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Scientific Program
International Conference on Petrochemistry and Natural Gas, will be organized around the theme “Recent Innovations in Petroleum and Chemical Industries”
Euro Petrochemistry 2020 is comprised of 19 tracks and 127 sessions designed to offer comprehensive sessions that address current issues in Euro Petrochemistry 2020.
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 and biochemical engineering are at the core of the conversion of any kind of raw materials into substances and products required by modern society. The research into and development of methods for large-scale production of drugs, inexpensive production of basic chemicals and fuels, and the economic production of advanced materials used in a wide range of areas-including communication, IT, health, and transport. Research into and development of methods for preventing and remedying environmental problems in relation to chemicals in the production, as well as research into and development of methods for sustainable chemical and biochemical energy conversion are also key fields of activity.
- Reservoir Engineering
- Agrochemicals
- Biofuel from algae
- Bioprocess engineering
- Food Technology
- Industrial Separation Techniques
- Water Science and Technology
- Pharmaceutical Engineering
- Materials Science
- Track 1-1Reservoir Engineering
- Track 1-2Agrochemicals
- Track 1-3Biofuel from algae
- Track 1-4Bioprocess engineering
- Track 1-5Food Technology
- Track 1-6Industrial Separation Techniques
- Track 1-7Water Science and Technology
Geological prospecting and exploration for oil and gas is a set of industrial and R&D activities for geological study of subsurface resources, identification of promising areas, and discovery of fields, their evaluation and pre-development. The final objective of geological prospecting is preparation of subsurface resources. The main principle of geological prospecting is the comprehensive geological study of subsurface resources when along with oil and gas exploration all associated components (petroleum gas and its composition, sulphur, rare metals, etc.), possibility and practicality of their production or utilization are investigated; hydrogeological, coal mining, engineering, geological and other studies are performed; natural, climatic, socioeconomic, geological engineering and economic indicator and their changes caused by future field development are analysed.
- Exploration Strategy
- Geophysical Methods
- Geohazards
- Seismic Data Acquisition, Processing and Interpretation Technique
- Structural Development and Basin Evolution
- Geochemistry
- Coal Geology
- Track 2-1Exploration Strategy
- Track 2-2Geophysical Methods
- Track 2-3Geohazards
- Track 2-4Seismic Data Acquisition, Processing and Interpretation Technique
- Track 2-5Structural Development and Basin Evolution
- Track 2-6Geochemistry
- Track 2-7Coal Geology
The development of drilling wells offshore in petrochemical industry offers additional energy resources. The essential seaward wellbore development process isn't altogether not quite the same as the rotational penetrating procedure utilized for arrive based boring. The primary contrasts are the sort boring equipment and changed strategies used to complete the activities in a more intricate circumstance. For offshore boring a Mechanical Properties of stable seaward stage or gliding vessel from which to penetrate must be given. These range from perpetual seaward settled or gliding stages to impermanent base bolstered or skimming boring vessels. In USA, 35% of oil is obtained through offshore development. The direction of drilling is ascertained by the dipole sharing investigation tool (DSI).
- Well Logging
- Flaring
- Offshore Drilling
- Rotary Drilling
- Land Based Drilling
- Hydraulic fracturing
- Offshore drilling
- Track 3-1Well Logging
- Track 3-2Flaring
- Track 3-3Offshore Drilling
- Track 3-4Rotary Drilling
- Track 3-5Land Based Drilling
- Track 3-6Hydraulic fracturing
Pipeline transport is the transportation of goods through a pipe. Liquids and gases are transported in pipelines and any chemically stable substance can be sent through a pipeline. Pipelines exist for the transport of crude and refined petroleum, fuels such as oil, natural gas and biofuels and other fluids including sewage, slurry, water, and beer.
Oil pipelines are made from steel or plastic tubes which are usually buried. The oil is moved through the pipelines by pump stations along the pipeline. Natural gas are lightly pressurised into liquids knows as “Natural Gas Liquids” (NGLs). Natural gas pipelines are constructed of carbon steel. Highly toxic ammonia is theoretically the most dangerous substance to be transported through long-distance pipelines, but accidents have been rare. Hydrogen pipeline transport is the transportation of hydrogen through a pipe. District heating or tele-heating systems use a network of insulated pipes which transport heated water, pressurized hot water or sometimes steam to the customer.
- Pipe Line Design, Laying, and Integration
- Intelligent Pigging-Pipelines
- Pipeline Flow Assurance
- Mixing Fluid Streams
- Slurry pipeline
- Gas-grid injection
- Track 4-1Pipe Line Design, Laying, and Integration
- Track 4-2Intelligent Pigging-Pipelines
- Track 4-3Pipeline Flow Assurance
- Track 4-4Mixing Fluid Streams
- Track 4-5Slurry pipeline
- Track 4-6Gas-grid injection
Offshore drilling is a mechanical process where a wellbore is drilled below the seabed. It is typically carried out in order to explore for and subsequently extract petroleum which lies in rock formations beneath the seabed. Most commonly, the term is used to describe drilling activities on the continental shelf, though the term can also be applied to drilling in lakes, inshore waters and inland seas.
Offshore drilling presents environmental challenges, both from the produced hydrocarbons and the materials used during the drilling operation. Controversies include the on-going US offshore drilling debate. There are many different types of facilities from which offshore drilling operations take place. These include bottom founded drilling rigs (jack up barges and swamp barges), combined drilling and production facilities either bottom founded or floating platforms, and deep-water mobile offshore drilling units (MODU) including semi-submersibles and drill-ships. These are capable of operating in water depths up to 3,000 metres. In shallower waters the mobile units are anchored to the seabed, however in deeper water (more than 1,500 metres) the semisubmersibles or drill-ships are maintained at the required drilling location using dynamic positioning.
- Offshore Vessels
- Brownfield and Rig Fleet Management
- Offshore Field Optimization
- Offshore Development
- Track 5-1Offshore Vessels
- Track 5-2Brownfield and Rig Fleet Management
- Track 5-3Offshore Field Optimization
- Track 5-4Offshore Development
Upstream oil and gas operations identify deposits, drill wells, and recover raw materials from underground. This sector also includes related services, such as rig operations, feasibility studies, and machinery rental and extraction chemical supply. Many of the largest upstream operators are the major diversified oil and gas firms, such as Exxon-Mobil.
Midstream operations link the upstream and downstream entities. Midstream operations mostly include resource transportation and storage, such as pipelines and gathering systems. Kinder Morgan and Williams Companies are two examples of midstream firms.
Refineries and marketing are major tasks in downstream operations. These services turn crude oil into usable products such as gasoline, fuel oils, and petroleum-based products. Marketing services help move the finished products from energy companies to retailers or end users. Marathon Petroleum and Phillips 66 are two noteworthy examples of downstream companies.
- Midstream/Upstream Interface Optimisation
- Hydrocarbon exploration
- Streamline Simulation
- Oil Refining Technologies
- Target Refining and Petrochemical Integration
- EPC Capability & Capacity
- Track 6-1Midstream/Upstream Interface Optimisation
- Track 6-2Hydrocarbon exploration
- Track 6-3Streamline Simulation
- Track 6-4Oil Refining Technologies
- Track 6-5Target Refining and Petrochemical Integration
- Track 6-6EPC Capability & Capacity
Biopolymers are polymers created by living beings; as it were, they are polymeric biomolecules. Since they are polymers, biopolymers contain monomeric units that are covalently attached to shape bigger structures. There are three fundamental classes of biopolymers, ordered by the monomeric units utilized and the structure of the biopolymer framed: polynucleotides (RNA and DNA), which are long polymers made out of at least 13 nucleotide monomers; polypeptides, which are short polymers of amino acids; and polysaccharides, which are frequently straight fortified polymeric starch structures. Other cases of biopolymers incorporate elastic, suberin, melanin and lignin.
- Future and Scope for Biopolymers and Bio plastics
- Industrial Biotechnology and Bio refineries
- Plastic Pollution and Waste Management
- Biomaterials and Biopolymers
- Biopolymer Companies and Market
- Bio based Thermosetting Polymers
- Flory–Huggins solution theory
- Cossee-Arlman mechanism
- Track 7-1Future and Scope for Biopolymers and Bio plastics
- Track 7-2Industrial Biotechnology and Bio refineries
- Track 7-3Plastic Pollution and Waste Management
- Track 7-4Biomaterials and Biopolymers
- Track 7-5Biopolymer Companies and Market
- Track 7-6Bio based Thermosetting Polymers
- Track 7-7Flory–Huggins solution theory
- Track 7-8Cossee-Arlman mechanism
Bioenergy describes any energy source based on biological matter-everything from a dung cooking fire or a biomass power station to ethanol-based car fuel. Unlike oil, coal or gas, bioenergy counts as a renewable energy option, because plant and animal materials can be easily regenerated. Bioenergy is often considered to be environmentally friendly because, in theory, the CO2 released when plants and trees are burned is balanced out by the CO2 absorbed by the new ones planted to replace those harvested. However, the environmental and social benefits of bioenergy are hotly contested – especially in the case of biofuels, which are often produced from food crops such as palm oil, corn or sugar.
The biofuels is sometimes used interchangeably with bioenergy, though more commonly it's used specifically to describe liquid bioenergy fuels such as biodiesel (a diesel substitute) and bioethanol (which can be used in petrol engines).
- Production of Biofuels
- Bioenergy Applications
- Biomass and Biodiesel
- Biogas and Bioethanol
- Aviation biofuels
- Bio-refineries
- Bioethanol for Sustainable Transport
- Greenhouse gas emissions
- Ecological sanitation
- Track 8-1Production of Biofuels
- Track 8-2Bioenergy Applications
- Track 8-3Biomass and Biodiesel
- Track 8-4Biogas and Bioethanol
- Track 8-5Aviation biofuels
- Track 8-6Bio-refineries
- Track 8-7Bioethanol for Sustainable Transport
- Track 8-8Greenhouse gas emissions
- Track 8-9Ecological sanitation
This field amalgamate facet of organic, organometallic, and inorganic chemistry. Synthesis forms a considerable component of most programs in this area. Mechanistic scrutiny are 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. Re-organization of a compound into smaller and simpler compounds, or compounds of lofty molecular weight, under elevated temperatures usually in the range of 400°C to 800°C to as high as 1400°C. It differs from combustion in that it occurs in the absence of air and therefore no oxidation takes place. The pyro-lytic disintegration of wood forms a large number of chemical substances. Some of these chemicals can be used as substitutes for conventional fuels. The dispersal of the products varies with the chemical composition of the biomass and the operating conditions.
- Catalysis for Chemical Synthesis
- Bio-catalysis, Biotransformation
- Organometallic catalysis and Organ catalysis
- Spectroscopy in Catalysis
- Photo Catalysis and Nano Catalysis
- Environmental and green catalysis
- Applications of analytical pyrolysis
- Track 9-1Catalysis for Chemical Synthesis
- Track 9-2Bio-catalysis, Biotransformation
- Track 9-3Organometallic catalysis and Organ catalysis
- Track 9-4Spectroscopy in Catalysis
- Track 9-5Photo Catalysis and Nano Catalysis
- Track 9-6Environmental and green catalysis
- Track 9-7Applications of analytical pyrolysis
To produce materials for industry, like chemicals, plastics, food, agricultural and pharmaceutical products and energy carriers. Industrial biotechnology, which is often referred as white biotechnology utilizes microorganisms and enzymes. Waste generated from agriculture and forestry and renewable raw materials are used for the production of industrial goods. It also contributes to lowering of greenhouse gas emissions and moving away from a petrochemical based economy.
Bioprocess engineering is an essential component for rapid conversion of bio products from the laboratory to a manufacturing scale. This makes the benefits of biotechnology on a large scale at a reasonable cost for common people. Bioprocess engineering may include the work of mechanical, electrical, and industrial engineers to apply idea and knowledge of their domains and process based on using living cells.
- Molecular Bio-sensing, Bio-robotics and Biomarkers
- Biotechnology in Vaccine Production
- Biochemistry and Protein Engineering
- Biomaterials, Bio polymers & Biosensors
- Microbial Biotechnology and Food Processing
- Pharmaceutical and Medical Biotechnology
- Petroleum Biotechnology and Green chemicals
- Industrial and Chemical Biotechnology
- Environmental Biotechnology and Waste Water Management
- Track 10-1Molecular Bio-sensing, Bio-robotics and Biomarkers
- Track 10-2Biotechnology in Vaccine Production
- Track 10-3Biochemistry and Protein Engineering
- Track 10-4Biomaterials, Bio polymers & Biosensors
- Track 10-5Microbial Biotechnology and Food Processing
- Track 10-6Pharmaceutical and Medical Biotechnology
- Track 10-7Petroleum Biotechnology and Green chemicals
- Track 10-8Industrial and Chemical Biotechnology
- Track 10-9Environmental Biotechnology and Waste Water Management
Green chemistry otherwise called as sustainable chemistry, which is part of chemistry and chemical engineering focused on designing products and by minimizing the generation and use of hazardous substances .whereas, environmental chemistry focuses on the effects chemicals polluting the nature, green chemistry focuses on technological ways to prevent pollution and by reducing the consumption of non-renewable resources.
Catalysis is the defined as the substance which only alters the rate of the reaction without changing is nature. In order to achieve objectives of the Green chemistry, catalysis plays a fundamental role. The main goal of green chemistry is to provide an eco-friendly, reusable, recyclable and minimum waste production and green catalysis design the chemical products in a way that reduces or eliminates the use and generation of hazardous substances.
- Design of Next Generation Catalysis
- Nanotechnology and Green catalysis
- Green energy and power
- Green Chemistry in Pharmaceuticals
- Green catalysis in Petrochemical Industries
- Enhanced geothermal system
- Green economy
- Track 11-1Design of Next Generation Catalysis
- Track 11-2Nanotechnology and Green catalysis
- Track 11-3Green energy and power
- Track 11-4Green Chemistry in Pharmaceuticals
- Track 11-5Green catalysis in Petrochemical Industries
- Track 11-6Enhanced geothermal system
- Track 11-7Green economy
Industrial gases are a group of gases that are specifically manufactured for use in a wide range of industries, which include oil and gas, petro chemistry, chemicals, power, mining, steelmaking, metals, environmental pollution, medicine, pharmaceuticals, biotechnology, food, water, fertilizers, nuclear power, electronics and aerospace. The main gases provided are nitrogen, oxygen, carbon dioxide, argon, hydrogen, helium and acetylene; although a huge variety of natural gases and mixtures are available in gas cylinders. The industry producing these gases is known as the industrial gases industry, which is seen as also encompassing the supply of equipment and technology to produce and use the gases.
Whilst most industrial gas is usually only sold to other industrial enterprises; retail sales of gas cylinders and associated equipment to tradesmen and the general public are available through gas local agents and typically includes products such as balloon helium, dispensing gases for beer kegs, welding gases and welding equipment, LPG and medical oxygen.
- Gas Conversion Technologies
- Gas Compression
- Gas Field Developments
- Gas Storage and Transport
- Track 12-1Gas Conversion Technologies
- Track 12-2Gas Compression
- Track 12-3Gas Field Developments
- Track 12-4Gas Storage and Transport
Simulation modelling is the process of creating and analysing a digital prototype of a physical model to predict its performance in the real world. It is used to help engineers understand whether, under what conditions, and in which ways a part could fail and what loads it can withstand. It can also help predict fluid flow and heat transfer patterns. It allows designers and engineers to avoid repeated building of multiple physical prototypes to analyse designs for new or existing parts. Before creating the physical prototype, users can virtually investigate many digital prototypes.
- Modelling of Bioprocesses
- Simulation and Separation Equipment Design
- Simulation, Optimization, Planning and Control of Processes
- Agent-based Model
- Individual-Based Models
- Micro scale and Macro scale Models
- Track 13-1Modelling of Bioprocesses
- Track 13-2Simulation and Separation Equipment Design
- Track 13-3Simulation, Optimization, Planning and Control of Processes
- Track 13-4Agent-based Model
- Track 13-5Individual-Based Models
- Track 13-6Micro scale and Macro scale Models
Nano chemistry can 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 bio analytical 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 Nano medicine is one of the medical applications of nanotechnology. It ranges from the medical applications of nanomaterial’s to Nano electronics biosensors, and the future applications of molecular nanotechnology, such as biological machines. Nano medicine sales reached $16 billion in 2015, with a minimum of $3.8 billion in nanotechnology R&D being invested every year.
- Nano electronics Bio-Sensors
- Tissue Engineering
- Nano Topography, Medicine and Enzymes
- Nano Pharmaceutical Chemistry
- Organic Materials in Nano chemistry
- Nano-Electromechanically Systems
- Application and Commercialization of Nanotechnology
- Biomedical Applications and Bioelectronics
- Track 14-1Tissue Engineering
- Track 14-2Nano Topography, Medicine and Enzymes
- Track 14-3Nano Pharmaceutical Chemistry
- Track 14-4Organic Materials in Nano chemistry
- Track 14-5Nano-Electromechanically Systems
- Track 14-6Application and Commercialization of Nanotechnology
- Track 14-7Biomedical Applications and Bioelectronics
- Track 14-8Nano electronics Bio-Sensors
The marine drugs which are obtained from marine organisms are known as marine drugs. These marine drugs are used since ancient times. And interestingly, innumerable products derived from the marine organisms in several 'crude forms' have been widely used across the globe by the traditional practitioners for thousands of years. The study of marine biology includes a wide variety of disciplines such as astronomy, biological oceanography, cellular biology, chemistry, ecology, geology, meteorology, molecular biology, physical oceanography and zoology and the new science of marine conservation biology draws on many longstanding scientific disciplines such as marine ecology, biogeography, zoology, botany, genetics, fisheries biology, anthropology, economics and law.
- Marine Pollution
- Marine Natural Products Chemistry
- Marine Chemical Biology
- Ocean Biogeochemistry
- Fisheries Biology and Management
- Marine heavy metals poisoning marine toxicology
- Ocean Acidification
- Track 15-1Marine Pollution
- Track 15-2Marine Natural Products Chemistry
- Track 15-3Marine Chemical Biology
- Track 15-4Ocean Biogeochemistry
- Track 15-5Fisheries Biology and Management
- Track 15-6Marine heavy metals poisoning marine toxicology
- Track 15-7Ocean Acidification
Petro chemistry is a process which researches on the conversion of petroleum or crude oil and natural gas into raw materials and helpful products. Petro chemistry makes a huge contribution to the advancement attained in the 20th century in the fields of universal healthcare and sanitation. The majority of products in Pharma are manufactured from chemicals and a significant number of these medicines are manufactured from petroleum goods. Pharmaceutical chemical engineering is a department of Chemical Engineering that mainly deals with the design and construction of unit operations that involve biological organisms or molecules, such as bioreactors. Its applications are in the petrochemical industry, food and pharmaceutical, biotechnology, and water treatment industries.
- New Concepts and Innovations
- Safety and Hazard Developments
- Chemical Reaction Engineering
- Process Design and Analysis
- Track 16-1New Concepts and Innovations
- Track 16-2Safety and Hazard Developments
- Track 16-3Chemical Reaction Engineering
- Track 16-4Process Design and Analysis
Environmental chemistry is the scientific review of the chemical and biochemical phenomena that occur in natural places. Environmental chemistry can be described as the study of the sources, reactions, transport, effects of chemical species in the air, soil, and water environments; and the effect of human activity on these. Environmental chemistry is an integrative science that includes atmospheric, aquatic and soil chemistry, as well as uses analytical chemistry. It is allied to environmental and other areas of science. It is different from green chemistry, which tries to trim potential pollution at its source. Whereas Environmental engineering deals with the combination of sciences and engineering principles to develop the natural environment, to provide healthy air, water, and land for human habitation and for other organisms, and to procure pollution sites.
- Green Chemistry
- Environmental Toxicology and Mutagenicity
- Environmental Geology
- Chemical and Polymer Engineering
- Renewable Energy Sources and Storages
- Environmental Technologies and sustainability Metrics
- Track 17-1Green Chemistry
- Track 17-2Environmental Toxicology and Mutagenicity
- Track 17-3Environmental Geology
- Track 17-4Chemical and Polymer Engineering
- Track 17-5Renewable Energy Sources and Storages
- Track 17-6Environmental Technologies and sustainability Metrics
Pollution prevention reduces the amount of pollution generated by industry, agriculture, or consumers. In contrast to pollution control strategies which seek to manage a pollutant after it is emitted and reduce its impact upon the environment, the pollution prevention approach seeks to increase efficiency of a process, 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.
- Biogeochemical cycles
- Bioreactor and Photovoltaic
- Desalination
- Hydrogen fuel cell
- Thermal depolymerisation
- Track 18-1Biogeochemical cycles
- Track 18-2Bioreactor and Photovoltaic
- Track 18-3Desalination
- Track 18-4Hydrogen fuel cell
- Track 18-5Thermal depolymerisation
Environment, Health & Safety (EHS) programs are so prevalent across global manufacturing organizations, at first thought, providing a definition can feel redundant and unnecessary. Environmental Health and Safety Managers work with and for organizations (private and public sector) to promote good working practices for employees. Mostly, they observe these organizations to ensure that they comply with environmental legislation regarding safety in the workplace. When they work in environmental roles, it is about ensuring that steps are taken to protect the environment from the actions of the organization, and ensuring that people are protected from the environment.
- Occupational Safety and Health
- Physical and Chemical hazards
- Radiological Hazards
- Hazardous Materials Management
- Wastewater and Ambient Water Quality
- Track 19-1Physical and Chemical hazards
- Track 19-2Radiological Hazards
- Track 19-3Hazardous Materials Management
- Track 19-4Wastewater and Ambient Water Quality
- Track 19-5Occupational Safety and Health