Your search keyword '"Nicolae Scarlat"' showing total 14 results

1. Strategic deployment of riparian buffers and windbreaks in Europe can co-deliver biomass and environmental benefits

Author

Oskar Englund, Christel Cederberg, Nicolae Scarlat, Pål Börjesson, Göran Berndes, Blas Mola-Yudego, and Ioannis Dimitriou

Subjects

Förnyelsebar bioenergi, Biomass, Environmental protection, Bioenergy, Miljö- och naturvårdsvetenskap, media_common.cataloged_instance, GE1-350, European union, Agricultural productivity, General Environmental Science, media_common, Riparian zone, geography, QE1-996.5, geography.geographical_feature_category, Other Environmental Engineering, Geology, Windbreak, Miljövetenskap, Environmental sciences, Environmental Sciences related to Agriculture and Land-use, Renewable Bioenergy Research, Software deployment, General Earth and Planetary Sciences, Environmental science, Annan naturresursteknik, Common Agricultural Policy, Environmental Sciences

Abstract

Deployment of riparian buffers and windbreaks can effectively reduce nitrogen emissions to water and soil loss by wind erosion in Europe, according to analyses of three implementation scenarios. Within the scope of the new Common Agricultural Policy of the European Union, in coherence with other EU policies, new incentives are developed for farmers to deploy practices that are beneficial for climate, water, soil, air, and biodiversity. Such practices include establishment of multifunctional biomass production systems, designed to reduce environmental impacts while providing biomass for food, feed, bioenergy, and other biobased products. Here, we model three scenarios of large-scale deployment for two such systems, riparian buffers and windbreaks, across over 81,000 landscapes in Europe, and quantify the corresponding areas, biomass output, and environmental benefits. The results show that these systems can effectively reduce nitrogen emissions to water and soil loss by wind erosion, while simultaneously providing substantial environmental co-benefits, having limited negative effects on current agricultural production. This kind of beneficial land-use change using strategic perennialization is important for meeting environmental objectives while advancing towards a sustainable bioeconomy.

Published

2021

2. Quantification of the carbon intensity of electricity produced and used in Europe

Author

Monica Padella, Nicolae Scarlat, and Matteo Prussi

Subjects

Upstream (petroleum industry), Power station, Natural resource economics, business.industry, Well-to-Wheel, Mechanical Engineering, Carbon intensity, Electricity, Greenhouse gas emissions, Building and Construction, Management, Monitoring, Policy and Law, Energy transition, General Energy, Electricity generation, Greenhouse gas, Environmental science, media_common.cataloged_instance, Production (economics), European union, business, media_common

Abstract

The EU has a comprehensive legislation to facilitate the energy transition towards a low carbon energy system and achieve the EU’s Paris Agreement commitments for reducing greenhouse gas emissions. The European Green Deal is an integral part of the EU strategy for a sustainable and climate neutral economy by 2050. The decarbonisation of the power generation is essential to achieve the goal of decarbonising the energy and transport sectors. This paper presents a study conducted to quantify the carbon emissions associated to the production of electricity produced and used in European countries, based on a comprehensive methodology developed for this purpose. A spreadsheet model has been developed that considers the various sources for electricity generation, the type of plants, conversion efficiencies, upstream emissions and emissions from power plant construction, as well as the electricity trade. The results show the greenhouse gas emissions from the production and use of electricity in all European countries, revealing significant variations between countries. The carbon intensity of electricity shows a clear reduction trend since 1990, for most of the European countries. In the European Union, carbon intensity of electricity used at low voltage degreased from 641 gCO2eq/kWh in 1990 to 334 gCO2eq/kWh in 2019, and this trend is expected to continue in the coming years.

Published

2022

3. Biogas: Developments and perspectives in Europe

Author

Jean Francois Dallemand, Fernando Fahl, and Nicolae Scarlat

Subjects

Waste management, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, 02 engineering and technology, Renewable energy, Electricity generation, Biogas, Bioenergy, Biofuel, Heat generation, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, media_common.cataloged_instance, Electricity, European union, business, media_common

Abstract

This paper presents an overview of the development and perspectives of biogas in and its use for electricity, heat and in transport in the European Union (EU) and its Member States. Biogas production has increased in the EU, encouraged by the renewable energy policies, in addition to economic, environmental and climate benefits, to reach 18 billion m3 methane (654 PJ) in 2015, representing half of the global biogas production. The EU is the world leader in biogas electricity production, with more than 10 GW installed and a number of 17,400 biogas plants, in comparison to the global biogas capacity of 15 GW in 2015. In the EU, biogas delivered 127 TJ of heat and 61 TWh of electricity in 2015; about 50% of total biogas consumption in Europe was destined to heat generation. Europe is the world's leading producer of biomethane for the use as a vehicle fuel or for injection into the natural gas grid, with 459 plants in 2015 producing 1.2 billion m3 and 340 plants feeding into the gas grid, with a capacity of 1.5 million m3. About 697 biomethane filling stations ensured the use 160 million m3 of biomethane as a transport fuel in 2015.

Published

2018

4. A spatial analysis of biogas potential from manure in Europe

Author

Fernando Fahl, Fabio Monforti, Jean-François Dallemand, Nicolae Scarlat, and Vicenzo Motola

Subjects

Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Environmental engineering, 02 engineering and technology, Manure, Renewable energy, Anaerobic digestion, Biogas, Biofuel, Bioenergy, 0202 electrical engineering, electronic engineering, information engineering, media_common.cataloged_instance, Environmental science, European union, business, Energy source, media_common

Abstract

Anaerobic digestion is increasingly used worldwide to generate energy from biogas, bringing significant economic and environmental benefits. In particular, in the European Union (EU), biogas can contribute significantly in several countries to reach the renewable energy targets. This study provides an assessment of the spatial distribution of the biogas potential of farm manure from livestock and poultry in Europe, which is a key issue for the location and economic performances of a bioenergy plant. Biogas estimates provided in this study are computed through a spatial analysis algorithm that uses data of livestock and poultry, manure production and collection, leading to the evaluation of the spatial distribution of biogas potential at 1 km spatial resolution. Following this analysis, the theoretical biogas potential of manure was estimated at 26 billion m3 biomethane in Europe (23 billion m3 biomethane in the EU) and the realistic biogas potential, counting on collectible manure, was assessed at 18 billion m3 biomethane in Europe (16 billion m3 biomethane in the EU). Several maps provide the suitable locations and capacity of manure-based biogas plants in two different scenarios. Between 13,866 and 19,482 biogas plants could be built in Europe, with a total installed capacity between 6144 MWe and 7145 MWe, and an average capacity between 315 kWe and 515 kWe.

Published

2018

5. Status and Opportunities for Energy Recovery from Municipal Solid Waste in Europe

Author

Jean-François Dallemand, Nicolae Scarlat, and Fernando Fahl

Subjects

0106 biological sciences, Energy recovery, Environmental Engineering, Municipal solid waste, Primary energy, Renewable Energy, Sustainability and the Environment, 020209 energy, 02 engineering and technology, 01 natural sciences, Incineration, Waste-to-energy, Environmental protection, 010608 biotechnology, 0202 electrical engineering, electronic engineering, information engineering, Suitability analysis, Environmental science, media_common.cataloged_instance, European union, Tonne, Waste Management and Disposal, media_common

Abstract

This paper provides an overview of waste generation and treatment operations in the European Union (EU) and other European countries and an analysis of the possibilities for the use of municipal solid waste (MSW) for energy production. A geographic information system based methodology was developed to investigate the spatial distribution of MSW and to identify the optimal location for new potential waste-to-energy in Europe. In 2016, there were 512 plants in Europe, with 251 combined heat and power plants, 161 electricity-only and 94 heat-only plants, which provide a total incineration capacity of 93 million tonnes. The suitability analysis showed that there is a potential to implement around 248 new waste to energy plants in the EU and 330 in all Europe, with a total capacity of 37 and 50 million tonnes, respectively. This represents an additional primary energy production of 260 PJ (6.2 Mtoe) in the EU, in comparison to 406 PJ (9.7 Mtoe) already produced in 2015, and about 352 PJ (8.4 Mtoe) in all European countries considered in this analysis.

Published

2018

6. Renewable energy policy framework and bioenergy contribution in the European Union – An overview from National Renewable Energy Action Plans and Progress Reports

Author

Jean-François Dallemand, Manjola Banja, Fabio Monforti-Ferrario, Nicolae Scarlat, and Vincenzo Motola

Subjects

Renewable energy in the European Union, Renewable energy, business.industry, Renewable Energy, Sustainability and the Environment, Environmental impact of the energy industry, Environmental economics, National Renewable Energy Action Plans, Energy policy, 2020 targets, Renewable energy credit, Energy subsidies, Economics, media_common.cataloged_instance, Bioenergy, European union, Feed-in tariff, business, media_common

Abstract

The use of renewable energy is projected to increase substantially in the European Union to reach a share of 20% in final energy consumption and 10% renewable energy in transport by 2020. The renewable energy contribution is further expected to increase to 55%–75% of gross final energy consumption in 2050. According to the latest reports, the European Union has made significant progress since 2005 and is on track to reach its 2020 renewable energy targets. This paper provides a review of the policy framework for renewable energy in the European Union and an analysis of the progress made by the use of renewable energy as well as the expected developments until 2020 and beyond. It focusses on the contribution of bioenergy, the major source among renewables in the European Union. As biomass availability is a critical issue for the bioenergy production, this paper provides an analysis of the biomass demand for reaching the 2020 targets, in relation with the expected domestic supply and biomass potential.

Published

2015

7. The role of biomass and bioenergy in a future bioeconomy: Policies and facts

Author

Jean-François Dallemand, Fabio Monforti-Ferrario, Nicolae Scarlat, and Viorel Nita

Subjects

Resource (biology), Cost effectiveness, 020209 energy, Geography, Planning and Development, 02 engineering and technology, Low-carbon economy, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, 7. Clean energy, Agricultural economics, 12. Responsible consumption, Green economy, Bio-materials, Bioenergy, 11. Sustainability, 0202 electrical engineering, electronic engineering, information engineering, media_common.cataloged_instance, Biomass, European union, Policies, 0105 earth and related environmental sciences, media_common, 2. Zero hunger, business.industry, Bioeconomy, 13. Climate action, Agriculture, Biofuel, business

Abstract

The European Commission has set a long-term goal to develop a competitive, resource efficient and low carbon economy by 2050. Bioeconomy is expected to play an important role in the low carbon economy. This paper provides a review of the policy framework for developing a bioeconomy in the European Union covering energy and climate, agriculture and forestry, industry and research. The Europe has a number of well-established traditional bio-based industries, ranging from agriculture, food, feed, fibre and forest-based industries. This paper proposes an analysis of the current status of bioeconomy in the European Union and worldwide until 2020 and beyond. We estimate the current bio economy market at about € 2.4 billion, including agriculture, food and beverage, agro-industrial products, fisheries and aquaculture, forestry, wood-based industry, biochemical, enzymes, biopharmaceutical, biofuels and bioenergy, using about 2 billion tonnes and employing 22 million persons. New sectors are emerging, such as biomaterials and green chemistry. The transition toward a bioeconomy will rely on the advancement in technology of a range of processes, on the achievement of a breakthrough in terms of technical performances and cost effectiveness and will depend on the availability of sustainable biomass.

Published

2015

8. The possible contribution of agricultural crop residues to renewable energy targets in Europe: A spatially explicit study

Author

F. Monforti, Katalin Bódis, Jean-François Dallemand, and Nicolae Scarlat

Subjects

Crop residue, Renewable Energy, Sustainability and the Environment, business.industry, Biomass, Land cover, Raw material, Renewable energy, Agronomy, Agriculture, Bioenergy, Environmental science, media_common.cataloged_instance, European union, business, media_common

Abstract

This paper provides a geographical assessment of potential bioenergy production in the European Union from residues of eight agricultural crops (wheat, barley, rye, oat, maize, rice, rapeseed and sunflower). The evaluation is geographically explicit at the scale of 1 km2 and is based on two main computational steps. In the first step the amount of crop residues resulting from statistical assessment based on the methodology developed by Scarlat et al. [1] have been spatially allocated on the EU-27 1 territory using several auxiliary geospatial layers describing, for example, land cover, expected biomass productivity derived from soil parameters, climatic zones and topographical conditions. In the second step the number of model power plants (i.e., plants with a size of 50 MW thermal input and a raw material demand of about 100 kt/yr might be conveniently fed with available crop residues was estimated on the basis of two different allocation strategies implying a different grade of optimization. The results show that the estimated crop residue resources in EU-27 could provide fuel for about 850 plants expected to produce about 1500 PJ/yr. Mobilization needs for the residues are also estimated, leading to a total amount of 1.5×1012–2×1012 tkm are necessary for the full potential exploitation.

Published

2013

9. Possible impact of 2020 bioenergy targets on European Union land use. A scenario-based assessment from national renewable energy action plans proposals

Author

Nicolae Scarlat, Jean-Franc¸ois Dallemand, and Manjola Banja

Subjects

Land use, Renewable Energy, Sustainability and the Environment, business.industry, Natural resource economics, Agricultural economics, Renewable energy, Second-generation biofuels, Bioliquids, Agricultural land, Bioenergy, Economics, media_common.cataloged_instance, European union, Arable land, business, media_common

Abstract

According to the renewable energy directive 2009/28/EC, the European Union Member States should increase by 2020 the use of renewable energy to 20% of gross final energy consumption and to reach a mandatory share of 10% renewable energy in the transport sector. This study aims to quantify the impact of 2020 bioenergy targets on the land use in the EU, based on the projections of the National Renewable Action Plans in four scenarios: Scenario 1. Bioenergy targets according to NREAPs; Scenario 2. Bioenergy targets according to NREAPs, no second generation biofuels; Scenario 3. Bioenergy targets according to NREAPs, reduced import of biofuels and bioliquids; Scenario 4. Bioenergy targets according to NREAPs, high imports of biofuels and bioliquids. This study also considers the credit for co-products generated from biofuel production. The analysis reveals that the land used in the EU for bioenergy would range between 13.5 Mha and 25.2 Mha in 2020. This represent between 12.2% and 22.5% of the total arable land used and 7.3% and 13.5% of the Utilised Agricultural Area (UAA). In the NREAPS scenario, about 17.4 Mha would be used for bioenergy production, representing 15.7% of arable land and 9.4% of UAA. The increased demand from biofuels would lead to an increased generation of co-products, replacing conventional fodder for animal feed. Considering the co-products, the land used for bioenergy would range between 8.8 Mha and 15.0 Mha in 2020 in the various scenarios. This represent between 7.9% and 13.3% of the total arable land used in the EU and 4.7% and 8.0% of the UAA. In the NREAPS scenario, when co-products are considered, about 10.3 Mha would be used for biofuels, bioliquids and bioenergy production, representing 9.3% of arable land and 5.6% of agricultural land. This study further provides detailed data on the impact on land use in each Member State.

Published

2013

10. An overview of the biomass resource potential of Norway for bioenergy use

Author

Nicolae Scarlat, Jean-François Dallemand, Dan Asplund, Lars Nesheim, and Odd Jarle Skjelhaugen

Subjects

Resource (biology), Renewable Energy, Sustainability and the Environment, business.industry, Natural resource economics, Fossil fuel, Biomass, Agricultural economics, Renewable energy, Hydroelectricity, Bioenergy, Economics, media_common.cataloged_instance, Energy supply, European union, business, media_common

Abstract

This paper provides an overview of the Norwegian biomass resources for bioenergy use, bioenergy market and frame conditions through a comparison with Denmark, Finland and Sweden, which have a leading role in bioenergy production in the European Union. Although the contribution of renewable energy in Norway is among the highest in Europe (58%), mainly due to hydroelectricity, bioenergy has a low contribution to Norwegian energy supply (6%). As the experience from the other EU Member States showed, long-term, stable policies and relatively strong incentives are needed to initiate and build up a bioenergy market. In Norway, there is still a significant available potential for increasing the bioenergy contribution to the energy supply. The abundance and relatively low prices of energy (i.e. fossil fuels and electricity), in connection with the need of high investment costs, did not favour so far bioenergy production. Additional forest biomass may be mobilized in Norway by more intensive management of currently exploited forests. However, there are several limitations related to topography, accessibility and economics. The biomass resources and the full range of technologies available for heat or electricity generation both at small and large scale that can provide good opportunities for increased bioenergy production. The experience gained in Denmark, Finland and Sweden may be relevant for Norway, as well as for other EU Member States, where there is a deficit of mobilization of biomass resources and insufficient industrial integration of bioenergy with other forest-based sectors.

Published

2011

11. Recent developments of biofuels/bioenergy sustainability certification: A global overview

Author

Jean-François Dallemand and Nicolae Scarlat

Subjects

Engineering, Natural resource economics, business.industry, Environmental resource management, Land-use planning, Certification, Management, Monitoring, Policy and Law, General Energy, Fair trade, Biofuel, Bioenergy, Sustainability, media_common.cataloged_instance, Environmental impact assessment, European union, business, media_common

Abstract

The objective of this paper is to provide a review on the latest developments on the main initiatives and approaches for the sustainability certification for biofuels and/or bioenergy. A large number of national and international initiatives lately experienced rapid development in the view of the biofuels and bioenergy targets announced in the European Union, United States and other countries worldwide. The main certification initiatives are analysed in detail, including certification schemes for crops used as feedstock for biofuels, the various initiatives in the European Union, United States and globally, to cover biofuels and/or biofuels production and use. Finally, the possible way forward for biofuel certification is discussed. Certification has the potential to influence positively direct environmental and social impact of bioenergy production. Key recommendations to ensure sustainability of biofuels/bioenergy through certification include the need of an international approach and further harmonisation, combined with additional measures for global monitoring and control. The effects of biofuels/bioenergy production on indirect land use change (ILUC) is still very uncertain; addressing the unwanted ILUC requires sustainable land use planning and adequate monitoring tools such as remote sensing, regardless of the end-use of the product.

Published

2011

12. Bioenergy production and use in Italy: Recent developments, perspectives and potential

Author

Fabio Monforti-Ferrario, Nicolae Scarlat, J.F. Dallemand, V. Motola, and Motola, V.

Subjects

Engineering, Renewable energy, Renewable Energy, Sustainability and the Environment, business.industry, Natural resource economics, Energy mix, National Renewable Energy Action Plans, Italy, Bioenergy, Energy development, Electricity generation, Energy subsidies, Renewable energy credit, Economy, media_common.cataloged_instance, European union, business, Feed-in tariff, media_common

Abstract

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. © 2013 Elsevier Ltd.

Published

2013

13. Assessment of the availability of agricultural crop residues in the European Union: potential and limitations for bioenergy use

Author

Milan Martinov, Nicolae Scarlat, and Jean-François Dallemand

Subjects

Crops, Agricultural, Crop residue, Conservation of Natural Resources, business.industry, Crop yield, fungi, food and beverages, Agriculture, Refuse Disposal, Agricultural science, Agronomy, Bioenergy, Biofuel, Biofuels, media_common.cataloged_instance, Environmental science, European Union, Soil fertility, European union, Energy source, business, Waste Management and Disposal, media_common

Abstract

This paper provides a resource-based assessment of the available agricultural crop residues for bioenergy production in the European Union, at the level of the 27 Member States. The assessment provides the amount of the residues produced, collected, their present uses and the residues left available for bioenergy. This study considers the crop production and yields and multi-annual yield variation for each crop. The calculation was based on specific residues to product ratios, which were determined, depending on the crop type and crop yield. Sustainable removal rates were considered in order to protect soil fertility. The results show large spatial and temporal variations of available crop residues within EU27. The average amount of crop residues available for bioenergy in EU27 was estimated at 1530 PJ/year, with a variation between 1090 and 1900 PJ/year. The average value represents about 3.2% in final energy consumption in the EU27 while the variation 2.3-4%. This variation, which is even larger at the level of Member States, may result in shortages in biomass supply in some years, when crop residues are available in a lower amount than the average.

Published

2009

14. Optimal energy use of agricultural crop residues preserving soil organic carbon stocks in Europe

Author

Katalin Bódis, Nicolae Scarlat, Jean-François Dallemand, Vincenzo Motola, F. Monforti, and E. Lugato

Subjects

Crop residue, Crop residues, Renewable Energy, Sustainability and the Environment, business.industry, Natural resource economics, Agroforestry, Organic carbon stock, Soil organic matter, Soil carbon, Energy consumption, Renewable energy, Agriculture, Sustainability, media_common.cataloged_instance, Environmental science, Bioenergy, European union, business, Sustainable collection, media_common

Abstract

The European Union has committed itself to ambitious targets of Renewable Energy and bioenergy is expected to play a major role, increasing its contribution to Gross Final Energy Consumption from 2458 PJ in 2005 to 4605 PJ by 2020. Agricultural crop residues are considered a reliable resource for energy uses but important concerns still exist on the potential depletion of Soil Organic Carbon (SOC) stocks that may partially offset the environmental suitability and convenience of their large-scale exploitation. This paper provides an estimate of available agricultural residues and related potential energy production obtainable without impacting the EU SOC stock showing how SOC content preservation imposes the application of different collection rates for agricultural residues across the EU, depending on factors such as climate, soil type, current farming practices and pre-existing cultivation history. The results suggest that a potential amount of residues of 146,000 kt/year of dry matter leading to a potential gross energy production of about 2300 PJ/year could be obtained in EU-27 1 without impacting the current SOC stocks. Agricultural residues are then theoretically able to provide a substantial contribution to renewable energy targets in several EU-27 countries as well as accommodating competitive uses and SOC preservation. Nevertheless, the spatial pattern of results also clearly indicates regions and countries where residues exploitation should be handled with care and current practices on residues collection are risky in term of SOC content. The estimate provided builds on results from previous studies (e.g., Scarlat et al. Waste Manage 2010;30:1889–1897, Monforti et al. Renewable Sustainable Energy Rev 2013;19:666–677) and on the analysis of future scenarios of SOC content obtained from an innovative pan-EU modelling platform (Lugato et al. Global Change Biol 2014;20:313–326. doi:10.1111/gcb.12292. Such an integrated approach, making use of soil, climate and energy transformation modelling, is unique and constitutes a substantial applied value for assessing the sustainability of crop residues use.