Advanced Chemical Engineering

About Conference

On behalf of 2^nd International Conference on Advanced Chemical Engineering organizing committee, invites Chemical Engineers, researchers, professors, scientific communities, delegates, students, business professionals and executives to attend the “Advanced Chemical Engineering 2018” which is going to be held during November 29-30, 2018, Barcelona, Spain.

Advanced Chemical Engineering 2018 is a global platform for presenting research about Chemical Engineering related fields. This event brings together the top professionals in the field of chemical Engineering along with the highly affiliated professors to explore the advancements and latest applications achieved in the field. Advanced Chemical Engineering 2018 discusses various fields of Chemical Engineering  employed in Petro Chemicals, Petrochemistry, Chemical Reaction Engineering, Separation Process , Environmental and Green Chemistry, Polymer technology, Electrochemical Engineering, Biofuels, Biomolecular Engineering, Heat transfer technology, Computational Fluid Dynamics, Combinatorial Material Synthesis, Unit Operations and Chemical Science fields which mark the support for the advanced and much needed research by their study on various topics.

In the light of this theme, the Euroscicon aims to provide a forum for international researchers from various areas of Chemistry, Chemical Engineering, Material 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 chemical engineering world. Chemical Engineering 2018 chiefly aims to provide information in analysis and advances in chemical techniques. Chemical engineering has provided many latest researches and findings in recent times and thus Advanced Chemical Engineering 2018 would be an ideal venue to showcase and experience these happenings.

Sessions/ Tracks

We invite all the global participants to join us for “Advanced Chemical Engineering 2018”. The Theme of the Advanced Chemical Engineering 2018 conference is “Exploring the Emerging Trends in the Realm of Advanced Chemical Engineering” with an objective to encouraging young minds and researchers by providing an opportunity and platform to meet the experts in the field of Chemical Engineering. Chemical Engineering events are designed to explore various applications in different chemical fields. 

Track 1: Chemical Engineering

Chemical engineering is a branch of engineering that applies physical sciences, life sciences, together with applied mathematics and economics to produce, transform, transport, and properly use chemicals, materials and energy.  Chemical engineering is also concerned with pioneering valuable new materials and new methods such as nanotechnology, fuel cells and biomedical engineering. The global chemical industry and market analysis, estimated at U.S. $2.4 trillion, is one of the fastest growing business sectors of the manufacturing industry. It also shipped 3.4 billion dollars’ worth of chemicals globally across regions in 2009.

1. Organic Chemical Technology
2. Inorganic Chemical Technology
3. Nanomaterial’s and Nanotechnology
4. Catalysis Engineering
5. Petrochemistry

Track 2: Chemical Reaction Engineering

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.

1. Multiphase flow and reactors
2. Chemical Reactors and photochemical Reactors
3. Micro-reactors

Track 3: Thermodynamic Process

Thermodynamics is a division of physics involved with heat and temperature and their relation to energy and work. Thermodynamics applies to a wide range of subjects in science and engineering, mainly physical chemistry, chemical engineering and mechanical engineering. Thermodynamic equilibrium is one of the very important concepts of thermodynamics. A thermodynamic operation usually results in thermodynamic process of transfer of mass or energy that modifies the state of the system, and the transfer occurs in natural accord with the laws of thermodynamics.

1. Chemical Thermodynamics
2. Laws of Thermodynamics
3. Biological Thermodynamics

Track 4: Advances in Renewable Chemicals

The renewable chemicals market is expanding primarily the resources of renewable chemicals, and the consumer’s inclination towards using eco-friendly products. The high cost and certain subjects related to the production of renewable chemicals are the factors that are hampering the development of this market. Renewable chemicals contain all the chemicals which are produced from renewable feedstock such as microorganisms, biomass (plant, animal, and marine), and agricultural raw materials. Renewable chemicals are utilized in several applications across different Chemical industries such as in food processing, housing, textiles, environment, transportation, hygiene, pharmaceutical, and other applications. Renewable chemicals are mainly available as ketones, alcohols, organic acids, and bio-polymers. They are used in surfactants and lubricants, consumer goods, resins, and plastics for environmental purpose. Renewable chemicals are used for increasing the use of renewable resources rather than fossil fuels. There are diverse technologies available in chemical engineering which are used for making renewable chemicals.

1. Solar Chemicals
2. Sustainable energy
3. Clean technology
4. Green Chemistry

Track 5: Biochemical Engineering

Biochemical Engineering is the application of chemical engineering methods and approaches to industrial processes based on biological elements such as living cells or their components. Microbes and enzymes for example are used to produce useful chemical compounds such as antibiotics, other medically useful chemicals, detergents, amino acids, etc. Biochemical engineers translate exciting discoveries in life sciences into practical materials and processes contributing to human health and well-being. It deals with the design and construction of unit operations that involve biological organisms or molecules, such as bioreactors. A bioreactor may also refer to a device meant to grow cells or tissues in the ambience of cell culture. These devices are being developed for use in tissue engineering or biochemical engineering. Different types of Bioreactors are Photo bioreactor, Sewage treatment, Up and Down agitation bioreactor, NASA tissue cloning bioreactor, Moss bioreactor. Its applications are in the petrochemical industry, food and pharmaceutical, biotechnology, and water treatment industries. Orthopaedic applications form the largest division of the overall biomaterials market. Polymer-based biomaterials are expected to initiate the next wave of market growth; and the future biochips and biosensors business segments also offer huge growth potential.

1. Industrial biotechnology
2. Industrial biotechnology
3. Biological hydrogen production
4. Bioprocess engineering

Track 6: Computational Fluid Dynamics

Computational fluid dynamics (CFD) is the use of applied mathematics, physics and computational software to visualize how a gas or liquid flows, as well as how the gas or liquid affects objects as it flows past. Computational fluid dynamics is based on the Navier-Stokes equations. These equations describe how the velocity, pressure, temperature, and density of a moving fluid are related. It also uses numerical analysis and data structures to solve and analyse problems that involve fluid flows.

1. Discretization methods
2. Turbulence models
3. Two-phase flow
4. Unsteady aerodynamics
5. Solution algorithms

Track 7: Chemical Polymer Technology

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. 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. Monomers are terephthalic acid, ethylene glycol Laboratory synthetic method are step-growth polymerization and chain-growth polymerization. The essential variation between the two is that in chain growth polymerization, monomers are added to the chain one at a time only, such as in polyethylene, but in step-growth polymerization chains of monomers may combine with one another directly. Beside metals and ceramics, the study of polymers has currently become a cornerstone of material sciences and engineering. A Polymer Material Sciences and Engineering will provide you with a strong basis in the wide range of issues around structural and functional polymers.

1. Polymer Chemistry
2. Polymer Nanotechnology
3. Polymer Physics
4. Advanced Polymer Structures

Track 8: Unit Operations

A unit operation is related fields of chemical engineering It is the basic step in a process. Unit operations involve a chemical transformation or physical change such as filtration, polymerization, isomerization, separation, crystallization, evaporation and other reactions. In the field of Chemical Engineering separation process is the mass transfer that converts the substance mixture into specific product mixtures. In some cases, a separation may fully divide the mixture into its pure constituents. Separation Techniques are conducted based on the differences between chemical properties, or physical properties like size, shape, mass, density and chemical affinity, between the constituents of a mixture, and are often differentiated according to the specific differences they use to achieve.

1. Aqueous two-phase system
2. Mixing (process engineering)
3. Heat transfer

Track 9: Process design and control

Process design is distinct from equipment design, which is closer in spirit to the design of unit operations. Processes often include many unit operations. In chemical engineering, process design is the design of processes for desired physical and/or chemical transformation of materials. Process design is central to chemical engineering, and it can be considered to be the summit of that field, bringing together all of the field's components. Process design can be the design of new facilities or it can be the modification or expansion of existing facilities. The design starts at a conceptual level and ultimately ends in the form of fabrication and construction plans.

1. Process engineering
2. Process integration
3. Process simulation
4. Process safety

Track 10: Chemistry Usage in Chemical Engineering

Inorganic chemistry handles with the synthesis and behaviour of inorganic and organometallic compounds. This field covers all chemical compounds but not the carbon-based compounds which are the subjects of organic chemistry. It has applications in every aspect of the chemical industry catalysis, material science, pigments, surfactants, coatings, medicine, fuel, agriculture. And many inorganic compounds are ionic compounds, consisting of cat-ions and anions joined by ionic bonding. Inorganic compounds are naturally found in nature as minerals.

1. Cluster Chemistry
2. Bioinorganic Chemistry
3. Synthetic Inorganic Chemistry

Track 11: Heat Transfer Research

Heat is defined in physics as the transfer of thermal energy across a well-defined boundary around a thermodynamic system. The thermodynamic free energy is the amount of work that a thermodynamic system can perform. Enthalpy is a thermodynamic potential, designated by the letter "H", that is the sum of the internal energy of the system (U) plus the product of pressure (P) and volume (V). Joule is a unit to quantify energy, work, or the amount of heat. Heat transfer is a process function (or path function), as opposed to functions of state; therefore, the amount of heat transferred in a thermodynamic process that changes the state of a system depends on how that process occurs, not only the net difference between the initial and final states of the process. Thermodynamic and mechanical heat transfer is calculated with the heat transfer coefficient, the proportionality between the heat flux and the thermodynamic driving force for the flow of heat. Heat flux is a quantitative, vectorial representation of heat-flow through a surface.

1. Advection
2. Conduction or Diffusion
3. Convection
4. Radiation

Track 12: Nanotechnology

Nanotechnology is the study of manipulating matter on an atomic and molecular scale. Generally, nanotechnology deals with developing materials, devices, or other structures with at least one dimension sized from 1 to 100 nanometres. Nanotechnology entails the application of fields of science as diverse as surface science, organic chemistry, molecular biology, semiconductor physics, microfabrication, etc.

1. Nanomaterials
2. Nano chemistry
3. Nano electronics
4. Nano photonics

Track 13: Petrochemistry and Petrochemicals

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. Oil refineries produce olefins and aromatics by method of fluid catalytic cracking of petroleum fractions. Chemical plants produce olefins by a steam cracking of natural gas liquids like ethane and propane. Aromatics are produced by a process of catalytic reforming of naphtha. 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. Each refinery has its own specific arrangement and combination of refining processes largely determined by the refinery places, desired products and economic considerations.

1. Analytical Instrumentation
2. Flow Level Pressure
3. Measurement and testing

Track 14: Biomolecular Engineering

A biomolecular engineer studies and manufactures new molecules to create products and processes that don't already exist in the natural world. Biomolecular Engineering is an emerging discipline at the interface of molecular biology, biophysical chemistry, and chemical engineering. Biomolecular engineering is the application of engineering principles and practices to the purposeful manipulation of molecules of biological origin. Biomolecular engineering research includes mathematical modelling of biomolecules and biological processes, their quantitative measurements, visualizations, multidimensional and detailed structural analyses, protein structure prediction using current approaches protein structure- function relationships, rational design of bioactive molecules discovery of new target molecules leading to new drug discoveries, construction of artificial gene circuits to produce novel gene products. Worldwide, biomedical engineering is rapidly developing given its crucial role in the biomedical field.

1. Bioengineering
2. Biochemistry
3. Biochemical engineering
4. Biotechnology
5. Bioelectrical engineering
6. Biomedical engineering

Track 15: Electrochemical Engineering

An Electrochemical Synthesis is a chemical reaction that is caused by the movement of electrical current. These processes are a type of oxidation-reduction chemical reactions in which one atom or molecule loses an electron to another atom or molecule. In electrochemical process, the atoms or molecules in the reaction are relatively far apart from each other compared to other reactions, forcing the electrons being transferred to travel a greater distance and thereby produce an electrical current. 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.

1. Electrochemical energy conversion
2. Electro deionization
3. Electrodialysis
4. Electro filtration

Track 16: Biofuels

A biofuel is a fuel that is produced through contemporary biological processes, such as agriculture and anaerobic digestion, rather than a fuel produced by geological processes such as those involved in the formation of fossil fuels, such as coal and petroleum, from prehistoric biological matter. Biofuels can be derived directly from plants, or indirectly from agricultural, commercial, domestic, and/or industrial wastes. Renewable biofuels generally involve contemporary carbon fixation, such as those that occur in plants or microalgae through the process of photosynthesis. Other renewable biofuels are made through the use or conversion of biomass. This biomass can be converted to convenient energy-containing substances in three different ways: thermal conversion, chemical conversion, and biochemical conversion. This biomass conversion can result in fuel in solid, liquid, or gas form. This new biomass can also be used directly for biofuels.

1. Bioethanol
2. Biorefineries
3. Biodiesel
4. Aviation Biofuels
5. Biogas
6. Bio energy

Track 17: Combinatorial materials synthesis

Combinatorial materials synthesis. Also known as "combi," it allows for the rapid screening of a large number of compositionally varying samples to determine if any have the characteristics the researchers desire, saving tremendous amount of time and money in the process. 

1. Thin-film synthesis
2. Pulsed laser deposition
3. Luminescent materials
4. Ferroelectrics/dielectrics
5. Superconductors.

Track 18: Industrial Safety Methods and Pollution

Safety is the state 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. 

1. Transportation and Handling
2. Risk Management
3. Chemical Wastes Handling
4. Air pollution
5. Water pollution

Track 19: Application of Chemical Technology

The branch of engineering that handles with the technology of large-scale chemical production and the manufacture of products through chemical process. The Modern products of chemistry lead to cutting edge advancements applied technology in medical devices, aerospace, computing, fuels and more. As technology advances our nation’s primary chemicals management law must be updated to adapt to scientific progress and to promote that chemical products are safe for intended use. Chemistry Usage in Nanotechnology has many diverse applications, some of which include delivering drugs to specific cells, and repairing of damaged human tissue, improving efficiency of solar energy production and enabling both lighter, higher performance plastics for aerospace, construction and vehicles. Chemistry in the Space Age Aerospace needs the products of chemistry such as plastic space suits that can withstand 600-degree (Fahrenheit) temperature ranges. Chemistry in Computing has widespread use of touch screens, enabled by plastics, adhesives and other products of chemical technology are employed on cell phones, PDAs, computer screens. The global construction chemicals market (2015–2020) is estimated to reach USD 33.98 Billion by 2020 increasing at a rate of 7.62% between 2015 and 2020.

Track 20: Separation Processes

A Separation process is a technique 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. 

1. Membrane Separation
2. Chromatography
3. Micro Filtration
4. Fractional distillation

Track 21: Chemical Industry and Market Analysis

The Chemical Industry and Market Analysis is one of the quickest growing segments in manufacturing industry. Chemicals broadly contain bulk petrochemicals and intermediates, minerals, polymers, more derivatives, etc. The industry has been undergoing through important structural modifications in the recent years, such as new developing markets, change in manufacturing places, superior technologies, and rising raw material cost. The key challenges for the industry are government regulations, carbon-emission policies, and economies of scale. Transparency Market Research provides study on sealants, adhesives, explosives, chemicals, agro-chemicals, petrochemicals, renewable chemicals paints and coatings, colorants, biodegradable plastics, and other chemicals.

 

 

 

 

 

 

 

 

 

 

 

Market Analysis

Chemical engineering is a branch of engineering that applies physical sciences and life sciences. It essentially deals with the engineering of chemicals, energy and the processes that create and/or convert them. Modern chemical engineers are concerned with processes that convert raw materials or chemicals into more useful or valuable forms. They are also concerned with pioneering valuable materials and related techniques which are often essential to related fields such as nanotechnology, fuel cells and bioengineering. Chemical engineers "develop economic ways of using materials and energy". Chemical engineers use chemistry and engineering to turn raw materials into usable products, such as medicine, petrochemicals and plastics on a large-scale, industrial setting.

Advanced Chemical Engineering 2018 provides the chance for Scientists, researchers, Practitioners and Scholars to present and discuss the most recent innovations, trends, and concerns, practical challenges encountered, and the solutions adopted in the fields.

Chemical volumes continue to rise and chemical market expected to contract this year - will expand 2.7% this year, 4.1% in 2018 and 5.0% in 2019. Growth in production volumes will accelerate and the industry will expand 3.7% in 2018 and by another 4.5% in 2019. Chemistry revenues will exceed $1.0 trillion by 2020. Over 260 new chemical production projects (valued at over $161 billion) have been announced. 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 will reach $227 billion this year and will grow steadily over the coming years.

Why Barcelona?

Sprawled between the beaches of the Mediterranean and the hills of Montjuïc, Barcelona is a city whose personality bursts at every natural seam. The capital of Catalonia, one of Spain’s 17 autonomous communities, with a population of 1.6 million, Barcelona is also known as the country’s most progressive city, always on the cutting-edge of European art, fashion and cuisine.

The chemical sector has become the second largest exporter within the Spanish economy. It is one of the basic pillars of the Spanish economy, and is made up of more than 3,300 companies. Spain was the fifth largest producer in Europe (after Germany, France, Italy and the United Kingdom), accumulating 7% of European business and 2% of international trade.

The good performance of the Spanish chemical industry over the past 30 years has also seen a progressive move towards products with greater added value. By sub-sector, pharmaceutical products account for 25% of the total, followed by plastic and rubber raw materials (15%). Also significant are organic chemicals, detergents and cleaning products, which all account for more than (9%), and paints and inks, pharmaceutical raw materials and perfumes and cosmetics, all of which account for more than 5%.

The chemical sector has become the second largest exporter within the Spanish economy. In 2016, exports exceeded €25 billion, 24% more than in 2015, when sales to foreign markets already ac­counted for more than 40% of revenues. This industry is also a leader in R&D +I investments and environmental protection, accounting for 20% of national investments in this field. Companies based in Catalonia generate 44% of the country’s total chemicals sales, followed by Madrid (16%), Valencia (8%), Andalusia (8%) and the Basque Country (4%).

Why to attend?

• Educational opportunities
• Networking with peers
• Encounter new vendors and suppliers
• Position yourself as an expert
• Gain visibility in your field

Major Chemical Engineering Associations around the Globe:

• European Federation of Chemical Engineering
• American Chemical Society (ACS)
• Canadian Society for Chemical Engineering (CSChE)
• Society of Chemical Engineers New Zealand
• Argentinian Association for Chemical Engineers
• National Organization for the Professional Advancement of Black Chemists and   
  Chemical Engineers (NOBCChE)
• Indian Institute of Chemical Engineers (IIChe)
• Society of Chemical Engineers
• Thai Institute of Chemical Engineering and Applied Chemistry
• Israel Institute of Chemical Engineers (IIChe)
• American Chemical Society
• The Electrochemical Society
• Italian Chemical Society
• Royal Netherlands Chemical Society
• Chinese Chemical Society
• Royal Australian Chemical Institute
• The Korean Chemical Society
• Japan Association for International Chemical Information

 

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TOP CHEMICAL ENGINEERING UNIVERSITIES WORLDWIDE

Pennsylvania State University | Pohang University of Science and Technology | Harvard University | University of Cambridge | University of Oxford | Massachusetts Institute of Technology | Stanford University | Johns Hopkins University | Karolinska Institute | University of California | Yale University | University College London | Imperial College London | The University of Melbourne |Euroscicon Conferences |University of California Berkeley | University of Toronto | University of California San-Diego | The University of Sydney | King’s College London | Duke University | National University of Singapore | University of Edinburgh | The University of Tokyo | University of Pennsylvania | University of Washington | Cornell University | Columbia University | University of Copenhagen | McGill University |Euroscicon | Monash University | Process Engineering Conferences | University of British Columbia | University of Michigan | The University of Queensland  | Washington University in St Louis | University of Hong Kong | Seoul National University | University of Amsterdam | University of Chicago | London School of Hygiene & Tropical Medicine | University of North Carolina | Kyoto University | Boston University Ruprecht-Karls-Universität Heidelberg | University of Zurich | Ludwig-Maximilians-Universität München | National Taiwan University | New York University | The University of New South Wales | University of Glasgow | Uppsala University |International Conference on Chemical Engineering 2018 | University of Illinois At Urbana-Champaign | Stanford University | University of Massachusetts At Amherst | University of California-Santa Barbara | Pennsylvania State University |University of Pennsylvania | Carnegie Mellon University | California Institute Technology | Rensselaer Polytechnic Inst | University of Wisconsin-Madison | University of Michigan | University of Florida | University of Minnesota | Case Western Reserve Univ | University of Texas At Austin | Chemical Engineering Conferences | Ohio State University | University of Virginia | Lehigh University | North Carolina State University |Rutgers State Univ-New Brunswick | Univ of California-Los Angeles | Arizona State University |University of Arizona | Columbia University | Brown University | University of Akron | Purdue University | Johns Hopkins University | Vanderbilt University | University of Utah | Euroscicon Conferences |University of Rochester | Virginia Polytech Inst & State U | Drexel University | State Univ of New York-Stony Brook |University of Washington | University of Mass-Lowell | Georgia Institute of Technology | University of Pittsburgh | University of Missouri-Rolla | University of Delaware | University of Southern California | Colorado School of Mines | Michigan State University | University of Maryland College Park | Stevens Inst of Technology | Duke University | University of Cincinnati | University of Alabama-Birmingham |South Dakota Sch Of Mines & Tech | Illinois Institute of Technology | Oregon Graduate Inst Sci & Tech | University of Houston | University of Notre Dame | University of Alabama-Huntsville | University of Kentucky | University of Wisconsin-Milwaukee | Auburn University | University of Vermont |

EUROPE: CHEMICAL ENGINEERING UNIVERSITIES

University of Graz | University of Innsbruck | Montanuniversität Leoben | Johannes Kepler University | Ghent University | Chemical Engineering Conferences | Ruaer Boskovia Institute  | University of Split  | University of Zagreb | Charles University | Palacký University | University of Pardubice | University of Copenhagen | Aalto University | University of Grenoble | Institute for Research in Organic Fine Chemistry  | National Graduate School of Engineering Chemistry | Lille University | Euroscicon Conferences | University of Lyon | Chimie paris tech | Laboratory Analytical Sciences  | University of Poitiers | University of Pau and Adour Country  | University of Reims Champagne  | University of Strasbourg | University in Aachen | University of Bayreuth | Technical University of Berlin  | Process Engineering Conferences | Free University of Berlin  | Ruhr University Bochum  | Euroscicon |University of Bonn  | University of Alicante | University of Barcelona  | University of the Basque Country  | University of Cádiz  | University of Granada  | University of Jaén  | University of Oviedo | University of Santiago de Compostela | University of Valladolid | University of Vigo | University of Zaragoza | Stockholm university | University of Bradford | University College Cork | Masaryk University Robert Gordon University |

US: CHEMICAL ENGINEERING UNIVERSITIES

Brigham Young University |  California State University | Case Western Reserve University | Clarkson University |Cleveland State University | Florida State University | Georgetown University | The George Washington University |Euroscicon Conferences| Governors State University | Howard University | Illinois Institute of Technology |International Conference on Chemical Engineering 2018 | Indiana University | Kansas State University | Kent State University | Marquette University |Miami University | Northeastern University | Old Dominion University |Oregon State University | Purdue University | New Brunswick Piscataway | Seton Hall University | South Dakota State University | Stevens Institute of Technology | Tufts University | University of Cincinnati | University of Georgia | University of Louisville |Process Engineering Conferences | University of Maryland | University of Missouri | The University of Montana | University of Nebraska | University of Southern Mississippi | University of South Florida | The University of Tennessee | The University of Texas at Austin |Euroscicon|  University of Toledo |Vanderbilt University | Wake Forest University | Washington State University | University of Wisconsin-Madison | University of Texas At Austin | Ohio State University | University of Virginia | Lehigh University | North Carolina State University | Rutgers State Univ-New Brunswick | Univ Of California-Los Angeles | Arizona State University | Chemical Engineering Conferences | University of Arizona | Columbia University | Brown University |University of Akron | Purdue University | Johns Hopkins University | Euroscicon Conferences|Vanderbilt University |University of Utah |University of Rochester | Virginia Polytech Inst & State U | Drexel University | State Univ of New York-Stony Brook | University of Washington | University of Mass-Lowell |Georgia Institute of Technology | University of Pittsburgh | University of Missouri-Rolla | University of Delaware | University of Southern California | Colorado School of Mines|

ASIA AND MIDDLE EAST: CHEMICAL ENGINEERING UNIVERSITIES

Nanyang Technological University | Tsinghua University | National University of Singapore | Peking University | University of Tokyo | Chemical Engineering Conferences | Zhejiang University | Nanjing University | Kyoto University | Fudan University | University of Science and Technology of China | Osaka University | Korea Advanced Institute of Science and Technology | East China University of Science and Technology | Dalian University of Technology | Euroscicon Conferences | Xiamen University | Jilin University | Nankai University | Tohoku University | National Taiwan University | Seoul National University | Shanghai Jiao Tong University | King Abdullah University of Science & Technology | Hong Kong University of Science and Technology | National Tsing Hua University | Process Engineering Conferences | Indian Institute of Science | King Abdulaziz University | Indian Institute of Technology Bombay | University of Malaya | Istanbul Technical University | University Sains Malaysia | Indian Institute of Technology Madras | Middle East Technical