Euroscicon honored to welcome all the participants for the upcoming CPD accredited “7th Edition of International Conference and Exhibition on Separation Techniques” to be held from July 5-7, 2018 at Berlin, Germany. The main goal of this Separation Techniques 2018 conference is to make a breakthrough in the field of separation science by bringing together all the persons related to this sector around the world. So, this international conference is designed in such a way to display their ideas, theories, analyses, innovations through Keynote presentations, Oral Talks, Poster presentations, Yonug Research Forum, Symposiums, Workshops, and Exhibitions.
The theme of this conference is “Launching the innovative ideas and technologies of Separation Techniques “which will provide an international platform for the discussion of current trends in separation techniques. This event gathers all the eminent persons, professors, professionals, students, and industrialists all over the world to exchange their ideas, researches and to exhibit their novel instruments. Separation Techniques 2018 provides an opportunity to discuss and learn about the innovative ideas and technologies inherited in various fields like Analytical chemistry, Biochemistry, Instrumentation chemistry, Nanotechnology, Geochemistry, Pharmaceutical chemistry, Membrane science, Organic Chemistry as well as about the novel technologies in separation science, chromatography, spectroscopy, mass spectrometry, hyphenated techniques along with the investigations conducted with these techniques. This conference also provides a podium to exhibit the brand-new equipment relate to separation techniques for the industries and companies in which they can be benefited in the global market moreover they can upgrade their product value.
Separation techniques are those techniques that can be used to separate two different states ofmatter such as liquid and solid. Such separation techniques include filtration or evaporation. Separation process, or a separation method, or simply a separation, is a methodology to attain any mass transfer phenomenon that converts a mixture of substances into two or more distinct product mixtures.Seperation Techniques are essential unit operation in the greater part of the current compound, pharmaceutical and different process plants. There are numerous standard and traditional partition methods accessible in the market and these strategies are very normal and the pertinent advances and also all around created and all around contemplated. Then again, more current partition forms, similar to, layer based procedures, chromatographic division, super basic liquid extraction, and so forth., are picking up significance in present days plants.
Why to attend our conference
This event will provide an opportunity to build and expand your network with various people and gives chance to make collaboration with other universities and research labs. It also helps you to meet the experts in the relevant field of study. It gives the access to novel instruments in the market. This conference plays a major role in your business development and maximizes the profit.
Separation Techniques 2018 keenly focuses on the following people
Eminent Scientists who work with separation instruments
Directors / Head of Analytical chemistry
Principal Investigators, Research lab Scientists, Research Scholars
Professors & Associate Professors of Analytical / organic / Geochemistry / Refining Chemistry
Directors/ Scientists of Analytical Instruments companies
Experts in Chromatography, Mass Spectrometer, Spectroscopy, NMR etc.
Theoretical Scientists working on deriving analytical hypotheses
Experts from Pharmaceutical, Chemical Industries
Industrial Experts related to Separation Instruments.
Research lab scientists, scholars working with separation Instruments.
Relevant Post-graduates, Graduates, Technicians, Students.
Poster Competition (Winner will get Best Poster Award)
Young Researcher Forum (YRF Award to the best presenter)
Book Launch event
Exhibitor and Vendor booths
Marketing and Networking with clients
Germany's location at the heart of Europe has shaped its history both for good and bad. It is the fifth largest country in Europe and shares its border with nine neighbor countries. Germany's central and southern regions have forested hills and mountains cut through by the Danube, Main, and Rhine river valleys. In the north, the landscape flattens out to a wide plain that stretches to the North Sea. Between these extremes, Germany is a country of incredible variety. Germany is the land of cultural heritage where it is known for its famous historical spots and world class institutions. It has been called the "Land of Poets and Thinkers." Germans are famous in all forms of art, but particularly classical music. Germany's famous composers include Bach, Brahms, Schumann, Wagner, and Beethoven and some of the world's greatest philosophers include Kant, Hegel, Schopenhauer, Nietzsche, and Heidegger are from Germany. This country boasts some of the world's most famous inventions like the light bulb, insulin, the automated calculator, and the automobile. Germany has more cultural activities and places than any other country – it's a cultured place, with 6,200 museums, 820 theaters, 130 professional orchestras and 8,800 libraries. Berlin is the capital of Germany featured with art museums, and other historic places. A feature of Berlin, aside from its exuberance, is the way it continuously reinvents itself. It also called as greener city of Germany by its forests, lakes and sprawling parks.
Don’t miss to visit
Berlin's Brandenburg Gate
The Black Forest
Fairytale Castle: Neuschwanstein
Cologne Cathedral (Kölner Dom)
Museum Island in Berlin
The Island of Rügen
is an approach to achieve any phenomenon that converts a mixture of chemical substance into two or more distinct product mixtures. Separation techniques plays a major role in almost all industrial process and sectors like petroleum, chemical, pharmaceutical
, food technology, biotechnology, mining industries, wastewater management. Separation between constituents can be done by the standard and traditional methods like distillation, sedimentation, drying, absorption and adsorption process. Besides these techniques there are many more newer separation process like membrane filtration
, extraction, fractionation
etc. are gaining our attention in this modern era by accomplishing purified component
Many advanced instruments employ different sample preparation techniques and it’s also specific to each instrument. Separation techniques
, need samples which suits the instrument. Discussion on this topic gives the clear knowledge about the sample preparation and it can be used effectively for the analysis.
Separation process involved between biomolecules like proteins, amino acids, sugars, cells, tissues, Microorganisms which can separated by using various techniques like electrophoresis, centrifugation, cytometry, elucidation are dealt under this topic.
is the branch of science that deals with biomolecules and their chemical processes within the living system. It focuses on what’s happening inside our cells, studying components like proteins, nucleic acids, organelles, signaling pathways and their metabolism to learn about these particles techniques like centrifugation
are being used. This session confers about the techniques used in biochemistry.
is an analytical technique which ionizes molecules and sort those ions based on their mass to charge ratio. Basically, it measures the mass within the sample and used to investigate the structure of materials to attain the quality spectra. Identification of unknown peaks in gas chromatography (GC/MS)
-based discovery in order to find the protein metabolomics is challenging, and it remains necessary to permit discovery of novel or unexpected metabolites in the signaling pathways and/or further our understanding of how genotypes relate to phenotypes of that genomic series. It also considered to be important for the protein discovery and further research process. New mass spectrometry
(MS) methods, collectively known as data independent analysis and hyper reaction monitoring, have recently emerged. Mass spectrometry is an analytical tool used for measuring the molecular mass of a sample.
is the study of communication between particles and electromagnetic radiation where it involves scattering, absorption, reflection or transmission of materials. The intensity of interaction between these materials gives the data about the physical properties of the substance. This track deals with various spectroscopy techniques
which act as a basic analysis before separation.
Separation Process are technical procedures which are used in industry to separate a product from impurities or other products. The original mixture may either be a natural resource (like ore, oil or sugar cane) or the product of a chemical reaction (like a drug or an organic solvent). Separation processes are of great economic importance as they are accounting for 40 – 90% of capital and operating costs in industry. The separation processes of mixtures are including besides others washing, extraction, pressing, drying, clarification, evaporation, crystallization and filtration. Often several separation processes are performed successively. Separation operations are having several different functions
Purification of raw materials and products and recovery of by-products
Recycling of solvents and unconverted reactants
Removal of contaminants from effluents
Hybrid separation techniques
or hyphenated techniques is the combination of mass spectrometry and chromatography in which the particles can be detected and then separated accordingly by chromatographic separation technique. The term Hyphenated techniques ranges from the blend of division ID, hyphenated systems, e.g., GC-MS, LC-MS
, LC-FTIR, LC-NMR, CE-MS, and so forth. Hyphenated procedures along with chromatographic
and ghostly techniques (mass spectrometer
) to abuse the benefits of both partition detachment methods. These systems demonstrate specificity and affectability. A Hyphenated system is mix or coupling of two distinctive systematic strategies with the assistance of two legitimate interfaces. Advancements in hybrid separation techniques over the past decade has significant outgrowth which added a new dimension to the separation techniques especially for the analysis of biomaterials.
is a science of intermolecular interactions and transport molecules or particles in a system of mutually immiscible phases moving relative to each other leading to the formation of concentration zones of individual components of original mixtures of substances or particles. Chromatography
is a partition method that each scientific expert is familiar with the technique.
is the study deals with physical and chemical nature of organic materials which contains carbon atoms. Chiral separation techniques are gained the importance in biotech and pharma field since all the natural products are composed of bio-organic molecules. Chiral separation techniques
separate racemic compounds into enantiomers of that organic molecules. It is one of the analytical technique in organic chemistry which involves D and L forms of sugars, amino acids. This track deals with the separation techniques involved in organic chemistry.
is a classification of analytical chemistry which used to find composition of inorganic materials. Detecting and separation of ions from other compounds. Supramolecular chemistry
is the study focuses on the chemical system rather than molecules. It deals with the molecular assembly where two or more compounds interact with weak electrostatic to strong covalent bonding provided with electronic coupling between molecules.
Separation and purification techniques
is an important aspect in this modern era. It involved in separation and purification of homogenous and heterogenous mixtures to its purest form. Separation is the segregation of different types of solid waste at the location where they are generated (a household or business). The number and types of categories into which wastes are divided usually depends on the collection system used and the destination of the wastes. The most common reason for separating wastes at the source is for recycling. To reduce the environmental impact of waste disposal, the Environmental Protection Agency (EPA)
encourages communities to develop strategies to decrease landfill use and lower the risks and inefficiencies of incineration. Waste reduction and recycling are considered to be the most environmentally beneficial methods to manage waste. Increasing concentrations of greenhouse gases (GHGs) such as CO2 in the atmosphere is a global warming. Human activities are a major cause of increased CO2 concentration in the atmosphere, as in recent decades, two-thirds of the greenhouse effect was caused by human activities. Carbon capture and storage (CCS) is a major strategy that can be used to reduce GHG emissions. There has been an accompanying increase in interest in the academic community in environmental issues and research on ways to treat environmental problems. Separations
could be used to concentrate contaminants for eventual destruction or immobilization and to remove contaminants and concentrate or purify them to the point where they can be used again and no longer be considered contaminants. Applications of separation methods
are expected to increase as efforts are made to reduce waste volumes, reuse contaminants in inlet streams even further, or to remove containments from soils and groundwater. Separation operations are currently important in almost every aspect of waste and environmental treatment. This track deals with techniques involved in separation and purification in various fields like green chemistry
, containments of environment and instrumentation of the technique.
Separation techniques employed to treat and separate impurities of water. Desalination
is the process of that extracts mineral components from saline water. More generally, desalination refers to the removal of salts and minerals from a target substance, as in soil desalination, which is an issue for agriculture.
In chemical engineering
sector separation process is the transfer of mass substance into two or more distinctive mixtures. This separation process proceeded based on their differences in chemical properties or chemical properties such as size, shape, mass, density or chemical affinity, between the constituents of mixtures. The separation process in chemical engineering is comprised of absorption, adsorption, floatation, fractionation
, precipitation, magnetic separation, crystallization, electrochemical separation,
is an innovation which specifically isolates (fractionates) materials by means of pores as well as moment holes in the sub-atomic course of action of a nonstop structure. Layer detachments are characterized by pore size and by the division driving force. Membrane separation is a technique that separate solvent and solute particles with help of semi permeable membranes. Membrane innovation is a non-specific term for various extraordinary, exceptionally trademark partition forms. These procedures are of a similar kind, because in each of them a film is utilized. Membrane films
are utilized frequently for the purification of groundwater, surface-water, and wastewater
. Recent advances in membrane separation technology attained a new dimension in this era.
is the emerging field that deals with Nano particles this track confers the information about the separation techniques used in nanotechnology. It is a branch of science that exploring the new dimension in the Nano level which leads into the discovery of new drugs, treatments, user friendly equipment, technologies, etc. This generation is now focusing on the Nano & Pico level experiments
& technologies which leads to newer version of science.
This track covers all the key areas in Separation Science that includes, Adsorption, Centrifugation, Extraction, Crystallization, Evaporation, Electrostatic separation
, Crystallization, Distillation, Flotation, microfiltration, Flocculation, Filtration membrane processes
, Fractional distillation, Precipitation, Sublimation, Vapor-liquid separation, Sedimentation, Gravity separation, Electrophoresis, Ultrafiltration, Chromatography, cyclonic separation, Froth flotation, Reverse osmosis, dialysis (biochemistry), Desalination
, Wastewater Treatment
etc. which are developing in a rapid speed to make a betterment of Analytical Science.
Innovations in separation science for improved sensitivity and cost-efficiency, increased speed, higher sample throughput and lower solvent consumption in the assessment, evaluation, and validation of emerging drug compounds. It investigates breakthroughs in sample pretreatment
, HPLC, mass spectrometry, capillary electrophoresis
and therapeutic drug monitoring for improved productivity, precision, and safety in clinical chemistry
, biomedical analysis
, and forensic research. The most common instrumental chromatographic method used in the clinical laboratory is the gas-liquid chromatography
. Separation Techniques
in Clinical Chemistry is a thorough single-source guide for analytical, organic, pharmaceutical, medicinal, physical, surface, and colloid chemists and biochemists; and upper-level undergraduate and graduate students in these disciplines. Four detection methods commonly used with gas chromatography are thermal conductivity, flame ionization, nitrogen/phosphorous, and mass spectrometry
. The thermal conductivity detector takes advantage of variations in thermal conductivity between the carrier gas and the gas being measured. Advances in Chromatographic Techniques for Therapeutic Drug Monitoring
is a comprehensive reference describing the theory and application of therapeutic drug monitoring in clinical laboratories. The technological innovations in clinical chemistry analyzers have led to early disease detection and specialized diagnosis in the areas of oncology, gynecology, & endocrinology and enabled testing on a larger scale. The advancements comprise advanced modeling & parameter estimation, better resolution, improved pattern recognition, computer-assisted interpretation
, and artificial intelligence. This Track confers about the information about the separations in clinical chemistry
plays a major role in all aspects of our daily life products it became a part and parcel of our environment. Raw materials which is of different forms and phases but can be separated to its purest constituent. The importance of separation techniques of different fields like biotechnology, forensic studies, mining industries
, food technology, pharmaceutical industry
, petroleum industries.
Mineral ores are one of the basic raw materials which should be separated and purified to their mineral forms. Mineral ore can be separated according to their particle sizes, physical properties and chemical properties. Separations are made by chemical treatments
and they are subject to quality control in each sector to reach its economic grade by separating all other impurities.
The Separation Techniques industry
is indicating development quickly, with esteem anticipated that would hit 240 billion dollars by 2017, up from 164 billion dollars in the year 2010, stamping yearly development of about 7%, as per a current modern research report.
Geologically, worldwide detachment innovations advertise has been portioned into four zones to be specific, North America, Europe, Asia-Pacific and Rest of the World. Separation techniques industry which is comprised of several equipment like chromatography, centrifuges
, spectrometry, electrophoresis
, is one of the emerging field which shows the greater impact in the market.
is a separation technique in terms of phase transition
. It most probably used in all research and industrial sectors. Magnetic separation
is used to separate materials which are susceptible to the magnetic field. Magnetic Separation
is the way toward utilizing attractive drive to expel metallic or ferrous materials from a mixture. This track deals with separations based on the magnetic field coupled with electric current, electrostatic separation, and polarizing separation.
process are based on differences in the kinetic properties of the components of mixtures,such as the velocity of migration in a medium or of diffusion through a semipermeable barriers
Adsorption and Chromatography
Membrane separation processes
Separation Techniques are used to separate particles of different or same phases. Techniques inherited to attain the separation phenomena of two or more distinct products from the mixture of substances. This separation process can be done with the help of techniques like chromatography, electrophoresis, mass spectrometry, spectroscopy, membrane separation, etc. The market analysis of separation technologies can be described as follows.
The global membrane separation technology market is projected to reach USD 28.10 Billion by 2022 at a CAGR of 7.2%. The base year considered for the study is 2016 while the forecast period is from 2017 to 2022. Membrane separation technology is used to separate and purify a specific component from the rest of the mixture. This technology is widely used for commercial and industrial purposes. Certain properties of membrane separation technology, such as durability, porosity, permeability, stability, and selectivity, make it indispensable in various industrial applications. The membrane separation technology is widely used in water & wastewater treatment, industrial, laboratory, medical, food & beverages, and research applications to purify, concentrate, sterilize, or separate samples.
The global chromatography instruments market is projected to be valued at USD 7.86 Billion in 2017 and is expected to grow at a CAGR of 6.9% to reach to USD 10.99 Billion by 2022. The growth of the overall chromatography instruments market can be attributed to the rising food safety concerns, increasing use of chromatography tests in the drug approval process, and growing popularity of hyphenated chromatography techniques.
Mass spectrometry is an analytical technique used to identify compounds present in a sample by measuring the mass-to-charge ratio. The market is segmented based on platform and application. The mass spectrometry market, by platform, is segmented into hybrid mass spectrometry, single mass spectrometry, and other mass spectrometry. The mass spectrometry market is expected to reach USD 7,279.1 Million in 2020 from USD 4,919.1 Million in 2015 at a CAGR of 8.1%.
The process spectroscopy market is expected to grow to USD 22.04 Billion by 2020, at a CAGR of 8.72% between 2015 and 2020 and the global molecular spectroscopy market is projected to be valued at USD 4.68 Billion in 2017 and is expected to grow at a CAGR of 6.6% to reach to USD 6.85 Billion by 2022. The growth of the overall molecular spectroscopy market can be attributed to the growing food safety concerns, the growth of the pharmaceutical and biotechnology industry, application of molecular spectroscopy in environmental screening and technological advancements in molecular spectroscopy.
The global electrophoresis market is expected to reach USD 2.15 Billion in 2017, growing at a CAGR of 5.4% during the forecast period. Several factors, such as the growth in funding for research on electrophoresis techniques, increasing the number of research collaborations between market players and academic institutions, increasing use of capillary electrophoresis (CE) with mass spectroscopy (MS), and growing focus on next-generation sequencing research are driving the growth of the electrophoresis market. The base year considered for the study is 2016 and the forecast period includes 2017 to 2022. The future growth prospects for the protein crystallization market are optimistic which is estimated to grow at a CAGR of 10.1% to reach a worldwide market of $1,253 million by 2018
The global process analyzers (liquid & gas) market is expected to grow to USD 4.98 Billion by 2020, at an estimated CAGR of 5.50% between 2015 and 2020. This market is driven by the increase in the shale gas production in the U.S. In addition, the gas chromatography market is projected to reach USD 3.90 Billion by 2020, at a CAGR of 8.60% between 2015 and 2020.
The global gas separation membranes market is projected to reach USD 2.61 Billion by 2022 at a CAGR of 7.2% forecast period. The base year considered for the study is 2016 while the forecast period is from 2017 to 2022.
The global air separation plant market is projected to reach USD 7.27 Billion by 2026, at a CAGR of 5.3% from 2016 to 2026. The market is expected to witness growth in the coming years owing to the increasing demand for iron & steel around the world, coupled with stringent policies and measures taken by countries to promote the safe use of air separation methods for industrial applications.
The global analytical standards market is projected to reach USD 1.73 Billion by 2022 from USD 1.27 Billion in 2017, at a CAGR of 6.3%. And the global analytical laboratory services market, by public health organization, is projected to reach USD 333.8 Million by 2021 from USD 202.8 Million in 2016, at a CAGR of around 10.5% during the forecast period. The overall market, by public health organization, is positively impacted by factors such as the growing expenditure on drugs and medical devices by public health organizations, government initiatives to strengthen analytical testing capabilities, increasing number of drug approvals & clinical trials, and rising demand for specialized analytical testing services.
The global healthcare analytical testing services market is estimated to grow at a CAGR of 11.3% from 2017 to 2021 to reach USD 4.13 Billion by 2021. The growing demand for analytical services for biologics and large-molecule drugs, increasing outsourcing of analytical testing by pharmaceutical companies, rising demand from the nutraceutical industry and increasing acceptance of the QbD (Quality by Design) approach in pharma research/manufacturing are the major factors driving the growth of the global market.
Top Separation Techniques Universities World wide:
University of Maryland | University College London | University of Minnesota | Imperial college of London | Oregon State University | University of Lowa Wake | Forest University | Penn State College | Boston University | Trinity College | Hunter College | King College Old Dominion University | University of Calcutta | University of Exeter | Baylor College | University of Leicester | University Of Montana | Swansea University | Lycoming Colleges | National College | University of California | UCD Science Centre | Skaggs the School of Pharmacy | The University of Houston | Biyani Colleges | University of Cambridge | University Of Kentucky | University of Vermont | University of Michigan--Ann Arbor | Jilin University | Nankai University | University of Toronto | Tohoku University | Princeton University | University of North Carolina | University of Minnesota | National Taiwan University | University of Pennsylvania | Seoul National University | Cornell University | University of California| New York University | Ruprecht Karls Universität | Aarhus University | Baylor College of Medicine | Brown University | Cardiff University | Dartmouth College | Freie Universität Berlin | Katholieke Universiteit Leuven | London School of Hygiene & Tropical Medicine | Ludwig Maximilians Universität | Lund University| Maastricht University | Mayo Medical School | National Taiwan University | Northwestern University | Osaka University | Pennsylvania State University | Purdue University | Queen Mary University | Technische Universität | The University of Adelaide | The University of New South Wales | The University of Sheffield | The University of Western Australia | Trinity College Dublin | Tufts University | Université Catholique de Louvain | Université de Montréal | University of Aberdeen| University of Alberta | University of Amsterdam | University of Bath | University of California | University of Copenhagen | Massachusetts Institute of Technology | University of Oxford | Stanford University | Yale University | University of California | Johns Hopkins University | Imperial College London | University of California | University of Cia Institute of Technology | University of Toronto | McGill University | Duke University | University of Melbourne | Columbia University | National University of Singapore | University of Chicago| The University of Tokyo | University of Pennsylvania | University of Michigan | Cornell University | University of Washington | University College London | Karolinska Institute| Sweden Rockefeller University | University of Edinburgh | The University of Sydney | University of London | University of British Columbia | The University of Manchester | University of Queensland | University of Wisconsin Madison | Boston University | Monash University | University of Texas | Kyoto University | The University of AucklandWashington University | Humboldt Universität ZU Berlin | Erasmus University | Leiden University | McMaster University | University of Hong Kong| Australian National University | University of Helsinki | University of Bristol
University of Cádiz | University of Extremadura | 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 | Sheffield Hallam University | University of Southampton | University of Warwick
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 | University of Maryland
| University of Missouri-Columbia | Brigham Young University
| California State University | California State University | Case western Reserve University | Clarkson University
| Cleveland State University | Florida State University | Georgetown University | The George Washington University | Governors State University | Howard University
| Illinois Institute of Technology | Indiana University Bloomington | Kansas State University | Kent State University | Marquette University | Miami University | Northeastern University | Old Dominion University | lorida State University
| Georgetown University | The George Washington University
| Governors State University | Howard University | Illinois Institute of Technology | Indiana University Bloomington | 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 | University of Maryland
| University of Missouri
Separation Techniques Conferences:
World Analytical Conferences
and Bioanalytical Techniques Conferences September 17, 2018, Singapore City, Singapore; 5th Annual Asia Chemical Conferences, November 01, 2017, Singapore; World Analytical Conferences
and Bioanalytical Techniques
Conferences September 17, 2018 Singapore City, Singapore; Global Experts Chemistry Conferences May 17, 2018 Singapore City, Singapore pharma analyis Dubai, UAE; Annual Analytical Conferences
and Separation Techniques Conferences
October 12, 2017 Osaka, Japan
5th International Separation Techniques Conferences
October 23, 2017 Paris, France; 4th International Physical Chemistry Conferences and Theoretical Chemistry Conferences September 18, 2017 Dublin, Ireland; 3rd International Exhibition on Advances in Chromatography Conferences and HPLC Techniques Conferences
July 13, 2017 Berlin, Germany; 3rd International Electrochemistry Conferences
July 10, 2017 Berlin, Germany;World Analytical Conferencesand Bioanalytical Techniques Conferences
September 17, 2018, Singapore; 6thInternational Advances in Chromatography Conferences
and HPLC Techniques Conferences August 02, 2018, Barcelona, Spain; 8th Annual Analytical Conferencces
and Bioanalytical Techniques Conferences Brussels, Belgium August 28, 2017; 8th European Chemistry Congress
June 21, 2018 Paris, France; Extractables Conferences
and Leachables Conferences
2017, 07 November 2017, Lyon, France; Eletronic Structure Conferences and Spectroscopy of Transition Metal Complexes Conferences 03 September 2017 , Gelsenkirchen, Germany; HPLC Methods Conferences
26 October 2017, Dublin, Ireland; 7th Edition Multivariate Analysis and Chemometry Conferences
27 May 2018, Lecce, Italy; IEASI-2017 International Expo on Analytical Sciences Conferences and Instrumentation Conferences 06 November 2017, Barcelona, Spain; Polymorphism Conferences
and Crystallisation Conferences
03 October 2017, Edinburgh, United Kingdom
18th World Analytical Conferences and Bioanalytical Chromatographic Techniques Conferences, November 02, 2017 Atlanta, USA;5th International Current Trends in Mass Spectrometry Conferences and Chromatography Conferences September 25, 2017 Atlanta, USA; 3rd World Chemistry Conferences September 11, 2017 Dallas, USA; 24th International Oxide Electronics Conferences, 24 September 2017, Chicago, IL, United States;Eastern Analytical Conferences13 November 2017, Princeton, NJ, United States; 18th World Analytical Conferences and Bioanalytical Chromatographic Techniques Conferences November 02, 2017 Atlanta, Georgia, USA; 7th International Analytical Conferences and Bioanalytical Techniques Conferences September 28, 2016 Orlando, USA
Pan Africa Chemistry Network Conferences2017: Sustainable Agriculture; How the Chemical Sciences Can Contribute to Food Security for a Growing Population 7 November 2017, Accra, Ghana;GC-MS Conferences: A Hands on Approach on 2 October 2017, Addis Ababa , Ethiopia; The 3rd TCS International Conferences and the 6th FASC Congress , September 11, 2017, Arusha, Tanzania; 40thChemical Society Annual International Conferences-Kadacity 2017, Sep17 2017, Kaduna, Nigeria; 34th World Internal Medicine Conferences
(WCIM 2018) October 18, 2018, Cape Town, South Africa
Separation Techniques Companies in Europe:
Separation Techniques Companies in USA:
himadzu Scientific Instruments | Agilent Technologies | BaySpec
| Celerity | Pickering Laboratories | Labsphere | Analytica of Branford | IMR Technologies | International Equipment Trading Ltd | Industrial Test Systems | Eckert & Ziegler CNL Scientific Resources
| Thar Instruments | High-Purity Standards | J2 Scientific | Columbus Instruments | PerkinElmer Life and Analytical Sciences | Tiger Optics LLC
| Spex CertiPrep | Aspex Corporation | Extech Instruments Corp
| OI Analytical | ESA Laboratories
| Nova Analytics Corporation| Caliper Life Sciences | Advanced Instruments | Troemner Inc. | Optimize Technologies | Advanced Microscopy Group | MAC-MOD Analytical | AB Sciex | BMG Labtech | B&W Tek | Buchiglas USA Corp | Light Technology Industries
| Biomics Inc | Pickering Laboratories | Labsphere Inc | Analytica of Branford | IMR Technologies | Industrial Test Systems | Milestone Inc | DAK Americas LLC | Basic Chemical Solutions | Jacobs Engineering Group Inc | Kinetic Systems
| BioCision | Anasys Instruments Corporation
Separation Techniques Jobs:
Lab Technician-Sumaco Manpower | Laboratory Technical Manager-NYU Abu Dhabi University | Researcher-Abu Dhabi | Life Sciences manager-Australian Laboratory Services | Standard Preparation Technician-DAL Mining |Territory Manager-Peak Scientific | Brand Manager-Inspire Selection
| Analytical Chemist I-Novartis | Senior Chemist-Zagro | Chemist I (Analytical)-Shire | QC Chemist-Pfizer | Associate Chemist (Junior)-Nestlé | Laboratory Analyst-West Pharma | Senior Analytical Scientist-VOLT
| Analytical Scientist-RegionUP | Analytical chemist-Vitasta Consulting | Analytical Chemist (q.c & r. d)-Titan Biotech Limited
| Senior Analytical Chemist-BP Healthcare | Brand Manager-Analytical Equipment-Inspire Selection
List of Separation Techniques Products:
Gas Chromatography | Liquid Chromatograph | Thin Layer Chromatograph | Instruments for Liquid Chromatography-Mass Spectrometer | Gel Permeation Chromatograph Scattering Method Capillary Electrophoresis | Transmission Electron Microscope | Scanning Electron Microscope | Atomic Force Microscope | Optical Microscope| Field Emission Scanning Microscope | Nuclear Magnetic Resonance Analyzer | Visible/Ultraviolet Spectrochemical Analyzer
| Raman Spectrometer | X-ray Diffraction Analyzer | Electron Spin Resonance Analyzer | Fourier Transform Infrared Microspectrometer| Scanning Infrared Microprobe Analyzer | Thermogravimetric Analyzer
| Differential Scanning Calorimeter | Reaction Heat Measuring Instrument
| Thermal Expansion Coefficient Measuring Instrument | Organic Elemental Analyzer | Flame and Flameless Atomic Absorption Spectrometer | Emission Spectrophotometer | Inductively Coupled Plasma Emission Spectrometer | X-ray Fluorescence Analyzer | X-ray Photoelectron Spectrometer | Auger Electron Spectrometer | Electron Probe X-ray Microanalyzer | Field Emission Scanning Electron Microscope | Low Level Alpha particle measuring instrument | Water treatment Equipment | Membrane Filters