conference by choosing an appropriate package suitable to you.

Chemical engineering is a branch of engineering that applies physical sciences (physics and chemistry), life sciences (microbiologyand biochemistry), together with applied mathematics and economics to produce, transform, transport, and properly use chemicals, materials and energy. A chemical engineer designs large-scale processes that convert chemicals, raw materials, living cells, microorganisms and energy into useful forms and products.

  • Track 1-1 Nano technology
  • Track 1-2Chemically reacting Systems
  • Track 1-3Downstream Processing
  • Track 1-4Chemical kinetics
  • Track 1-5Chemical Process Modelling
  • Track 1-6Nanomaterials and Nanotechnology
  • Track 1-7Inorganic Chemical Technology
  • Track 1-8Organic Chemical Technology
  • Track 1-9 process control
  • Track 1-10 safety
  • Track 1-11Pharmaceutical Engineering

Catalysts are complex materials that have to fulfil many criteria on multiple scales, in order to be successfully used in catalytic processes. There are different types of catalysis process like photo catalysis, Thermo catalysis, and Nano catalysis etc. Heterogeneous catalysts act in a different phase than the reactants. 

  • Track 2-1Catalysis for Sustainable Systems
  • Track 2-2Photo & Electrocatalysis
  • Track 2-3Reaction Engineering
  • Track 2-4Structured Catalysts
  • Track 2-5Chemical Intermediates
  • Track 2-6Photocatalysis

 Chemical reaction engineering involves organising plant processes and conditions to ensure optimal plant operation to construct models for reactor process design and analysis. Many applications of chemical engineering involves in day to day life like rubber, plastic, cement, sugar, ceramic etc.

  • Track 3-1Modelling of Chemical Reaction Engineering
  • Track 3-2Non ideal Reactors and Mixers
  • Track 3-3Fluidized Bed Technologies
  • Track 3-4Reaction Testings
  • Track 3-5Chemical Reactor Designs

Carbon Materials are used in almost every aspects of life.The use of carbon materialsin wide applications derives from the materials unique diversity of structures and properties that extend from chemical bonding between carbon atoms to nanostuctures, crystallite alignment, and microstructures.

A Separation process is a technique to achieve any mass transfer occurrence that converts a mixture of substances into two or more individual product mixtures. Separations may differ in chemical properties or physical properties such as size, shape, mass, density, between the constituents of a mixture. 

  • Track 5-1Membrane Separation
  • Track 5-2Ion Exchange
  • Track 5-3Micro Filtration
  • Track 5-4Fractional distillation
  • Track 5-5Electrophoresis
  • Track 5-6Chromatography

In chemical compounds, polymerization occurs in a variety of reaction mechanisms that differ in complexity due to functional groups present in reacting compounds. Biopolymers contain monomeric units that are covalently bonded for the formation of larger structures. 

  • Track 6-1Advances in polymer Science
  • Track 6-2Polymer Processing
  • Track 6-3Industrial Aspects of Polymers
  • Track 6-4Bionics
  • Track 6-5Kinetics of Polymerization Reactions
  • Track 6-6Polymer Modifications
  • Track 7-1Water Quality Management
  • Track 7-2Surface Water Treatment
  • Track 7-3Environmental and Sustainable development

fluid dynamics is a subdiscipline of fluid mechanics that deals with fluid flow—the science of fluids (liquids and gases) in motion. It has several subdisciplines itself, including aerodynamics (the study of air and other gases in motion) and hydrodynamics (the study of liquids in motion).

  • Track 8-1Newtonian Fluids
  • Track 8-2Non Newtonian Fluids
  • Track 8-3Complex Fluids
  • Track 8-4Navier-Stokes Theorem
  • Track 8-5Computational Fluid Dynamics
  • Track 8-6Compressible Flows

Biotechnology refers to the living systems and organisms to develop or make products, or any technological application that uses biological systems. Depending on the tools and applications, it is often overlaps with the field of bioengineeringbiomedical engineeringmolecular engineering, etc. 

  • Track 10-1Bioengineering Process Intensification
  • Track 10-2Genetic Engineering
  • Track 10-3Enzyme Engineering

Biofuel are manufactured using a wide range of resources. This variety has grown in recent years, aiding to shape a dexterous industry that is steadily searching for a new technology and feedstock. 

Biomaterials seen steady growth in half century of existence and uses ideas from medicine, biology, chemistry, materials science and engineering. Biomaterials mainly considers ethics, law and the health care delivery system. 

Biochemical Engineering is an essential area in modern biotechnology.  Biochemical engineering includes Bioreactor and fermenter design aspects, Industrial biotechnology, Photo bioreactor electrochemical energy conversion, Biological hydrogen production (Algae), Biofuel from algae, Bioreactor landfill, and Moss bioreactor.

Petroleum engineering is concerned with the the production of hydrocarbons, which can be either crude oil or natural gases. Exploration and Production are deemed to fall within the  sector of the oil and gas industries. 

  • Track 14-1Gas Hydrates
  • Track 14-2Coal Bed Methane
  • Track 14-3Carbonate reservoir Characterization
  • Track 14-4Hydraulic Fracturing
  • Track 14-5Oil Exploration

Environmental Engineering basically is a branch of applied science which involves the issues of energy preservation, protection and control of wastes from human and animal activities. It also includes waste water management, air pollution control, recycling, waste disposal, radiation protection, industrial hygiene, animal agriculture, environmental sustainability, public health and environmental engineering law. 

Modeling and analysis of transport phenomena is essential for many industrial applications. Transport phenomena involve fluid dynamicsheat transfer and mass transfer, which are governed mainly by momentum transferenergy transfer and transport of chemical species respectively. Models often involve separate considerations for macroscopicmicroscopic and molecular level phenomena. Modeling of transport phenomena requires therefore requires an understanding of applied mathematics.

  • Track 16-1Transport Phenomenon in Fuel Cells
  • Track 16-2Solid Liquid Mass Transfers
  • Track 16-3Microfluidic Devices
  • Track 16-4Advanced Fluid Dynamics
  • Track 16-5Heat Transfer
  • Track 16-6Mass Transfer

Thermodynamics mainly deals about the relationship between work, heat and other forms of energy. Thermodynamics applies to a wide range of subjects in science and engineering, mainly physical chemistry, chemical engineering and mechanical engineering.

  • Track 17-1Thermodynamic equilibrium
  • Track 17-2Laws of Thermodynamics
  • Track 17-3Chemical Thermodynamics
  • Track 17-4Non Equilibrium thermodynamics
  • Track 17-5Biological Thermodynamics

Safety is the condition of being safe and free from any hazards or any non-desirable outcomes. The safety methods are the various procedures and techniques utilized while performing any tasks on fields in any industries or workplace. 

  • Track 18-1Transportation and Handelling
  • Track 18-2Chemical Safety Trainings
  • Track 18-3Risk Managements
  • Track 18-4Chemical Wastes Handelling