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Scientific Program
5th World Congress and Expo on Green Energy, will be organized around the theme “Share & acquire knowledge on utilization of natural resources ”
Green Energy Congress 2018 is comprised of 16 tracks and 88 sessions designed to offer comprehensive sessions that address current issues in Green Energy Congress 2018.
Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.
Register now for the conference by choosing an appropriate package suitable to you.
Renewable energy is energy that is collected from renewable resources, which are naturally replenished on a human timescale, such as sunlight, wind, rain, tides, waves, and geothermal heat. Renewable energy often provides energy in four important areas: electricity generation, air and water heating/cooling, transportation, and rural (off-grid) energy services. Based on REN21's 2016 report, renewables contributed 19.2% to humans' global energy consumption and 23.7% to their generation of electricity in 2014 and 2015, respectively. This energy consumption is divided as 8.9% coming from traditional biomass, 4.2% as heat energy, 3.9% hydroelectricity and 2.2% is electricity from wind, solar, geothermal, and biomass. Worldwide investments in renewable technologies amounted to more than US$286 billion in 2015, with countries like China and the United States heavily investing in wind, hydro, solar and biofuels. Globally, there are an estimated 7.7 million jobs associated with the renewable energy industries, with solar photovoltaics being the largest renewable employer As of 2015 worldwide, more than half of all new electricity capacity installed was renewable.
Green Energy- 2018 facilitates a unique platform for transforming potential ideas into great business. The present meeting/ conference creates a global platform to connect global Entrepreneurs, Proposers and the Investors in the field of Renewable Energy and its allied sciences. This investment meet facilitates the most optimized and viable business for engaging people in to constructive discussions, evaluation and execution of promising business.
Green Energy principally involves natural energetic processes which are able to be controlled with little or no pollution. Anaerobic digestion, geothermal power, wind power, small-scale hydropower, alternative energy, biomass power, recurrent event power, wave power, and many sorts of nuclear power belongs to the green energy. Some definitions might embody power derived from the combustion of waste. In several countries with enterprise arrangements, electricity selling arrangements build it attainable for patrons to shop for green electricity from either their utility or a green power provider. Once energy is purchased from the electricity network, the power reaching the customer will not primarily be generated from green energy sources. The native utility company, utility, or state power pool buys their electricity from electricity producers World Health Organization might even be generating from fuel, nuclear or renewable energy sources. In many countries green energy presently provides a very little bit of electricity, typically conducive two to five to the pool. green energy customers either obligates the utility firms to increase the number of inexperienced energy that they purchase from the or directly fund the green energy through a green power provider.
- Track 3-1Green energy and social benefits
- Track 3-2Green Industrial Technology
- Track 3-3Green Energy in Transport
- Track 3-4Green Buildings and Infrastructures
- Track 3-5Green Policies and Programmes
- Track 3-6Greenhouse gas abatement costs and potentials
- Track 3-7Green Power
- Track 3-8Greening Urbanization and Urban Settlements
Renewable Energy comes from non-conventional energy that is continuously replenished by natural processes. It’s attracted plenty of attention within the recent past due to exhaustion of fossil fuels and within the lookout for alternate energy for a clean and green future. Totally different varied kinds of renewable energy embody solar power, wind energy, hydro energy, heat energy, wave and tidal energy. Supported the report of REN21's 2014, renewable contributed 19 % to our energy consumption and 22 % to our electricity generation in 2012 and 2013. Renewable power is cost effective, reliable, property, and environmentally friendly. Recently the renewable energy sector is already providing quite 450,000 jobs associated has an annual turnover exceeding 45 billion Euros. Since 2009, 25 solar projects totalling quite 8,000 megawatts, and 9 wind comes totalling quite 4,000 megawatts, are approved on public lands within the U.S. That’s enough electricity to power nearly four million yankee homes. The worldwide renewable energy market (excluding biofuels) reached $432.7 billion in 2013 and $476.3 billion in 2014. This market is predicted to extend to $777.6 billion in 2019, with a compound annual rate of growth (CAGR) of 10.3% from 2014 to 2019.
- Track 4-1Biomass Conversion
- Track 4-2Photovoltaic Technology Conversion
- Track 4-3Solar Thermal Applications
- Track 4-4Wind Energy Technology
- Track 4-5Desalination
- Track 4-6Solar and Low Energy Architecture
- Track 4-7Climatology and Meteorology
- Track 4-8Geothermal Technology
- Track 4-9Wave, Tide and Ocean Thermal Energies
- Track 4-10Hydro Power
- Track 4-11Hydrogen Production Technology and Fuel Cells
- Track 4-12Socio-economic and Policy Issues
Green nanotechnology typically refers to the use of applied science to strengthen the environmental property of processes producing negative externalities. It to boot refers to the employment of the product of applied science to strengthen property. It includes making inexperienced Nano-products and exploitation Nano-products in support of property. Green applied science has been depicted as a result of the event of recent technologies, to attenuate potential environmental and human health risks associated with the manufacture and use of nanotechnology product, and to encourage replacement of existing product with new Nano-products that square measure further surroundings friendly throughout their lifecycle producing nanomaterial’s and products whereas not harming the surroundings or human health, and producing Nano-products that supply solutions to environmental problems. It uses existing principles of green chemistry and green engineering to make nanomaterials and Nano-products whereas not toxic ingredients, at low temperatures pattern less energy and renewable inputs wherever potential and pattern lifecycle thinking all told style and engineering stages.
- Track 5-1Treatment and remediation
- Track 5-2Pollution sensing and detection
- Track 5-3Nanotechnology for sustainable energy production
- Track 5-4Bio-inspired nano-materials and their applications
- Track 5-5Nano sorbents
Green process and Synthesis could be a bimonthly, peer-reviewed journal that gives up-to-date analysis each on basic as well as applied aspects of innovative green method development and chemical synthesis, giving an appropriate share to industrial views. The contributions are innovative, high-impact, authoritative, and supply each professionals and cons of potential technologies. Green process and Synthesis provides a platform for scientists and engineers, particularly chemists and chemical engineers, however is also open for knowledge base analysis from alternative areas like physics, materials science, or chemical process. The Novel water-borne coatings via hybrid mini emulsion polymerisation area unit extremely getting used and for pollution bar within the storage device business the data of this subject is incredibly necessary. For Eliminating solvents and acids in wafer process yet as Qualitative and measurement for environmentally benign electroplating operations ought to be done well. The solar power is in action these days and incorporates a nice impact on the energy resources.
- Track 6-1Solar energy in thermo-chemical processing
- Track 6-2Solar Energy as a green energy
- Track 6-3Green Applications of Carbondioxide
- Track 6-4Solar Powered Toilet
Environmental engineering is the branch of engineering that is concerned with protecting people from the effects of adverse environmental effects, such as pollution, as well as improving environmental quality. Environmental engineers work to improve recycling, waste disposal, public health, and water and air pollution control. Environmental engineering can also be described as a branch of applied science and technology that addresses the issues of energy preservation, protection of assets and control of waste from human and animal activities. Furthermore, it is concerned with finding plausible solutions in the field of public health, such as waterborne diseases, implementing laws which promote adequate sanitation in urban, rural and recreational areas. It involves waste water management, air pollution control, recycling, waste disposal, radiation protection, industrial hygiene, animal agriculture, environmental sustainability, public health and environmental engineering law. It also includes studies on the environmental impact of proposed construction projects.
- Track 7-1Pollution and monitoring
- Track 7-2Air pollution
- Track 7-3Solid waste management
- Track 7-4Sustainable tourism
- Track 7-5Urban and Rural Ecology
- Track 7-6Waste Management (industrial, domestic, natural)
- Track 7-7Biodiversity Conservation & Protected Areas Management
- Track 7-8Cleaner Technologies, Control, Treatment & Remediation Techniques
- Track 7-9Modeling, simulation, and optimization
Renewable energy and energy efficiency are typically aforementioned to be the "twin pillars" of property energy policy. Each resource ought to be developed so as to stabilize and cut back oxide emissions. There are various energy policies on a worldwide scale in relation to energy exploration, production and consumption, ranging from commodities companies to automobile manufacturers to wind and star producers and business associations. Recent focus of energy economic science includes the next issues: temperature change and climate policy, property, energy markets and process, political economy of energy infrastructure, energy and environmental law and policies and warming alongside exploring varied challenges associated with quick the diffusion of renewable energy technologies in developing countries. Most of the agricultural facilities at intervals the developed world are mechanized as a result of rural electrification. Rural electrification has created necessary productivity gains; however it additionally uses lots of energy. For this and various reasons (such as transport costs) throughout a low-carbon society, rural areas would want obtainable provides of renewably created electricity.
- Track 8-1Geothermal Energy
- Track 8-2Solar Power & Artificial Synthesis
- Track 8-3Space Based Solar Power (SPSV)
- Track 8-4Biomass & Biogas
- Track 8-5Distribution Generation Policy
- Track 8-6Sustainable coal use and clean coal technologies
- Track 8-7Potential Benefits of Energy Efficiency
- Track 8-8Thorium Fuel Cycle
Biofuels are created from living organisms or from metabolic by-products (organic or waste products) instead of a fuel created by natural science processes like those involved among the formation of fossil fuels, like coal and crude. Biodiesel is also a form of diesel fuel ready-made from vegetable oils, animal fats, or recycled building greases. It is safe, perishable, and produces less air pollutants than petroleum-based diesel. Biodiesel are typically utilised in its pure kind (B100) or mingling with crude diesel. Common blends embody B2 (2% biodiesel), B5, and B20.The 93 billion litters of biofuels created worldwide in 2009 displaced the equivalent of academic degree derived sixty eight billion litters of gas, up to regarding 5-hitter of world gas production. Two most common types of biofuels used are plant product and biodiesel are derived from gift plants, alcohol and oil that act as a perfect substitute for fuel.
- Track 9-1Lignocellulosic Biomass
- Track 9-2Thermochemical Routes
- Track 9-3Syngas from Biomass
- Track 9-4Second generation biofuels
- Track 9-5Microbial pathways for advanced biofuels production
- Track 9-6Synthesis of advanced biofuels
- Track 9-7Advanced biofuels from pyrolysis oil
- Track 9-8Commercialization of next generation Bio-fuels
- Track 9-9Next generation feed stock for Bio-fuel
- Track 9-10Advanced Bio-fuels from photo bioreactors
- Track 9-11Hydrogen Fuel cells
- Track 9-12Wastewater based algae Bio-fuels production
Bioremediation is also a waste management technique that involves the use of organisms to induce eliminate or neutralize pollutants from a contaminated site. Technologies are going to be sometimes classified as in situ or ex situ. in situ bioremediation also involves treating the contaminated material at the location, whereas ex situ involves the removal of the contaminated material to be treated elsewhere. Bioremediation would possibly occur on its own (natural attenuation or intrinsic bioremediation) or may exclusively effectively occur through the addition of fertilizers, oxygen, etc., that facilitate encourage the growth of the pollution-eating microbes at intervals the medium. However, not all contaminants unit of measurement merely treated by bioremediation using microorganisms. Phytoremediation is useful in these circumstances as results of natural plants or transgenic plants unit of measurement able to bio-accumulate these toxins in their above-ground parts, that unit of measurement then harvested for removal.
- Track 10-1Phytoremediation
- Track 10-2Bioleaching
- Track 10-3Bio augmentation
- Track 10-4Mycoremediation
- Track 10-5Genetic Engineering Approaches
Energy is deposited in a range of energy sources, which can be non-renewable or renewable. Renewable sources of energy are those that can be refilled in a short period of time, as opposed to non-renewable sources of energy.The use of renewable sources of energy is less polluting, compared to that of non-renewable sources. Specifically, increased dependence on renewable sources of energy is a key element of efforts to avert climate change. Renewable sources of energy today make an irrelevant contribution to total energy use, compared to that of non-renewable sources. A range of barriers hamper the widespread deployment of renewable energy technologies.
- Track 11-1Role of biomass in climate change mitigation
Renewable Energy or Green Energy is derived from non-conventional energy which is continuously replenished by natural processes. Renewable Energy has attracted a lot of attention in the recent past owing to exhaustion of fossil fuels and in the lookout for alternate energy for a clean and green future. Various forms of renewable energy include solar energy, wind energy, hydro energy, geothermal energy, wave and tidal energy. Based on REN21's 2016 report, renewables contributed 19.2% to humans' global energy consumption and 23.7% to their generation of electricity in 2014 and 2015, respectively. This energy consumption is divided as 8.9% coming from traditional biomass, 4.2% as heat energy (modern biomass, geothermal and solar heat), 3.9% hydroelectricity and 2.2% is electricity from wind, solar, geothermal, and biomass. Worldwide investments in renewable technologies amounted to more than US$286 billion in 2015, with countries like China and the United States heavily investing in wind, hydro, solar and biofuels. Globally, there are an estimated 7.7 million jobs associated with the renewable energy industries, with solar photovoltaic being the largest renewable employer. As of 2015 worldwide, more than half of all new electricity capacity installed was renewable.
- Track 12-1Wind Energy
- Track 12-2Solar Energy
- Track 12-3Hydroelectric Energy
- Track 12-4Wave and Tidal Energy
- Track 12-5Geothermal Energy
Environmental chemistry is the scientific study of the chemical and biochemical phenomena that occur in natural places. It should not be confused with green chemistry, which seeks to reduce potential pollution at its source. It can be defined as the study of the sources, reactions, transport, effects, and fates of chemical species in the air, soil, and water environments; and the effect of human activity and biological activity on these. Environmental chemistry is an interdisciplinary science that includes atmospheric, aquatic and soil chemistry, as well as heavily relying on analytical chemistry and being related to environmental and other areas of science.
Pollution is the introduction of contaminants into the natural environment that causes adverse change. Pollution can take the form of chemical substances or energy, such as noise, heat or light. Pollutants, the components of pollution, can be either foreign substances/energies or naturally occurring contaminants. Pollution is often classed as point source or nonpoint source pollution. In 2015, pollution killed 9 million people in the world.
- Track 13-1Methods of Environmental Analysis
- Track 13-2Soil Pollution and Remediation, Solidwaste Disposal
- Track 13-3Environmental modelling
- Track 13-4Waste management and recycling
- Track 13-5Toxicity and Ecotoxicity
- Track 13-6Environmental Control Technology of Air, Water and Soil Pollution
Green chemistry, 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 hazardous substances. Whereas environmental chemistry focuses on the effects of polluting chemicals on nature, green chemistry focuses on technological approaches to preventing pollution and reducing consumption of non-renewable resources. Green chemistry emerged from a variety of existing ideas and research efforts in the period leading up to the 1990s, in the context of increasing attention to problems of chemical pollution and resource depletion. The development of green chemistry in Europe and the United States was linked to a shift in environmental problem-solving strategies: a movement from command and control regulation and mandated reduction of industrial emissions at the "end of the pipe," toward the active prevention of pollution through the innovative design of production technologies themselves. The set of concepts now recognized as green chemistry coalesced in the mid- to late-1990s, along with broader adoption of the term.
- Track 14-1Biometric Multifunctional Reagents
- Track 14-2Combinatorial Green Chemistry
- Track 14-3Supramolecular Chemistry
- Track 14-4Green chemistry in sustainable development
Sustainable architecture is architecture that seeks to minimize the negative environmental impact of buildings by efficiency and moderation in the use of materials, energy, and development space and the ecosystem at large. Sustainable architecture uses a conscious approach to energy and ecological conservation in the design of the built environment. The idea of sustainability, or ecological design, is to ensure that our actions and decisions today do not inhibit the opportunities of future generations. Energy efficiency over the entire life cycle of a building is the most important goal of sustainable architecture. Architects use many different passive and active techniques to reduce the energy needs of buildings and increase their ability to capture or generate their own energy. One of the keys to exploit local environmental resources and influence energy-related factors such as daylight, solar heat gains and ventilation is the use of site analysis.
- Track 15-1Heating, ventilation and cooling system efficiency
- Track 15-2Renewable energy generation
- Track 15-3Sustainable building materials
- Track 15-4Sustainable urbanism and architecture
Waste-to-energy or energy-from-waste is that the strategy of generating energy among the kind of electricity and/or heat from the primary treatment of waste. Waste-to-energy is also a sort of energy recovery. Most Waste-to-Energy processes manufacture electricity and/or heat directly through combustion, or manufacture combustible fuel product, like gas, methanol, alcohol or artificial fuels. There are over one hundred thermal treatment plants victimization relatively novel processes like direct smelting, the Ebara fluidization methodology and conjointly the Thermo- choose -JFE and melting technology method. Waste to energy technology includes fermentation, which could take biomass and build alcohol, victimization waste plastic or organic material. Within the fermentation methodology, the sugar within the waste is changed to greenhouse gas and alcohol, within a similar general methodology that is used to build wine. Esterification can also be done victimization waste to energy technologies, and conjointly the results of this methodology are biodiesel. Therefore the value effectiveness of esterification will accept the feedstock being used and each one the other relevant factors like transportation distance, amount of oil gift within the feedstock, and others
- Track 16-1Agriculture, Forest Waste & waste management
- Track 16-2Waste to energy Technologies
- Track 16-3Transforming the Strategy into Reality
- Track 16-4Thermal Treatment
- Track 16-5Waste, Energy & climate Change Policy