Theme: The Sustainable Future of Earth with Green Engineering

Green Chemistry Congress 2018

Renowned Speakers

Green Chemistry Congress 2018


Dear colleagues and participants,                                                            

On behalf of the organizing committee of International Conferences on Green Chemistry and Green Engineering as keynote speakers, I invite you to our next international conference in Melbourne, Australia, on July 19- 20, 2018.  

This global congress incorporates a scientific program by the global expert to explore the future aspect for next generation.

I invite you to participate and send your abstracts and put them to the consideration of our prestigious international scientific committee. Deadline June 20, 2018SUBMIT HERE

The conference will take place in Melbourne, one of the main Australian cities, an important site for Waste Management and recycling science and industry and just a great place to visit.

With our warmest regards, the Organizing Committee of the Green Chemistry Congress 2018 wishes you the most productive work and the most pleasant stay in Melbourne.

Your Sincerely,

Dr. David A. Winkler 
Research Associate | CSIRO Australia 

Keynote Speaker & Organizing Committee for International Conference on “Green Chemistry and Green Engineering” Conference series LLC Ltd., UK 



The scientific program and workshops will focus on current advances in the research and use of Green Chemistry with the whole concept of this advanced technology is to agenise from past, analyse the present and implement for the future the latest innovative evolving theories and technologies to surpass the hurdles and make modish frontiers. Conference Series Organizes 1000+ Conferences Every Year across USA, Europe & Asia with support from 1000 more scientific societies and Publishes 1000+ Open access Journals which contains over 50000 eminent personalities, reputed scientists as editorial board members. To know more about the conference series visit:

Green Chemistry and Green Engineering Conference will be a multidisciplinary gathering and present major areas such as green synthesis, green catalysis, education and policies. The forum of Scientists, students and researchers from all corners of the globe, come together to discuss future science. Each session of the meeting will be included with expert lectures, poster and discussions, join us to design sustainable development processes, innovations by which and how these strategies drive new policies, advances the business and human health protection. We are glad to invite you on behalf of organizing the committee to join us, where you are the decision maker for future.

Green Chemistry Conference purpose is to fill your head with the knowledge you can use: ideas, new trends, amazing ingenuity. Our focus is on sustainable Development and Green Technologies, which we believe are foundational to the success of individual organizations as well as our cities, states, nations and world. Attendees come to Green Chemistry Conference to learn from experts in their community and leave.

Every year over 300 of experts representing renewable energy companies, technology and service providers, governments, investors and consultants attend our Green Chemistry Conferences


With so much to see and do, you can't miss the excitement and energy of Green Chemistry Conference in Melbourne, Australia.

The global chemical industry is expected to grow from $4 trillion to $5.3 trillion by 2020. According to a 2011 report from Pike Research, Green Chemistry represents a market opportunity that will grow dramatically from $2.8 billion in 2011 to $98.5 billion by 2020. The same report also estimates that Green Chemistry is forecast to save the industry $65.5 billion by 2020. a part of the $62 billion Australian chemical industry.

The Goal of Green Chemistry and Chemical Engineering is to minimize waste, totally eliminating the toxicity of waste, minimize energy use and utilize green energy (solar thermal, solar electric, wind, geothermal etc.) - that is, no fossil fuel.

The objective of this conference is to provide a significant platform to network and meet experts in the field and sampling of the scientific and engineering basis of green chemistry and engineering with a specific process as examples.

Conference Keywords

Green Steam Engine:

Steam engines can run 24 hours a day regardless of location, weather or daylight. There are no construction costs, towers, roof panels or permits required.

There is no noise or environmental impact associated with steam power.  The Green Steam Engine may be powered by the widest range of alternative fuels, including solar and geothermal. No backup power required as it is for wind and solar systems. Simple Green Engine Cleaner, when operated on solar, excess energy may be stored in the compressed air which can be returned to the steam engine later for electrical generation. Compressed air is much cheaper than batteries.

Green Process Engineering:

The Green Process Engineering integrates the fundamental principles of chemical engineering to the design of commercial products and processes that are safe, economical and environmentally friendly. Green Heron Engineering and Green Process Engineering emphasize the use of alternative sources of energy and renewable feedstocks with reduced carbon emissions and design of alternative pathways to processes or products with reduced environmental footprints and process intensification.

Green Diesel Engineering:

The mechanics behind the Green Diesel refers to a vegetable oil- or animal fat-based diesel fuel consisting of long-chain alkyl (methyl, ethyl, or propyl) esters. Green Diesels are environmentally friendly and are typically made by chemically reacting lipids (e.g., vegetable oil, soybean oil, animal fat (tallow) with an alcohol producing fatty acid esters. Green Diesel Engineering is meant to be used in standard diesel engines and is thus distinct from the vegetable and waste oils used to fuel converted diesel engines. Biodiesel can be used alone or blended with Petroleum diesel (green engine oil) in any proportions. Green Diesel blends can also be used as heating oil.

Climate Change:

The sessions of Green Chemistry Congress 2018 are mainly focused on Climate change that highlights the change in the statistical distribution of weather patterns when that change lasts for an extended from decades to millions of years. Climate change may refer to a change in average weather conditions, or in the time variation of weather within the context of longer-term average conditions. Paris Climate Agreement’s aim is to strengthen the global response to the threat of climate change caused by factors such as biotic processes, variations in solar radiation received by Earth, plate tectonics, and volcanic eruptions. Certain human activities have been identified as primary causes of ongoing climate change, often referred to as global warming and Greenhouse Effect.

Green Building:

The Green Building Project aims to build apartments, houses, hospitals etc. by Green materials or green building materials. Green Valley Engineering usually works on the improvement of Green buildings associated by green tech engineers.

Industrial Green Chemistry:

This particular track drags the proceedings of Green Chemistry principles in an industry point of view. Pharmaceutical companies can make robust green drugs which will almost pacify the situation of reductions causing hazards to public health and therefore should be prominent in selecting less hazardous reagents, reducing reaction steps, and developing better catalysts. Biochemical and biopolymers are biological derivatives that create less deduction in the ecology. Biotechnology produces chemicals and products through biological transformations of bio-based and renewable materials to promote advancement in the economy. Textile Science and Clothing Technology can also be intensified in terms of 12 assessed principles of green chemistry.

Green Engineering policies:

Green Engineering implements the design, commercialization and use of processes and products that are viable and economical evacuating the risk to human health and the environment and generation of pollution at the root following the distinctive principles are given by Sandestin. It encompasses various other disciplines like green biotechnology.

Sustainable Material Management:

The materials force people to look carefully at all aspects of the material life cycle that comprise industrial practices and consumer habits. The material lifecycle is the onset of scrapping or harvesting of raw materials which are transported and processed to create the products and services that drive our society and finally destined to validate resources and environmental sustainability.

Green Energy Prospects:

Green Energy reflects the unbound use of renewable energy sources that deliver negligible impact on the greenhouse gas emissions. The power generated from these sources is free from unwanted weeds of disturbance to ecology. Green power technology involves the joining technology of both biology and chemistry to build up a track in the generation of power with cost-effective and minimize the emissions of CO2.

Waste Management Strategies:

The wastages cause a tragic base to the environment that keeps on accumulating in abundance and therefore to retreat and manage these issues, administration policy should pioneer some steps ahead to recede the squandering of wastages for ecological benefits. Waste management, on the other hand, is deluged with boundary conditions such as costs, logistics, legislation & guidelines, storage, safety targets and the existing technologies on sites, so need to identify the prominent solutions for waste prevention by various aspects of process design before delivering for a production after management. Biological waste treatment directs to the management of waste through biological solutions that prelude a genuine green environment.

Green Biofuels and Energy:

Bio-mass delivers a renewable source of energy that trails the joints of many bio-derived resources and utilization is done based on the purpose, availability and demands. This can create a fruitful basement in agriculture. Bio-fuels can also be generated through biomass conversion that can take leadership in the development of sustainable energy by refining biodiesel and other relevant fuels for use in automotive. Oilfields and essential oils can also be merged with the concept of green chemistry and engineering by relying on their characteristic properties and then processing to sustainable applications. Green gas can mitigate the critical situations of pollution and development in the field of geo-sciences through accompanying the energy sources with more versatile biodegradable but less environmentally harmful materials.

Sustainable resources exploitation:

The exploitation of natural resources in abundance leads to a terrific growth in economy and another ecological feedstock. The modest way of profiling a green field weighs on the 3 R’s policies of management viz. Reduce, Reuse & Recycle and then processing with the benchmark steps to retain sustainability and achieving the goodness of environmental and ethical assessments through the follow ups of green connotations. Waste Hierarchy, Life-cycle of a Product, Clean combustion, Resource efficiency Recycling or reusing doesn’t prefer the destruction of indigenous constitutes.

Greening Industrial Applications:

The industrial applications can be transformed to green by petrifying the processes with respect to the principles of Green Chemistry and Engineering. These processes can be deciphered green only if the level of formation is limited to clean aspects and management of the toxic chemicals before these link with further tragic residuals.

Green Chemistry Metrics:

Green chemistry metrics deals with measuring aspects of a chemical process linking to the principles of green chemistry which is served for the quantification of the efficiency or environmental performance of the processes encountered and then allowing the changes in performance to be measured if it complies with the prospects of green evolution. Atom-economy balance refers measuring of the atoms that were wasted when making a chemical. The most potent catalysts in terms of lignin conversion to methanol-soluble products, without char formation, were based on copper in combination with other dopants based on relatively earth-abundant metals

Conservation: Conservation is an ethic of resource use, allocation, and protection focuses is on maintaining the health of the natural world, its habitats, fisheries and biological diversity. the principle by which the total value of a physical quantity or parameter such as mass and energy remains constant in a system which is not subject to external influence. For example; conservation of water, conservation of forest, conservation of biodiversity.

Wastewater: For a safe and Eco-friendly Wastewater Treatment some innovative researches are coming around. The experiments on environmental products cause an unsafe field for the habitats. It has become very important to reuse the wastewater namely Blackwater, Graywater and Yellow water comes from toilets, factories or industries. 


Session 1: Advanced Green Chemistry

In the first session of this conference, the theory will be discussed i.e. Green chemistry is the design of chemical products and processes that reduce or eliminate the use or generation of perilous substances. Green Chemistry’s focus is on the sustainability of the environmentGreen Chemistry is an absolute approach to the way that products are made. Green chemistry applies across the life cycle of a chemical product, including its design, manufacture, use, and ultimate disposal. New and innovative Design for Degradation is taken as an important topic to discuss in the present era. Real-time analysis for Pollution Prevention; Analytical methodologies need to be further developed to allow for real-time in-process monitoring and control prior to the formation of hazardous substances. Inherently Safer Chemistry for Accident Prevention.

The global market for green chemistry, which includes renewable feedstocks, biobased chemicals, green polymers and less-toxic chemical formulations, is projected to grow from $11 billion in 2015 to nearly $100 billion by 2020.

Similarly, the North American market for "green chemistry" is projected to grow from $3.02 billion to over $20 billion during the same period, according to Pike Research. 

Session 2: Green Engineering

Green Engineering advances the design of products and processes by applying technologically and financially practicable processes and products in a manner that simultaneously decreases the amount of pollution that is generated by a source, minimizes exposures to potential hazards (including reducing toxicity and improved uses of matter and energy throughout the life cycle of the product and processes) as well as protecting human health without relinquishing the economic efficiency and viability. Use life-cycle thinking in all engineering activities as such, green engineering is not actually an engineering discipline in itself, but an overarching engineering framework for all design disciplines.

This session represents with original research, Principles of Green Engineering, Innovations in Green Engineering, Efficient use of mass like energy, space & time, Sustainability throughout product life cycle and Industrial application of Green Engineering.

Considered in the broadest possible terms for green tech activities, products and services of all types, Plunkett Research estimates the green tech sector to represent about 5% of global GDP for 2016, or approximately $3.78 trillion.

The energy sector, in all of its many facets, is unquestionably a major part of the green tech field. Bloomberg New Energy Finance (BNEF) counted, as of 2015, more than 600 publicly-held companies worldwide in the clean energy value chain.

Session 3: Green Catalytic Modulations

This session will cover all types of Green Catalysts. You might wonder why phase differs from the term physical state. It includes solids, liquids and gases, but is actually a bit more general. It can also apply to two liquids (oil and water, for example) which don't dissolve in each other. You could see the boundary between the two liquids. The role of catalysis in Catalytic oxidation and Reduction and for the sustainable products of Bio-Fuels and the role of a catalyst is to provide a shorter route for the reaction to occur, hence it increases the rate of the reaction as the catalyst provides a route that requires a low activation energy. Thus, the rate of the reaction is increased. Included with catalysis of solid acids and basesCatalytic Reduction and Catalytic Oxidation, the Green Catalytic transformation can be done. This Session includes Heterogeneous catalysis, Homogeneous catalysis, The Role of catalysis, Chemical Engineering, Catalysis of solid acids and Bases, Sustainable Catalysts, Catalytic Oxidation and Reduction, Risky Reagents, Green Catalytic transformation.

The global green catalyst market is expected to reach USD 34.3 billion by 2024, according to a new report by Grand View Research, Inc. The accelerating use of catalysts for reducing the cost of manufacturing chemicals, petrochemicals and polymers are expected to remain a favourable factor.

Session 4: Green Energy Prospects & Technology

The most important issue of the green technology that includes the Eco-Design in Industry, the renewable energy or technology of generating energy, Use of waste materials, Green Fertilizers waste-to-green Product Conversion and energy efficiency. The search for the alternative fuel has getting queries in the field to Increase the energy efficiency. In so doing, the overall health and ecological stress and risk are reduced. As such, green engineering is not actually an engineering discipline in itself, but an overarching engineering framework for all design disciplines. Minimize the waste and then reuse or recycle as much of it as possible. Minimize energy and water usage in our buildings, vehicles and processes in order to conserve supplies, and minimize the consumption of natural resources, especially where they are non-renewable. This session will include all the topics related to Waste -to-green Product ConversionGreen Energy, Energy savings, Green building, Environmentally preferred purchasing Green chemistry etc. Considered in the broadest possible terms for green tech activities, products and services of all types, Plunkett Research estimates the green tech sector to represent about 5% of global GDP for 2016, or approximately $3.78 trillion. The energy sector, in all of its many facets, is unquestionably a major part of the green tech field. Bloomberg New Energy Finance (BNEF) counted, as of 2015, more than 600 publicly-held companies worldwide in the clean energy value chain.

Session 5: Green Nanotechnology

Green Nanotechnology involves the manipulation of materials at the scale of the nanometer, one billionth of a meter. Some scientists believe that mastery of this subject is forthcoming that will transform the way that everything in the world is manufactured. "Green nanotechnology" is the application of green chemistry and green engineering principles to this field. Green nanotechnology has been described as the development of clean technologies, "to minimize potential environmental and human health risks associated with the manufacture and use of nanotechnology products, and to encourage replacement of existing products with new nano-products that are more environmentally friendly throughout their lifecycle. Research is underway to use nanomaterials for purposes including more efficient solar cellspractical fuel cells, and environmentally friendly batteries. The most advanced nanotechnology projects related to energy are storage, conversion, manufacturing improvements by reducing materials and process rates, energy saving (by better thermal insulation for example), and enhanced renewable energy sources.

The market for chemical compounds as catalysts are expected to foresee volume growth at a CAGR of 4.2% from 2016 to 2024. Rising application of amine catalyst for the production of polyurethane foam on account of enhancing the rate of reaction between polyols and polyurethane is expected to have a positive impact in the near future. Moreover, increasing requirement of polyurethane (PU) foams are projected to augment demand for catalysts over the forecast period.

Session 6: Green Biofuels and Energy

In this session, the trends of biofuels which helps to build a greener environment and technology will be discussed. For that some bioresources like an isolated, solvent-extracted lignin from candlenut (Aleurites moluccana) biomass was subjected to catalytic depolymerization in the presence of supercritical CH3OH (Methanol or wood alcohol), using a range of porous metal oxides derived from hydrotalcite-like precursors. The most potent catalysts in terms of lignin conversion to methanol-soluble products, without char formation, were based on copper in combination with other dopants based on relatively earth-abundant metals. Nearly complete conversion of lignin to bio-oil composed of monomers and low-mass oligomers with high aromatic content was obtained in 6 h at 309 °C using a catalyst based on a Cu- and La-doped hydrotalcite-like precursor. Product mixtures were characterized by NMR spectroscopy, gel permeation chromatography, and GC–MS. The related subtracks of the sessions are Lignin, Catalysis, Porous metal oxides, Bio-oil, Supercritical solvents. 

Session 7: Green Innovative Trends

Building the future with sustainable and innovative technologies can be done by following the innovative trends in Green Chemistry. Over the years different principles have been proposed that can be used when thinking about the design, development and implementation of chemical products and processes. These principles enable scientists and engineers to protect and benefit the economy, people and the planet by finding creative and innovative ways to reduce waste, conserve energy, and discover replacements for hazardous substances. “Green Chemistry is the utilization of a set of principles that reduces or eliminates the use or generation of hazardous substances in the design, manufacture and applications of chemical products”.

The global market for green chemistry, which includes biobased chemicals, renewable feedstocks, green polymers and less-toxic chemical formulations, is projected to grow from $11 billion in 2015 to nearly $100 billion by 2020

Session 8: Recent Development in Environmental Engineering

Environmental Engineering is something that you can get a degree in these days, but the field is one that existed long before it had a name, begun at the dawn of civilization when we started modifying our environment to meet our needs. It involves applying science and engineering practices to how we utilize and impact our natural resources. Modern environmental engineers work on solutions to issues like pollution reduction and cleanup, energy consumption and emissions, land erosion, water treatment and waste management in an effort to properly manage and maintain the quality of our soil, water and air. They strive to keep everyone healthier and happier by helping us live off the land more efficiently and less destructively. Environmentally Benign Catalysis: Over the past 22 years, Catalysis by Heteropolyacids (HPAs) has received wide attention and led to new and promising developments both at academic and industrial level. In particular, heterogeneous catalysis is particularly attractive because it generally satisfies most of green chemistry’s requirements. By emphasizing the development of third generation catalysts, this volume presents trends and opportunities in academic and industrial research. Dealing with Low-pressure oxidative carbonylation of aniline, Clean combustion (catalyst challenges) and Zeolite technologies for a greener environment, this Conference appeals to postgraduates, researchers, and chemists working in the field of environmentally benign catalysts as well as catalytic processes.

Session 9: Emerging Technology on Biobased Chemicals 

The biobased industry is addressing our environmentally and socioeconomically unsustainable dependence on petroleum feedstocks in all market fronts. Researchers and firms are working quickly to create biofuels for all modes of transport, and are now beginning to highlight and even commercialize bio-derived drop-in replacements and alternatives for chemicals on which nearly every industry depends.

Biomass is the organic matter derived from plants which is generated through photosynthesis. In particular, it can be referred to solar energy stored in the chemical bonds of the organic material. In addition to many benefits common to renewable energy, biomass is attractive because it is current renewable source of liquid transportation of biofuel. The Bioenergy Conference and Biofuel Conferences will optimize and enhance existing systems. However, biomass could play in responding to the nation's energy demands assuming, the economic and advances in conversion technologies will make biomass fuels and products more economically viable? The renewable energy policies in the European Union have already led to a significant progress, energy mix should further change till 2020.

Session 10: Green synthesis and Designing

Green synthesis is a special branch of chemical synthesis and is concerned with the construction of organic compounds via organic reactions. Organic molecules often contain a higher level of complexity than purely inorganic compounds, so that the synthesis of organic compounds has developed into one of the most important branches of organic chemistry. There are several main areas of research within the general area of organic synthesis: total synthesis, semi synthesis, and methodology.

A total synthesis is the complete chemical synthesis of complex organic molecules from simple, commercially available (petrochemical) or natural precursors. The total synthesis may be accomplished either via a linear or convergent approach. In a linear synthesis often adequate for simple structures several steps are performed one after another until the molecule is complete. The chemical compounds made in each step are called synthetic intermediates. For more complex molecules, a different approach may be preferable: convergent synthesis involves the individual preparation of several "pieces" (key intermediates), which are then combined to form the desired product.

Session 11: Green materials and Engineering

In this session the chief topics like sustainable materials, industrial ecology, eco-efficiency, and green chemistry will be discussed and elaborated in an innovative manner. These are guiding the development of the next generation of materials, products, and processes. Biodegradable plastics and bio-based polymer products based on annually renewable agricultural and biomass feedstock can form the basis for a portfolio of sustainable, eco-efficient products that can compete, and capture markets currently dominated by products based exclusively on petroleum feedstock. Natural/Biofiber composites (Bio-Composites) are emerging as a viable alternative to glass fibre reinforced composites especially in automotive and building product applications. Green, ecological and eco-marketing are a piece of the new advertising methodologies which don't simply refocus, modify or upgrade existing promoting thinking and practice, however, try to challenge those methodologies and give a generously alternate point of view. In more detail, green, natural and eco-marketing have a place with the gathering of methodologies which look to address the absence of fit between promoting as it is as of now drilled and the biological and social substances of the more extensive advertising environment.

Session 12: Environmental Health & Safety Management 

To fulfil our social responsibilities and achieve continuous development, the protection of the environment and health must be the key management principle. The materials force people to look carefully at all aspects of the material life cycle that comprise industrial practices and consumer habits. The material lifecycle is the onset of scrapping or harvesting of raw materials which are transported and processed to create the products and services that drive our society and finally destined to validate resources and environmental sustainability. These are distributed, consumed, reused or recycled, and ultimately disposed of. The main aim of this management is to degrade the environmental impacts caused by the deviant extracts of hazardous materials for sustainable development. So, to control and monitor these steps are to be forwarded for managing to imperil materials.  Green Building Technology is picturesque of design and construction of buildings of high-performance structures that also meet certain standards for reducing natural resource consumption. 

Session 13: Renewable and Sustainable Energy

Photo-catalytic Hydrogen Production in which Nano-sized TiO2 photocatalytic water-splitting technology has great potential for low-cost, environmentally friendly solar-hydrogen production to support the future hydrogen economy. Presently, the solar-to-hydrogen energy conversion efficiency is too low for the technology to be economically sound. The main barriers are the rapid recombination of photo-generated electron/hole pairs as well as backward reaction and the poor activation of TiO2 by visible light. There are Further developments in sensitized H2 production and a vision on the Future directions and challenges in a photocatalytic H2 generation are enumerated.

Photosynthetically active radiation (PAR) is the critical forcing data in ecological and agricultural fields. Remote sensing can be utilized to derive spatiotemporally continuous PAR. Empirical algorithms can be used to quickly retrieve surface PAR data sets, but their accuracy cannot be guaranteed in regions without local calibration. Physical algorithms generally incorporate all relevant physical processes and can be used globally, but their computational efficiency is often low. In this paper, an efficient algorithm is developed to calculate surface PAR by combining a clear-sky PAR model and the parameterizations for cloud transmittances.

Session 14: Green solvents

The use of hazardous and toxic solvent in chemical laboratories and the chemical industry is considering chemical a very important problem for the health and safety of workers and environmental aims to change the use of toxic solvents with greener alternatives to discuss this issues and related topic this session is designing to elaborate the discussion with replacement and synthetic techniques, separation and purification which do not need the use of solvents. One of the principles of Green Chemistry is to promote the idea of “greener” solvents (non-toxic, benign to the environment), replacement in cases that can be substituted with safer alternatives, or changes.

Session 15: Green separations

Green separation science & technology for separation processes are very energy intensive and in most cases, have not approached the thermodynamic limits of minimum work of separation. Historically, for liquid and condensable gas separation, multistage distillation has been the workhorse process, based on boiling point differences between the components to be separated. The energy consumption of oil refineries involved distilling crude oil into its various fractions, replacement of volatile organic compounds in industrial scale liquid/liquid or chromatographic separations and subsequent separation of thermally or catalytically cracked components in these various fractions. Moreover, many bulk organic chemicals involve distillation in their production, which adds significantly to their production CO2 footprints. Thus, avoiding distillation, making distillation more efficient, and searching for alternatives to distillation are very important aspects of implementing the third principle of green engineering. Waste management strategies for the resource smart like waste education and Regional Strategies are being developed.

Session 16: Green Processing and Solar Energy

Green Processing and Synthesis is a bimonthly, peer-reviewed journal that provides up-to-date research both on fundamental as well as applied aspects of innovative green process development and chemical synthesis, giving an appropriate share to industrial views. The contributions are cutting edge, high-impact, authoritative, and provide both pros and cons of potential technologies. Green Processing and Synthesis provides a platform for scientists and engineers, especially chemists and chemical engineers, but is also open for interdisciplinary research from other areas such as physics, materials science, or catalysis. The Novel water-borne coatings via hybrid mini-emulsion polymerization are highly being used and for pollution prevention in the magnetic tape industry, the knowledge of this subject is very necessary. For Eliminating solvents and acids in wafer processing as well as Qualitative and Quantitative analysis for environmentally benign electroplating operations should be done well.

The solar Energy is in action nowadays and has a great impact on the energy resources. For example; Solar Energy in Thermochemical processing, Solar Energy as a green energy, Water and air purification by photodegradation of contaminants.

the use of Solar energy in environmental clean-up, solar Powered Toilet, Disinfection with solar energy etc. The Green Applications of Carbon dioxide as Combined reaction/separation processes in CO, Green process concepts for the pharmaceutical industry (use of CO2 and nanoparticles), Two-stage drawing of PET fibres using CO and Supercritical CO2 carbonation of cement and cement/ fibre composites.

Session 17: Green Analytical Methodologies

As Anastasia alluded to, it is an unfortunate irony that environmental analytical methods often contribute to further environmental through the chemicals used in the analysis. And other techniques like HPLC techniques and Potentiometric techniques make the applications in measurement methods in Flameless atomic absorption spectrometry. This is because many analytical procedures require hazardous chemicals as part of sample preservation, preparation, quality control, calibration and equipment cleaning effectively creating wastes in larger quantities and with Plasma emission spectrometry, Surface analysis techniques and Nanoscale analytical method. Immunoassay and Microanalytical method are the main part of the Green analytical methodologies.

Session 18Entrepreneurs Investment Meet

People related to Green business administration would like to attend this meeting for their investment in the Green energy and chemistry projects in the market. Also get the chance to develop your knowledge in the green chemistry and green engineering products.

Green marketing is the showcasing of items that are dared to be naturally desirable over others. Thus, green marketing joins an expansive scope of exercises, including item adjustment, changes to the generation process, economical bundling, and in addition altering publicizing. Yet characterizing green promoting is not a straightforward assignment where a few implications cross and repudiate one another; a sample of this will be the presence of shifting social, natural and retail definitions appended to this term. Other comparable terms utilized are ecological advertising and environmental showcasing.

For businesses, sustainability is more than an ethical pursuit – it can be a real money maker.

The biggest challenge lies in changing the mindset of business leaders who struggle to accept the notion that by strategically implementing sustainability into their business practices, they can actually improve and grow their businesses financially.

leading expert on quantifying and selling the business value of corporate sustainability strategies discusses how businesses can avoid risk, create efficiency, save money, and grow revenue through strategic implementation of sustainable solutions. Additionally, he explains how civil engineers can be agents for change in making sustainability a reality for their clients in the public and private sectors.

Related Conferences:

Environmental pollution conference and Global warming conference, May 16-17, 2018, Osaka, Japan; Conference on Global warming December 5-6, 2018, Canada; 5th World congress and Expo on Green Energy, June 14-16, 2018, London, UK; Meeting on Green Chemistry, May 7-8, 2018 Japan; World Congress on Environmental Toxicology and Health, July 11-12, 2018, Sydney, Australia; International Conference on Agri Biotech and Environmental Engineering, September 11-12, 2018, USA; 10th World Congress and Expo on Recycling July 26-27, 2018 Amsterdam, Netherlands; Gordon Green Chemistry Conference, August 3, 2018; Conference on Environmental Science, February 7-9, 2018, France; Green Engineering Conference September 20-21, 2018, Germany; 8th International Recycling Conference, and Reduce Conference, and Reuse Conference, July 25-26, 2018, Germany; 22nd Annual Green Chemistry & Engineering Conference, June 18-20, 2018, Portland; Green catalysis and sustainable energy conference, September 6-7, 2018 Dubai, UAE; International Conference on Renewable EnergyICREN 2018, April 25-27, 2018 Barcelona.

Green Chemistry Associations | Chemical Societies

American Chemical Society (ACS), Royal Society of Chemistry, Royal Australian Chemical Institute, Green Chemistry Education Network (GC Ed Net), Greener Education Materials for Chemists (GEMS). Lombardy Green Chemistry Association (LGCA) Italy.

Green Chemistry Congress 2018 takes immense pleasure to invite you all to be a part of this meeting which will focus on current trends and emerging issues in Green Chemistry. This ConferenceSeries Ltd Conference desideratum is to render an intriguing forum and vibrant opportunity for researchers to share their original research results and practical experiences, at the same time absorb knowledge from works being done around the nooks of world. Apart from researchers, professors, biopharmaceutical industry practitioners, private and public investors, and students are also most welcome to get themselves inbuilt to the rays of novel happenings on Green Chemistry around the globe. The whole concept of this advanced technology is to agenized from past, analyse the present and implement for the future the latest innovative evolving theories and technologies to surpass the hurdles and make modish frontiers.

The major objective of the conference is to emphasize the importance of Green Chemistry, explore recent advancements, and research by making room to experts and researchers from around the globe. The gathering will address sustainable developments in areas such as organic chemistry, novel methodologies in physical and applied chemistry. This event will be the best venue for academicians, researchers and interested parties to discuss proposals and most sound issues related to eco-friendly chemical processes.

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Importance & Scope:

Green Chemistry provides a unique forum for the publication of innovative research on the development of alternative sustainable technologies. With a wide general appeal, Green Chemistry publishes urgent communications and high quality research papers as well as review articles. The scope of Green Chemistry is based on, but not limited to, the definition proposed. Green chemistry is the utilization of a set of principles that reduces or eliminates the use or generation of hazardous substances in the design, manufacture and application of chemical products. Green Chemistry is at the frontiers of this science and publishes research that attempts to reduce the environmental impact of the chemical enterprise by developing a technology base that is inherently non-toxic to living things and the environment. Green chemistry is the design of chemical products and processes that reduce or eliminate the use and generation of hazardous substances.

The meeting will be a multidisciplinary gathering and present major areas such as green synthesis, catalysis, education and policies. The forum of Scientists, students and researchers from all corners of the globe, come together to discuss future science. Each session of the meeting will be included with expert lectures, poster and discussions, join us to design sustainable processes, innovations by which and how these strategies drive new policies, advances the business and human health protection. We are glad to invite you on behalf of organizing committee to join us, where you are the decision maker for future.

Why Australia?

Renewable energy in Australia deals with efforts being made in Australia to quantify and expand renewable energy, which includes electricity, transport fuels and thermal energy. Total renewable energy consumption in Australia in 2015 was 346PJ, representing 5.9% of Australia's total energy consumption. This is an increase of 1.6% from 2011–12 levels (265PJ), representing 4.3% of Australia's total energy consumption. Of all renewable energy consumption in 2015 (in order of contribution) biomass (wood, wood waste and bagasse) represents 53%, hydroelectricity 19.2%, wind 10.7%, solar PV 5.1%, biogas 4.7%, solar hot water 3.8% and biofuels 3.6% Bioenergy (the sum of all energy derived from plant matter) represented 61.3% (211.9PJ) of Australia's total renewable energy consumption in 2015.

Renewable electricity has undergone substantial growth in Australia in the 21st century. It is estimated that Australia produced 35,007 Giga watt hours (GWh) of renewable electricity (or equivalent) over the year ending December 2015, representing 14.6% of the total production in Australia. By way of comparison, in 2006, approximately 9,500 GWh of electricity came from renewable sources, representing less than 4% of nationally generated electricity.

Of all renewable electrical sources in 2012, hydroelectricity represented 57.8%, wind 26%, bioenergy 8.1%, solar PV 8%, large-scale solar 0.147%, geothermal 0.002% and marine 0.001%; additionally, solar hot water heating was estimated to replace a further 2,422 GWh of electrical generation.

Why to attend???

Meet Your Target Market with three days of programming, the Green Chemistry and Green Engineering 2018 conference will feature 58 technical sessions, a poster session, green exhibit hall, and keynotes lectures. Green Chemistry Congress 2018 invites scientists, decision-makers, students, and chemists to come together, compare findings, and discuss the science of the future. Share your research with an engaged audience of your peers from around the globe; learn from scientific trailblazers who are designing more sustainable chemistries and processes; find out how green innovations are inspiring new businesses and product lines.

Renewable power plants in Australia:

Percentage of renewable electricity generation by energy source (2011)


Major Marketing Associations around the Globe

  • TCNJ’s Student Chemists Association
  • Lombardy Green Chemistry Association
  • A Sustainable Global Society
  • Chemistry Society of Peru

Major Marketing Associations in Australia

·      Australian Marketing Institute (AMI)

·        Association for Data-driven Marketing and Advertising (ADMA)

Statistical Analysis of Associations and Societies


Target Audience:

The target audience is Nobel laureates, MD/Presidents, Vice Presidents, Departmental Head & Chairs. Vendors will have the opportunity to introduce the latest Green Chemistry technology to a diverse audience by becoming a conference sponsor via exhibits and/or workshops.

Target Audience:

  • Industry           21%
  • Student            17%
  • Academia         42%
  • Government     11%
  • Others               9%

Top Universities in Australia

  •              University of Melbourne
  •            The Australian National University (ANU)
  •              Canberra Institute of Technology (CIT)
  •               Central Queensland University
  •              Griffith University
  •              RMIT University
  •              University of Sydney
  •              Monash University
  •              University of Canberra
  •              University of Queensland
  •              University of Tasmania
  •              University of Wollongong


Glance at Market of Green Chemistry:

The global market for green chemistry, which includes biobased chemicals, renewable feedstocks, green polymers and less-toxic chemical formulations, is projected to grow from $11 billion in 2015 to nearly $100 billion by 2020.

Similarly, the North American market for "green chemistry" is projected to grow from $3 billion to over $20 billion during the same period, according to Pike Research.

Materials Chemistry:

Today, many materials chemists are synthesizing functional device materials, and the discipline is often seen as directed towards producing materials with function—electrical, optical, or magnetic. Material chemistry is involved in the designing and processing of materials. Global market for catalysts is expected to reach $28.5 billion by 2020, growing at a CAGR (2015 to 2020) of over 3%. Asia-Pacific is having the largest market for catalysts accounting for more than 35% share.

*Source: BCC Research & Markets and Markets 

Top Environmental Companies Around the Globe

Mettler - Toledo Int. Inc | OMI Industries (OMI) | SoundPLAN International LLC | Myron L Company | Anguil Environmental Systems, Inc. | Fluence Corporation | OSEI - Oil Spill Eater International, Corp | econ industries services GmbH | BUCHI Labortechnik AG | American Water Works Association (AWWA) | The OTT Hydromet Group | ATN Engineering B.V. | Merck | Primozone Production AB | J & R Business Enterprises Inc. | Environmental Technology Publications Ltd | Chromatotec Group | Babcock & Wilcox MEGTEC LLC | Pieralisi Group | REDWAVE a division of BT-Wolfgang Binder GmbH | XP Solutions | Teledyne API | Aeration Industries International (AII) | Presona AB | ProMinent Group - ProMinent GmbH | Granutech-Saturn Systems | AEREON | Compliance Solutions | Harden Shredder Machinery Ltd. | C&G Depurazione Industriale S.r.l. | Umwelttechnik MCZ GmbH | Vac-Con, Inc. | TenCate Geosynthetics Netherlands bv | Flexus Balasystem AB | Gasmet Technologies Oy | Process Combustion Ltd | Pieralisi Group | REDWAVE a division of BT-Wolfgang Binder GmbH | Bioprocess Control Sweden AB | LNI Swissgas SA



To share your views and research, please click here to register for the Conference.

To Collaborate Scientific Professionals around the World

Conference Date July 19-20, 2018
Sponsors & Exhibitors Click here for Sponsorship Opportunities
Speaker Opportunity Closed Day 1 Day 2
Poster Opportunity Closed Click Here to View