Green Chemistry
Green science, additionally called feasible science, is a zone of science and artificial building concentrated on the planning of items and procedures that minimize the utilization and time of perilous substances Green science covers with all sub controls of science however with a specific concentrate on potion union, handle science, and compound designing, in mechanical applications. The degree covers green science recognized with engineered science, prepare and logical science, partition science, feasible assets, and option ecologically more secure synthetic techniques.

• Ultrasound assisted Green Technology
• Future of Green Chemistry
• Green manufacturing processes
• Aromatic and non-aromatic Green Chemistry
• Green chemical solvents
• Green Chemistry-Catalyst compatibility
• Research systems on Green Chemistry
• Trends in Green Chemistry
• Green chemistry Engineering metrics
• Benefits of Green Chemistry
• Green synthesis and Green catalysis

Catalysts and Catalytic processes
A substance that promptness a chemical reaction but it is not disbursed or reformed in the process. Catalysts are of massive importance in chemistry and biology. All enzymes are catalysts that impede the biochemical reactions necessary for life. The control of chemical and biochemical processes is often consequent from the use of catalysts, type that act to selectively increase the rate of chemical reactions. The action of catalysts may also assist to intensely decrease the energy needed to perform assured chemical reactions, as well as to selectively breakdown environmental contaminants - thus playing an important role in developing sustainable approaches to social, economic, and industrial development. Catalytic systems, developing better methods to existing catalytic processes, and even reconnoitring completely new chemical transformations enabled by catalysis.

• Highly efficient Palladium catalyst
• Hybrid and composite catalysts
• Solid chiral catalysts
• Thin film and membrane catalysts
• Magnetically separable catalysts
• Light Computational catalysis and Enantioselective catalysis
• Homogeneous catalysis, Molecular catalysis
• Integrated catalysis
• Harvesting catalysts

Biopolymers and Biomaterials
A biomaterial is any substance that has been engineered to interact with biological systems for a medical purpose - either a therapeutic (treat, augment, repair or replace a tissue function of the body) or a diagnostic one. They may be of natural origin or synthesized in a laboratory. Advanced polymeric Biomaterials proceed to serve as a cornerstone of new scientific applied sciences and therapies. The good sized majority of these materials, each natural and synthetic, interact with biological depend besides direct digital communication. However, biological systems have evolved to synthesize and employ naturally-derived materials for the technology and modulation of electrical potentials, voltage gradients, and ion flows. Bioelectric phenomena can be interpreted as strong signalling cues for intra- and inter-cellular communication. These cues can serve as a gateway to link artificial units with biological systems. Specific focal point will be granted to the use of natural and synthetic biological substances as necessary aspects in applied sciences such as thin film electronics, in vitro cell culture models, and implantable medical devices. Future views and emerging challenges will also be highlighted.

Catalysis in Nanotechnology
Nanocatalysis is a process in which the catalysis process use yields of nanotechnology as a catalyst which are mentioned as Nanocatalyst. A catalyst Composed of nanoparticles. Smaller than 100 nm in at least one dimension permeable compounds having pore diameters not bigger than 100 nm.

• Green nanotechnology
• Nano-Flake Technology
• Carbon nanotechnology
• Nano Materials
• Nanoscale membrane
• Energy applications of nano technology
• Nanotubes, nanofibers and nanoparticles
• Pratical Fuel cells
• Environmental friendly batteries

Catalysis for renewable resources
Catalysis, also called sustainable chemistry, is an area of chemistry and chemical engineering focused on the designing of products and processes that minimize the use and generation of precarious substances. whereas environmental chemistry attentions on the effects of polluting chemicals on nature, green chemistry focuses on technological approaches to preventing pollution and reducing ingestion of non-renewable resources.

• Efficient use of non-renewable resources
• Waste valorization management
• Sustainable Flow Chemistry
• Waste reduction, waste capture and recycling
• Catalysis for water treatment and remediation

Catalystic Materials
A substance that promptness a chemical reaction but it is not disbursed or reformed in the process. Catalysts are of massive importance in chemistry and biology

• Chemical polymer Technology
• Green materials and Engineering
• Green chemicals and fine chemicals

Green Catalysis
A catalyst is a component that participates in a chemical reaction, yet ruins unchanged after the reaction is complete. The waste produced in the manufacture of organic compounds consists mainly of inorganic salts. This is a direct significance of the use of Stoichiometric inorganic reagents in Organic synthesis. In particular, fine chemicals and pharmaceuticals manufacture is rambling with antiquated ‘stoichiometric’ technologies

• Solid catalysts
• Organo catalysis
• Homogeneoous catalysis
• Hetrogeneous catalysis

Green catalysis in Petrochemical Industries
Green chemistry and green catalysis ethics plays a key role in developing a number of chemicals but in another way from petroleum and other non-renewable source of energy. With growing advancement in the field of biotechnology, heredities, chemistry and engineering leading to a new thought for converting renewable biomass into valuable products and fuels through inventions by producing bio-based chemicals, which is an outcome of a coupling reaction of chemical and biological products.

Biocatalysis and Biotransformation
Biocatalysis is the main green chemistry technology which accepts its application by producing fine chemicals and pharmaceuticals with higher yield. Biocatalysis is the chemical process which uses biological or natural enzymes such as proteins or organic mechanisms. These enzymes are either isolated or live inside the living cells. Biocatalysts are fast, consume less time and yield a high precise product.

• Catalytic transformations
• Biocatalysts
• Microbiology
• Regioselectivity and diastereoselectivity
• Bio-gas
• Chemo selectivity
• Enantioselectivity

Green catalysis and Pollution control
Green chemistry and green catalysis principles plays a important role in developing a number of chemicals but in an different way from petroleum and other non-renewable source of energy. With growing advancement in the field of biotechnology, genetics, chemistry and engineering leading to a new idea for converting renewable biomass into valued products and fuels through innovations by producing bio-based chemicals, which is an result of a linking reaction of chemical and biological products.

Emerging Trends in Computational Catalysis
This session of Computational Catalysis is disturbed with method of theoretical chemistry, computer programs, to calculate structure and possessions of molecules and solids. Due to its high degree of precision, now-a-days it is widely used in different fields like designing of new drugs and materials, complementing the evidence obtained by chemical experiments, and predicting the previously unobserved chemical phenomena. Some highly research-oriented topics of this domain to be stressed in the session

• Photocatalysis
• Structured catalyst
• Organo-metallic catalyst
• Environmental catalysis
• Electrocatalysis
• Small molecules catalysis
• Asymmetric catalysis
• Homogeneous catalysis
• Nanocatalysis
• Organocatalysis
• Theoretical modeling of catalytic reactions

Green Chemistry & Commerce Council (GC3)
The Green Chemistry & Commerce Council (GC3) is a business-to-business opportunity that works collaboratively to accelerate the application of green chemistry across industry sectors and supply chains. GC3 members are the innovators in the fields of green chemistry, design for the environment, and the production of harmless chemicals, materials and products.

Catalysis for energy
A catalyst is a material that swiftness a chemical reaction, but is not obsessive by the reaction hence a catalyst can be convalesced chemically unchanged at the end of the reaction it has been recycled to speed up, or catalyze. Catalysts lower the energy barrier.

• Renewable and sustainable energy
• Green energy and efficiency

Green chemistry catalysis and fuel cell
Fuel cell is one of the tools for changing the sustainable energy sources like solar radiation, wind and biomass into usable form of energy. Fuel cells are the devices which change chemical energy into one form or other because of the efficiency and ability to yield energy from diverse source. The fuel cells are the one of the keys to bearable power generation and are used in space shuttles to generate water and electricity required for the mission. Green catalysis and fuel cell technology offers the opportunity to eliminate spreads by providing electricity in an effective manner and make use of waste by-products which is manufactured in a treatment processes

Bio Plastics
The term “Bioplastic” represents a plastic substance that is based (wholly or in part) on organic biomass rather than petroleum, these are plastics derived from renewable biomass sources, such as vegetable fats and oils, corn starch, or microbiota. Bioplastics are a diverse family of materials with differing properties. Today, there is a bioplastic alternative for almost every conventional plastic material and used in a variety of consumer products, such as food containers, grocery bags, biodegradable utensils, and food packaging. Bioplastics can also be used for engineering grade applications, such as electrical and electronic housings and enclosures.

Organometallic catalysis and Organocatalysis
A swift progress in the research of organometallic and coordination compound has the elicit to the advancement and real industrial application of a number of catalytic processes based on the use of these compounds as catalysts. The major advantage of organometallic catalysis that has led to its widespread embracing by industry is selectivity, the ability to produce pure products in high yield. The scarcity of metal in organocatalyst brings an indisputable advantage considering both the principles of “green chemistry” and the economic point of view. It is a original synthetic philosophy and mostly an alternative to the dominant transition metal catalysis. Organocatalysts are often based on innocuous organic compounds originating from biological materials. Organ catalysts can Lewis bases, Lewis acids, Bronzed bases, and bronzed acids.

Advancement of Green Chemistry for Industrial Uses
Green Chemistry in Industrial Applications has more progress in vast fields which outcomes in great Economic Growth and Production of value products. The wide range of applications of green chemistry contains use in the pharmaceutical industry, as well as new approaches that condense or eliminate the use of solvents, or render them safer and more effective.

• Principles of Green chemistry
• Green fertilizers
• Sustainability
• Industrial application of Green Chemistry
• Applications of green chemistry in organic synthesis

Catalysis for Chemical Synthesis
This field of study amalgamate facade of organic, organometallic, and inorganic chemistry. Synthesis forms a significant component of most programs in this area. Mechanistic examination are often undertaken to discover how an unexpected product is formed or to rearrange the concert of a catalytic system. Because synthesis and catalysis are vital, to the construction of new materials, Catalysts are gradually used by chemists busy in fine chemical synthesis within both industry and academia. Today, there triumph huge choices of high-tech catalysts, which add enormously to the list of synthetic possibilities. However, catalysts are intermittently fickle, sometimes exhausting to use and almost always require both skill and experience in order to achieve optimal results

Heterogeneous catalysis
Heterogeneous catalysis is a type of catalysis in which the catalyst occupies a different stage from the reactants and products. This may refer to the physical phase — solid, liquid or gas — but also to immiscible solutions. This involves the use of a catalyst in a different stage from the reactants. Typical examples contain a solid catalyst with the reactants as either liquids or gases. Note: It is important that you remember the change between the two terms heterogeneous and homogeneous.

Green chemistry and catalysis
Green chemistry otherwise called as sustainable chemistry, which is part of chemistry and chemical engineering focused in designing products and by minimizing the generation and use of hazardous substances .whereas, environmental chemistry focuses on effects chemicals polluting the nature, green chemistry focuses on technological ways to prevent pollution and by reducing the feasting of non-renewable resources.

Application of Green Chemistry
Green chemistry is the new and quick evolving branch of chemistry. This new approach introduces in green chemistry synthesis, dealing out and significance of chemical material in such a way as to minimize the risk to environment and health of human. This advanced contact is as well called: Eco-friendly chemistry, clean chemistry, Atom wealth, benign design chemistry. All chemical wastes should be willing of in the best possible manner without causing any damage to the environment and living beings. There are certain examples of green chemistry is given Sustainable Dry clean-up of Clothes, Solution to Turn Turbid Water Clear, Solar Array , Reusable Water Bottle , Solar Water Heater , Wind Generator, Rainwater Reaping System , Insulation of House , Building with Green Technology.

• Energy efficiency
• Use of waste materials
• Atom economy

Sustainability and environmental safety
Sustainability is a topic that continues to gain the consideration of safety, health, and environmental (SHE) professionals. Typically a board-level issue, sustainable growth struggles to balance social, economic, and ecological issues. Working safely is a critical module of Huber Engineered Materials (HEM). Our Environmental, Health, Safety & Sustainability (EHS&S) goal is to safely produce quality products in acquiescence with the laws and regulations throughout the world where we work while minimizing environmental impact.

• Current research in environmental science
• Environmental degradation
• renewable energy
• Bio energy
• Energy conservation
• Plasma Chemistry
• Air pollution & Waste water treatment
• Green technology