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Bioenergy 2018

About Conference

Conferences series LLC invites all the participants from all over the world to attend  11th  World Bioenergy Congress and Expo during July 2-4, 2018 in Frankfurt, Germany. Which includes prompt keynote presentations, Oral talks, Poster presentations and Exhibitions. Theme of the Bioenergy conference is “Bioenergy: Mobilizing the Bioeconomy and Globe through Innovation for a sustainable world” with an objective to encourage young minds and their research abilities by providing an opportunity to meet the experts in the field of Bioenergy. Bioenergy congress is designed to explore various applications in different fields.

Join us for two intensive and interesting days of discussing contemporary Bioenergy Expo research. We invite you to contribute and help to shape the Bioenergy congress through submissions of your research abstracts, papers and e-posters. Bioenergy International is cordially inviting for presentation at the conference.

Bioenergy technology mainly focuses on usage of Biomass Energy as an alternative source for Energy Production for future generation and aims to bring together leading academic scientists, researchers and research scholars to exchange and share their experiences and research results. Bioenergy 2018 aims to promote various researches on Biomass among scientists, academia and industries. Bioenergy 2018 offers various topics for interaction including Biomass, Bioenergy research, Algal Biofuel Production, Biomass conversion Processes to useful Energy. For the period 2014–2022 based on the historical years – 2012 and 2013. Projections have been provided for installed capacity (MW), power generation (Million KWh), and revenue (USD Million). The report includes the key market dynamics affecting the demand for biomass power generation feedstock and technologies. As a part of our market dynamics analysis, we have analyzed market drivers, market restraints, and market opportunities. A comprehensive competitive landscape, which includes company market share analysis and market attractiveness analysis, has also been provided in this report. Conferences series LLC has been and will be organizing Bioenergy Conferences and events to put front the research advances. The gathering will highlight the opportunities in both Biomass Conferences and Biofuel Conferences.

Target Audience:

Bioproduct companies

Bioenergy Associations

Bioenergy Researchers

Bioenergy Industry

Bioenergy Scientists

Nuclear energy Engineers

Bioenergy technology Engineers

Chemical Engineers

Renewable energy Organizations and Associations

Solar Energy companies


Track 1: Biomass

Biomass is biological material derived from living, or recently living organisms. It most often refers to plants or plant-based materials which are specifically called lignocellulosic biomass. As an energy source, biomass can either be used directly via combustion to produce heat, or indirectly after converting it to various forms of biofuel. Conversion of biomass to biofuel can be achieved by different methods which are broadly classified into: thermal, chemical, and biochemical methods. Wood remains the largest biomass energy source to date; examples include forest residues (such as dead trees, branches and tree stumps), yard clippings, wood chips and even municipal solid waste. In the second sense, biomass includes plant or animal matter that can be converted into fibers or other industrial chemicals, including biofuels. Industrial biomass can be grown from   numerous types of plants including miscanthus, switch grass, hemp, corn, poplar, willow, sorghum, sugarcane, bamboo, and a variety of tree species, ranging from eucalyptus to oil palm (palm oil). Biomass can be converted to other usable forms of energy like methane gas or transportation fuels like ethanol and biodiesel. There is research involving algal, or algae-derived, biomass due to the fact that it is a non-food resource and can be produced at rates five to ten times faster than other types of land-based agriculture, such as corn and soy. Using biomass as a fuel produces air pollution in the form of carbon monoxide, carbon dioxide, NOx (nitrogen oxides), VOCs (volatile organic compounds), particulates and other pollutants at levels above those from traditional fuel sources such as coal or natural gas in some cases (such as with indoor heating and cooking) Utilization of wood biomass as a fuel can also produce fewer particulate and other pollutants than open burning as seen in wildfires or direct heat applications. Black carbon – a pollutant created by combustion of fossil fuels, biofuel, and biomass – is possibly the second largest contributor to global warming.

Track 2: Biomass feed stocks for renewable energy generation

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.

Track 3: Renewable Energy

Renewable energy is energy that is generated from natural processes that are continuously replenished. This includes sunlight, geothermal heat, wind energy, tides, water, and various forms of biomass. This energy cannot be exhausted and is constantly renewed. Biomass, is a renewable organic matter, and can include biological material derived from living, or recently living organisms, such as wood, waste, and alcohol fuels. Renewable Energy is normally defined as any energy resource’s that can be naturally renew or regenerated over a short time and which is directly derived from the sun (solar energy),indirectly from sun such as wind energy, hydropower energy, bioenergy ,or from  other mechanisms of natural  resources (geothermal energy, tidal energy). Renewable energy only includes energy derived from organic and natural resources it doesn’t include inorganic resources. REN21 is an energy policy network that brings government and non-governmental organisation together and other organisations to learn from one another and build successes in advance renewable energy. Renewable energy which is replaced by a natural process as the rate of process is faster than the rate which is consumed.

Track 4: Biogas

Biogas typically refers to a mixture of different gases produced by the breakdown of organic matter in the absence of oxygen. Biogas can be produced from raw material testing such as agricultural waste, manure, municipal waste, plant material, sewage, green waste or food waste. It is a renewable energy source and in many cases exerts a very small carbon footprint. Biogas can be produced by anaerobic digestion with anaerobic bacteria, which digest material inside a closed system, or fermentation of biodegradable materials. Biogas is primarily methane (CH4) and carbon dioxide (CO2) and may have small amounts of hydrogen sulphide (H2S), moisture and siloxanes .Biogas is produced as landfill gas (LFG), which is produced by the breakdown of biodegradable waste inside a landfill due to chemical reactions and microbes, or as digested gas, produced inside an anaerobic digester. By converting cow manure into methane biogas via anaerobic digestion, the millions of cattle in the United States would be able to produce 100 billion kilowatt hours of electricity, enough to power millions of homes across the United States. In fact, one cow can produce enough manure in one day to generate 3 kilowatt hours of electricity; the dangers of biogas are mostly similar to those of natural gas, but with an additional risk from the toxicity of its hydrogen sulfide fraction. Biogas can be explosive when mixed one part biogas to 8-20 parts air.

Track 5: Biofuels

Biofuels are fuels that can be processed from numerous types of biomass. First generation biofuels are processed from the sugars and vegetable oils formed in arable crops, which can be smoothly extracted applying conventional technology. In comparison, advanced biofuels are made from lignocellulosic biomass or woody crops, agricultural residues or waste, which makes it tougher to extract the requisite fuel. Advanced biofuel technologies have been devised because first generation biofuels manufacture has major limitations. First generation biofuel processes are convenient but restrained in most cases: there is a limit above which they cannot yield enough biofuel without forbidding food supplies and biodiversity. Many first generation biofuels rely on subsidies and are not cost competitive with prevailing fossil fuels such as oil, and some of them yield only limited greenhouse gas emissions savings. When considering emissions from production and transport, life-cycle assessment from first generation biofuels usually approach those of traditional fossil fuels. Advanced biofuels can aid resolving these complications and can impart a greater proportion of global fuel supply affordably, sustainably and with larger environmental interests.

Track 6: Bioethanol

The principle fuel used as a petroleum substitute is bioethanol. Bioethanol is mainly produced by the sugar fermentation process, although it can also be produced by the chemical process of reacting ethylene with steam. The main source of sugar required to produce ethanol comes from fuel or energy crops. These fuel crops are normally grown specifically for energy use and include maize, corn and wheat crops, waste straw, willow, sawdust, reed canary grass, cord grasses, Jerusalem artichoke, Myscanthus and sorghum plants. There is also ongoing research and development into the use of municipal solid wastes to produce ethanol fuel. Brazil and the United States account for over 70 percent of all ethanol production in the world today with the USA producing an estimated 6,500 Million gallons a year. Bioethanol produces only carbon dioxide and water as the waster products on burning, and the carbon dioxide released during fermentation and combustion equals the amount removed from the atmosphere while the crop is growing This fuel is not suitable for use in all cars and you should check compatibility with your vehicle manufacturer before using it. If in doubt use the standard SP95 or SP98 Octane unleaded fuel which continues to be available alongside the new fuel. Researchers have recently launched a proposal to cultivate massive amounts of seaweed or algae. They laims that the project could occupy about ten thousand kilometers of seaweed farm and they estimated that the farm would be able to produce bioethanol from algae, as much as 20 million kiloliters or 5.3 billion gallons of bioethanol per year.

Track 7: Bioenergy Conversion methods

The process to convert biomass solid raw material to fuel gas or chemical feedstock gas (syngas) is called gasification. Chemical conversion of gas would be expensive and there are microorganisms that can convert the CO, H(2), and CO(2) gas to fuels. The discovery of organisms which are capable of higher product yield, as metabolic engineering of microbial catalyst, will make this technology a viable option for reducing our dependency on fossil fuels. Different conversion methods are gas production, Pyrolysis , Anaerobic digestion, Biorefineries, Bioethanol production and sugar release from biomass. Production of energy crops could potentially compete for land with food cropping as demand for biomass increases. Biomass customers may be locked in long-term supply contracts with a single supplier making it difficult to get competitive pricing in the future. Alternative impacts are similar to those covered in the District Heating and Combined Heat and Power pages. The non-destructive pilot market is estimated to be valued at USD 12.98 Billion in 2015 and is projected to outstretch USD 18.88 Billion by 2020, at a CAGR of 7.78% from 2014 to 2020. A new Bioenergy International aimed at developing countries is now on the horizon.

Track 8: Bioenergy Applications

Bioenergy is conversion of biomass resources such as agricultural and forest residues, organic municipal waste and energy crops to useful energy carriers including heat, electricity and transport fuels. Biomass is increasingly being used for modern applications such as dendro-power, co-generation and Combined Heat and Power generation (CHP). Depending on the resource availability and technical, economic and environmental impact, these can be attractive alternatives to fossil fuel based applications. Bioenergy, a renewable energy resource particularly suitable for electricity, heating & cooling in transport, will be at the core of this sectorial shift in renewable energy production and use and is expected to become the dominant form of RES before 2020.

Track 9: Green energy and economy

Green energy mainly involves natural energetic processes which will be controlled with very little pollution. Anaerobic digestion, geothermic power, wind power, small-scale hydropower, solar power, biomass power, periodic event power, wave power, and a few styles of atomic power belongs to the green energy. Once energy is purchased from the electricity network, the ability reaching the buyer won't essentially be generated from Green energy sources. The native utility company, utility, or state power pool buys their electricity from electricity producers World Health Organization could also be generating from fuel, nuclear or renewable energy sources. In several countries Green energy presently provides a really bit of electricity, generally contributing 2% to 5% to the overall pool. Green energy customers either obligates the utility corporations to extend the quantity of green energy that they purchase from the or directly fund the green energy through a green power supplier. Green economy can be defined as an economy that aims at reducing environmental risks and ecological scarcities, which aims for property development while not degrading the atmosphere in keeping with the United Nations setting Programme. It closely connected with ecological economic science, however contains a lot of politically applied focus. A green economy is thought of together that is low carbon, resource economical and socially comprehensive. It closely connected with ecological economic science, however contains a lot of politically applied focus. A low-carbon economy additionally called low-fossil-fuel economy, or decarbonized economy is an economy supported low carbon power sources that so contains a negligible output of greenhouse emission emissions into the setting region, however specifically refers to the greenhouse emission CO2. Greenhouse emission emissions as a result of human action area unit progressively either inflicting global warming or creating global climate change worse.

Track 10: Bioenergy Transition

Biomass plant material and animal waste IS used to create transportation fuels and generate electricity. Biomass energy is derived from plant-based material and solar energy has been converted into organic matter. Biomass can be used in a variety of energy-conversion process to yield power, heat, steam, and fuel. Biomass is used by food processing industries, animal feed industry, and wood products industry, which includes construction and fiber products (paper and derivatives), along with chemical products made from these industries that have diverse applications including detergents, biofertilizers, and erosion control products. The biggest opportunity for the global bioenergy technology is the increasing demand for electricity across the world.

Track 11: Solar energy

Solar energy has being derived from natural sources that doesn’t harm the behavioural and environmental factors. The energy which is taken from the sun is converted into solar energy (thermal or electrical) for further use. Fuel production is also done from solar energy with the help of high temperature. In energy storage, energy is capture which is produced at one time and is store for future use. Economics of solar energy depends upon usages and it is always varies from country to country. Solar panels are greater way to lock solar electricity rates. Solar also increases the value of place where it is plentily available. Wind energy produces from wind to generate electricity. It mechanical preforms the energy to produce large amount of energy for large use. It can be a good replacement to fossil fuel, renewable, widely distributed and produces no greenhouse gases and small space for installing. Wind farms consists of many wind turbines individually which are connected to the electric power network. Offshore wind is stronger than on land and has less impact on appearance of the landscape. About the production and capacity it depends upon the usage in every country. The effects on the atmosphere are less difficult than those of other sources.

Track 12: Processes for Bioenergy

Bio-carbon liquid, biofuel and gas are the products of thermal decomposition of biomass. Gasification process is conducted to ordinary reactors or in reactors with a fluidal field. During hydrothermal gasification process, hydrogen energy, carbon oxide and some amount of methane and superior hydrocarbons are produced. Liquids derived from biomass resources such as ethanol and bio-oils can be reformed to produce hydrogen in a process similar to natural gas reforming. Biomass derived liquids can be transported more easily than biomass feed stocks. The bioenergy technology faces challenges in terms of technological assistance, economics and knowledge.

Market Analysis

(THEME : Bioenergy: Mobilizing the Bioeconomy and Globe through Innovation for a sustainable world)


Bioenergy is renewable energy made available from materials derived from biological sources. Biomass is any organic material which has stored sunlight in the form of chemical energy. As a fuel it may include wood, wood waste, straw, manure, sugarcane, and many other by products from a variety of agricultural processes. Some of the important components of the bio energy market are biogas, starch-based and cellulosic ethanol, biodiesel, etc. Presently, the biofuels segment is the only one to have shown great promise of achieving large-scale CO2 emission reductions. According to analysts, the growth of this segment is also expected to create jobs, improve energy security, and boost economic growth. The bio energy market faces challenges in terms of technological assistance, economics, and knowledge. Several environmentalists are also opposed to the idea of burning forest biomass as it leads to greenhouse gas emissions. However, the biggest opportunity for the global bio energy market is the increasing demand for electricity across the world.

The organizing committee is gearing up for an informative conference program including plenary lectures, symposia, workshops on a variety of topics, poster presentations and various programs for participants from  all over the world. We invite you to join us at the Bioenergy -2018, where you will be sure to have a meaningful experience with scholars from around the world. All members of the Bioenergy-2018 organizing committee look forward to meeting you in Madrid, Spain.

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Importance & Scope:

The demand for renewable energy is growing enormously. From the evidence available today, we believe that renewable energy could, with developments in technology and favourable policy constitute up to 30% of the world transport fuel mix by 2030. The advantages of renewable energy – whether in greenhouse gas benefits, energy security or rural development-mean that many governments are keen to foster the industry through current phases of technology development to deliver material scale and reduced costs. The world is in a state of renewable energy fever. In 2006 biofuel constituted 49 bnlitres, or 3%, of the 1,600 billion litre market for gasoline and diesel fuel. By 2015 the renewable energy market is likely to have tripled to 155 billion litres. In practical terms that is an increase of around 10 billion litres per year over ten years. In terms of current ethanol yields of 5,250ltrs / ha, this equates to an increase of land use for renewable energy of approximately 17,000 square km per year. The bulk of the global demand for ethanol and biodiesel comes from a few major regions. The USA accounted for very nearly 50% of global ethanol consumption in 2006, with Brazil taking 36% of global volumes. The EU accounted for 75% of global biodiesel consumption in 2006. The reason why we believe the feverish rate of growth is likely to materialize is because, with no carbon beneficial substitutes available in the near term, renewable energy are being promoted by governments. Clear examples of this are the trends of regulations in the EU, and the intentions announced in the US. BP is already a major player in the global renewable energy market. In 2006 BP blended 3,016 million litres of ethanol into gasoline – a 25% increase on the previous year. Thus BP is already well exposed to the renewable energy fever – and the theme of this paper is to suggest how the industry can tap the heat of the fever in a positive sense.

The renewable energy policies in the European Union have already led to a significant progress; the energy mix should further change until 2020. Italy is planning to meet the 2020 targets on renewable energies also thanks to a relevant paradigm shift in renewable energy exploitation. Indeed, in 2005 the sector where RES were more present in Italy was electricity production with 203 PJ of renewable origin, while in the heating and cooling sector renewable energy penetration was limited to 80 PJ. On the contrary, in 2020 heating and cooling is expected to absorb the highest amount of renewable energy (438 PJ) with renewable electricity expected to count for 356 PJ. Bioenergy, a renewable energy resource particularly suitable for electricity, heating & cooling and in transport, will be at the core of this sectorial shift in renewable energy production and use and is expected to become the dominant form of RES before 2020. The paper makes a detailed analysis of the recent developments and expected evolution of the Italian energy mix in next decade. It provides an overview of the Italian bioenergy sector in comparison with other Renewable Energy Sources (RES) and with leading countries in the European Union with a special focus on the production, exploitation and potentials on the basis of the analysis of the Italian National Renewable Action Plan.

Why Fankfurt?

Frankfurt is the largest city in the German state of Hesse and the fifth-largest city in Germany. Frankfurt is home to many cultural and educational institutions, including the Goethe University and Frankfurt University of Applied Sciences, many museums and two major botanical gardens: the Palmengarten and the Botanical Garden of Goethe University. Frankfurt is a global hub for commerce, culture, education, tourism and traffic. It is the most important financial centre on the European mainland, with the HQs of the European Central Bank, German Federal Bank, Frankfurt Stock Exchange, Deutsche Bank, Commerzbank, DZ Bank, several fintech start-ups and other institutes. Messe Frankfurt is one of the world's largest trade fairs. Major fairs include the Frankfurt Motor Show, the world's largest motor show, and the Frankfurt Book Fair, the world's largest book fair. Frankfurt has many high-rise buildings in the city centre, forming the Frankfurt skyline. It is one of the few cities in the European Union to have such a skyline and because of it Germans sometimes refer to Frankfurt as Mainhattan, a portmanteau of the local Main River and Manhattan.

Frankfurt is also a centre for commerce, culture, education, tourism and web traffic. Messe Frankfurt is one of the world's largest trade fairs at 578,000 square metres and ten exhibition halls, a central logistics centre and an attached convention centre. Major trade fairs include the Frankfurt Motor Show, the world's largest motor show, and the Frankfurt Book Fair, the world's largest book fair. Frankfurt is also home to many cultural and educational institutions including the Johann Wolfgang Goethe University and Frankfurt University of Applied Sciences, many museums (e.g. Städel, Naturmuseum Senckenberg, Schirn Kunsthalle Frankfurt, Goethe House), and two major botanical gardens, the Palmengarten, which is Germany's largest, and the Botanical Garden of the Goethe University.  

Frankfurt is home to influential educational institutions, including the Goethe University, the UAS, the FUMPA, and graduate schools like the Frankfurt School of Finance & Management. Its renowned cultural venues include the concert hall Alte Oper, Europe's largest English Theatre and many museums (e.g. the Museumsufer ensemble with Städel and Liebieghaus, Senckenberg Natural Museum, Goethe House), the Schirn art venue at the old town. Frankfurt's skyline is shaped by some of Europe's tallest skyscrapers. The city is also characterised by various green areas and parks, including the central Wallanlagen, the City Forest and two major botanical gardens, the Palmengarten and the University's Botanical Garden. In electronic music, Frankfurt has been a pioneering city since the 1980s, with renowned DJs including Sven Väth, Marc Trauner, Scot Project, Kai Tracid, and the clubs Dorian Gray, U60311, Omen and Cocoon. In sports, the city is known as the home of the top tier football club Eintracht Frankfurt, the basketball club Frankfurt Skyliners, the Frankfurt Marathon and the venue of Ironman Germany. It's the seat of German sport unions for Olympics, football and motor sports.

Why to attend???

Meet highly qualified and experienced Scientists from around the world researching on Bioenergy, this is your single best opportunity to reach the largest assemblage of participants from all over the world. Conduct demonstrations, distribute knowledge meet with highly qualified scientists, discuss new researches, and receive name recognition at this 2-day event. World-renowned speakers, the most recent techniques, tactics, and the newest updates in Biofuels and Bioenergy are hallmarks of this conference. Be Part of it! This conference focusing on all the major aspects in the field of Bioenergy It would be beneficial for all the students who ever willing to enter into corporate as well as research fields targeting to the respective field. Chance to form alliance with emerging or established companies/ Research institutes in the respective field.

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Past Conference Report

Bioenergy 2017 Past Conference Report

The 5th World Bioenergy Congress and Expo, hosted by the Conference Series LLC was held during June 29-30, 2017 at Madrid, Spain with the theme “Bioenergy: Upgrading Sources of Energy for Future Generation”. Benevolent response and active participation was received from the scientists, engineers, researchers, students and leaders from the fields of Bioenergy, who made this event successful.

The meeting was carried out through various sessions, in which the discussions were held on the following major scientific tracks:

·         Biomass Feed Stocks for Renewable Energy Generation

·         Bioenergy Conversion

·         Bioenergy Transition

·         Processes for Bioenergy

·         Bioenergy Applications

·         Biogas

·         Biodiesel

·         Renewable Energy

·         Biomass

·         Biofuels

·         Bioethanol

·         Biomass Technology

·         Bioenergy Companies and Market

The conference was initiated with a series of lectures delivered by both Honorable Guests and members of the Keynote Forum. The list included:

§  Lew P Christopher, Lakehead University, Canada

§  Animesh Dutta, University of Guelph, Canada

§  Weilan Shao, Jiangsu University, China

§  Rintu Banerjee, Indian Institute of Technology, India

§  Mohammed Farid, University of Auckland, New Zealand

§  Irene M C LO, The Hong Kong University of Science and Technology, Hong Kong

§  Kunio Yoshikawa, Tokyo Institute of Technology, Japan

§  Boon Leong Lim, University of Hong Kong, China

§  Jana Zabranska, University of Chemistry and Technology, Czech Republic

§  Dana Pokorna, University of Chemistry and Technology, Czech Republic

§  David M Babson, US Department of Energy, Bioenergy Technologies Office, USA

§  Richard Sayre, Los Alamos National Laboratory, USA

Conference Series LLC offers its heartfelt appreciation to Organizing Committee Members, adepts of field, various outside experts, company representatives and other eminent personalities who supported the conference by facilitating the discussion forums. Conference Series

Thanks to all of our wonderful speakers and conference attendees, Bioenergy 2017 Conference was our best ever!

With the grand success of Bioenergy-2017, Conference Series LLC is proud to announce the "11th World Bioenergy Congress and Expo" to be held during July 2-4, 2018 at Frankfurt, Germany.

Let us meet again @ Bioenergy-2018 

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Supported By

Journal of Fundamentals of Renewable Energy and Applications Journal of Bioprocessing and Biotechniques International Journal of Waste Resources

All accepted abstracts will be published in respective Conferenceseries International Journals.

Abstracts will be provided with Digital Object Identifier by

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What People Say....

I truely enjoy the conference specially the quality of presentation, the food, the collogical environment. It is a very good conference with a good experience.


Animesh Dutta, University of Guelph, Canada

The scientific contents of the conference is highly appreciable. Selected renowned scientists from all over the world have been invited. I think the entire scientific community have been enriched with their lecture and scientific discussion. I enjoyed the conference very much.


Rintu Banerjee, Indian Institute of Technology, India

Bioenergy 2017 conference was good and went well. The quality of presentations and range of topics covered was very positive.


Lew P. Christopher, Lakehead University Canada

The organization of the Journal, the conference room as well as the food and catering was very satisfying. The conference was very interesting: it was good for networking and there have been many interesting presentations.


Simon Juan Tappen, Bavarian State Research Center for Agriculture, Germany

Thank you for the conference and everything. It was nice to be part of it


Bobbo Nfor Tansi, Brandenburg University of Technology, Germany

Its my grateful that i have joint this conference


Endro Gunawan, Indonesian Center for Agricultural Socio Economic and Policy Studies, Indonesia

let me thank for the very beneficial conference Bioenergy 2017, which was held in Madrid. It was very useful to meet experts from our job and their research.


Dana Pokorna, University of Chemistry and Technology Prague Czech Republic


  • Algae Biomass For Advanced Biofuel Production
  • Biodiesel Production
  • Bioenergy Feedstock Procurement Strategies
  • Bioenergy And Anaerobic Digestion
  • Bioenergy Crops
  • Bioenergy Innovation
  • Bioenergy Investments In Emerging Markets
  • Bioenergy Markets
  • Bioenergy Power Plants
  • Bioenergy Technologies
  • Bioenergy To Liquid Biofuels
  • Bioenergy-Biomass To Biofuels
  • Biofuels Economics, Sustainability, Environmental And Policy
  • Bioheat
  • Biomass Bioconversion For Fuels And Chemicals
  • Biomass Production And Use
  • Biomass To Biofuels Conversion Factors
  • Biomass To Liquid Biofuels
  • Cellulosic Ethanol-Biofuel Beyond Corn
  • Challenges And Opportunities In The Emerging Bioenergy Business
  • Gaseous Fuels And Bioelectricity
  • How Fuel Ethanol Is Made From Corn
  • On-farm Oill-based Biodiesel Production
  • Perennial Grass Biomass Production And Utilization
  • Pyrolysis Of Lignocellulosic Biomass
  • Sustainable Aviation Biofuels
  • Synthesis And Characterization Of Biodiesel
  • Wood And Grass Biomass As Biofuels
  • Wood And Grass Energy
  • Wood Bioenergy