SwePub - sökning: WFRF:(Lehtveer Mariliis 1983)

Numrering	Referens	Omslagsbild	Hitta
1.	Dahal, Karna, 1984, et al. (författare) Reviewing the development of alternative aviation fuels and aircraft propulsion systems 2020 Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract Alternative aviation fuels such as bio-jet fuels, liquid natural gas (LCH4), hydrogen (H2), electro-jet fuels and direct electricity use play an important role in decarbonizing the aviation sector. New aircraft propulsion systems are being developed but low-blending of fuels is possible for some options. It is imperative to understand the technical, environmental and economic performance of the different alternative aviation fuels and the new engine and propulsion technologies for the utilization of these fuels. We have reviewed various literature to map the current status of development on alternative aviation fuels and related aircraft propulsion systems in relation to different perspective such as their cost and technical maturity. There are several challenges related to the design and implementation of the fuels and new propulsion systems. For instance, the volumetric energy content of alternative fuels is lower than the conventional aviation fuels which requires larger fuel storage tanks. Despite the advantageous environmental performance, both the bio-jet and electro-jet fuels are currently not economically competitive. Yet, studies forecast that increased use of alternative aviation fuels is possible after modifications of engines, fuel storage tanks and improvements of the aerodynamics of aircraft and by introducing subsidies and/or carbon taxes on conventional jet fuels.
2.	Dahal, Karna, 1984, et al. (författare) Techno-economic review of alternative fuels and propulsion systems for the aviation sector 2021 Ingår i: Renewable and Sustainable Energy Reviews. - : Elsevier BV. - 1879-0690 .- 1364-0321. ; 151 Forskningsöversikt (refereegranskat)abstract Substitution of conventional jet fuel with low-to zero-carbon-emitting alternative aviation fuels is vital for meeting the climate targets for aviation. It is important to understand the technical, environmental, and economic performance of alternative aviation fuels and prospective engine and propulsion technologies for future aircraft. This study reviews alternative fuels and propulsion systems, focusing on costs and technical maturity, and presents conceptual aircraft designs for different aviation fuels. The cost review includes minimum jet fuel selling price (MJFSP) for alternative aviation fuels. Direct operating cost (DOC) is estimated based on the conceptual aircraft designs and the reviewed MJFSP. The DOCs for bio-jet fuel (5.0–9.2 US cent per passenger-kilometer (¢/PAX/km)), fossil and renewable liquefied hydrogen (5.9–10.1 and 8.1–23.9 ¢/PAX/km, respectively), and electro-methane and electro-jet fuel (5.6–16.7 and 9.2–23.7 ¢/PAX/km, respectively) are higher than for conventional jet fuel (3.9–4.8 ¢/PAX/km) and liquefied natural gas (4.2–5.2 ¢/PAX/km). Overall, DOC of renewable aviation fuels is 15–500 % higher than conventional jet fuels. Among the bio-jet fuels, hydroprocessed esters and fatty acids (23–310 $/GJ) and alcohol-to-jet (4–215 $/GJ) pathways offer the lowest MJFSPs. The implementation of alternative fuels in existing aircraft engines and the design and development of appropriate propulsion systems and aircraft are challenging. The overall cost is a key factor for future implementation. Bio-jet fuel is most promising in the near term while hydrogen and electrofuels in the long term. The level of carbon tax on fossil jet fuels needed for the latter options to be competitive depend on the hydrogen production cost.
3.	Fridahl, Mathias, 1980-, et al. (författare) Bioenergy with carbon capture and storage (BECCS): Global potential, investment preferences, and deployment barriers 2018 Ingår i: Energy Research and Social Science. - : Elsevier BV. - 2214-6296 .- 2214-6326. ; 42, s. 155-165 Tidskriftsartikel (refereegranskat)abstract Keeping global warming well below 2 °C entails radically transforming global energy production and use. However, one important mitigation option, the use of bioenergy with carbon capture and storage (BECCS), has so far received only limited attention as regards the sociopolitical preconditions for its deployment. Using questionnaire data from UN climate change conferences, this paper explores the influence of expertise, actor type, and origin on respondents’ a) preferences for investing in BECCS, b) views of the role of BECCS as a mitigation technology, globally and domestically, and c) assessment of possible domestic barriers to BECCS deployment. Non-parametric statistical analysis reveals the low priority assigned to investments in BECCS, the anticipated high political and social constraints on deployment, and a gap between its low perceived domestic potential to contribute to mitigation and a slightly higher perceived global potential. The most important foreseen deployment constraints are sociopolitical, which in turn influence the economic feasibility of BECCS. However, these constraints (e.g. lack of policy incentives and social acceptance) are poorly captured in climate scenarios, a mismatch indicating a need for both complemented model scenarios and further research into sociopolitical preconditions for BECCS.
4.	Göransson, Lisa, 1982, et al. (författare) The benefit of collaboration in the North European electricity system transition - System and sector perspectives 2019 Ingår i: Energies. - : MDPI AG. - 1996-1073 .- 1996-1073. ; 12:24 Tidskriftsartikel (refereegranskat)abstract This work investigates the connection between electrification of the industry, transport, and heat sector and the integration of wind and solar power in the electricity system. The impact of combining electrification of the steel industry, passenger vehicles, and residential heat supply with flexibility provision is evaluated from a systems and sector perspective. Deploying a parallel computing approach to the capacity expansion problem, the impact of flexibility provision throughout the north European electricity system transition is investigated. It is found that a strategic collaboration between the electricity system, an electrified steel industry, an electrified transport sector in the form of passenger electric vehicles (EVs) and residential heat supply can reduce total system cost by 8% in the north European electricity system compared to if no collaboration is achieved. The flexibility provision by new electricity consumers enables a faster transition from fossil fuels in the European electricity system and reduces thermal generation. From a sector perspective, strategic consumption of electricity for hydrogen production and EV charging and discharging to the grid reduces the number of hours with very high electricity prices resulting in a reduction in annual electricity prices by up to 20%.
5.	Hansson, Julia, 1978, et al. (författare) The Potential Role of Ammonia as Marine Fuel-Based on Energy Systems Modeling and Multi-Criteria Decision Analysis 2020 Ingår i: Sustainability. - : MDPI AG. - 2071-1050. ; 12:8 Tidskriftsartikel (refereegranskat)abstract To reduce the climate impact of shipping, the introduction of alternative fuels is required. There is a range of different marine fuel options but ammonia, a potential zero carbon fuel, has recently received a lot of attention. The purpose of this paper is to assess the prospects for ammonia as a future fuel for the shipping sector in relation to other marine fuels. The assessment is based on a synthesis of knowledge in combination with: (i) energy systems modeling including the cost-effectiveness of ammonia as marine fuel in relation to other fuels for reaching global climate targets; and (ii) a multi-criteria decision analysis (MCDA) approach ranking marine fuel options while considering estimated fuel performance and the importance of criteria based on maritime stakeholder preferences. In the long-term and to reach global GHG reduction, the energy systems modeled indicate that the use of hydrogen represents a more cost-effective marine fuel option than ammonia. However, in the MCDA covering more aspects, we find that ammonia may be almost as interesting for shipping related stakeholders as hydrogen and various biomass-based fuels. Ammonia may to some extent be an interesting future marine fuel option, but many issues remain to be solved before large-scale introduction.
6.	Johansson, Daniel, 1975, et al. (författare) The role of negative carbon emissions in reaching the Paris climate targets: The impact of target formulation in integrated assessment models 2020 Ingår i: Environmental Research Letters. - : IOP Publishing. - 1748-9326 .- 1748-9318. ; 15:12 Tidskriftsartikel (refereegranskat)abstract Global net-negative carbon emissions are prevalent in almost all emission pathways that meet the Paris temperature targets. In this paper, we generate and compare cost-effective emission pathways that satisfy two different types of climate targets. First, the common approach of a radiative forcing target that has to be met by the year 2100 (RF2100), and, second, a temperature ceiling target that has to be met over the entire period, avoiding any overshoot. Across two integrated assessment models (IAMs), we found that the amount of net-negative emissions - when global net emissions fall below zero - depends to a large extent on how the target is represented, i.e. implemented in the model. With a temperature ceiling (no temperature overshoot), net-negative emissions are limited and primarily a consequence of trade-offs with non-CO2 emissions, whereas net-negative emissions are significant for the RF2100 target (temperature overshoot). The difference becomes more pronounced with more stringent climate targets. This has important implications: more stringent near-term emission reductions are needed when a temperature ceiling is implemented compared to when an RF2100 target is implemented. Further, in one IAM, for our base case assumptions, the cost-effective negative carbon emissions (i.e. gross anthropogenic removals) do not depend to any significant extent on how the constraint is implemented, only, largely, on the ultimate stringency of the constraint. Hence, for a given climate target stringency in 2100, the RF2100 target and the temperature ceiling may result in essentially the same amount of negative carbon emissions. Finally, it is important that IAM demonstrate results for diverse ways of implementing a climate target, since the implementation has implications for the level of near-term emissions and the perceived need for net-negative emissions (beyond 2050).
7.	Johansson, Viktor, 1991, et al. (författare) Biomass in the electricity system: A complement to variable renewables or a source of negative emissions? 2019 Ingår i: Energy. - : Elsevier BV. - 0360-5442 .- 1873-6785. ; 168, s. 532-541 Tidskriftsartikel (refereegranskat)abstract Biomass is often assigned a central role in future energy system scenarios as a carbon sink, making negative greenhouse gas emissions possible through carbon capture and storage of biogenic carbon dioxide from biomass-fuelled power plants. However, biomass could also serve as a strategic complement to variable renewables by supplying electricity during hours of high residual load. In this work, we investigate the role of biomass in electricity systems with net zero or negative emissions of carbon dioxide and with different levels of biomass availability. We show that access to biomass corresponding to ca. 20% of the electricity demand in primary energy terms, is of high value to the electricity system. Biomass for flexibility purposes can be a cost-efficient support to reach a carbon neutral electricity system with the main share of electricity from wind and solar power. Biomass-fired power plants equipped with carbon capture and storage in combination with natural gas combined cycle turbines are identified as being the cost-effective choice to supply the electricity system with flexibility if the availability of biomass within the electricity system is low. In contrast, in the case of excess biomass, flexibility is supplied by biomethane-fired combined cycle turbines or by biomass-fired power plants.
8.	Lehtveer, Mariliis, 1983, et al. (författare) Actuating the European Energy System Transition: Indicators for Translating Energy Systems Modelling Results into Policy-Making 2021 Ingår i: Frontiers in Energy Research. - : Frontiers Media SA. - 2296-598X. ; 9 Tidskriftsartikel (refereegranskat)abstract In this paper, we define indicators, with a focus on the electricity sector, that translate the results of energy systems modelling to quantitative entities that can facilitate assessments of the transitions required to meet stringent climate targets. Such indicators, which are often overlooked in model scenario presentations, can be applied to make the modelling results more accessible and are useful for managing the transition on the policy level, as well as for internal evaluations of modelling results. We propose a set of 13 indicators related to: 1) the resource and material usages in modelled energy system designs; 2) the rates of transition from current to future energy systems; and 3) the energy security in energy system modelling results. To illustrate its value, the proposed set of indicators is applied to energy system scenarios derived from an electricity system investment model for Northern Europe. We show that the proposed indicators are useful for facilitating discussions, raising new questions, and relating the modelling results to Sustainable Development Goals and thus facilitate better policy processes. The indicators presented here should not be seen as a complete set, but rather as examples. Therefore, this paper represents a starting point and a call to other modellers to expand and refine the list of indicators.
9.	Lehtveer, Mariliis, 1983, et al. (författare) BECCS and DACCS as Negative Emission Providers in an Intermittent Electricity System: Why Levelized Cost of Carbon May Be a Misleading Measure for Policy Decisions 2021 Ingår i: Frontiers in Climate. - : Frontiers Media SA. - 2624-9553. ; 3 Tidskriftsartikel (refereegranskat)abstract Carbon dioxide removal (CDR) from the atmosphere is likely to be needed to limit global warming to 1.5 or 2°C and thereby for meeting the Paris Agreement. There is a debate which methods are most suitable and cost-effective for this goal and thus deeper understanding of system effects related to CDR are needed for effective governance of these technologies. Bio-Energy with Carbon Capture and Storage (BECCS) and Direct Air Carbon Capture and Storage (DACCS) are two CDR methods, that have a direct relation to the electricity system—BECCS via producing it and DACCS via consuming. In this work, we investigate how BECCS and DACCS interact with an intermittent electricity system to achieve net negative emissions in the sector using an energy system model and two regions with different wind and solar resource conditions. The analysis shows that DACCS has a higher levelized cost of carbon (LCOC) than BECCS, implying that it is less costly to capture CO2 using BECCS under the assumptions made in this study. However, due to a high levelized cost of electricity (LCOE) produced by BECCS, the total system cost is lower using DACCS as negative emission provider as it is more flexible and enables cheaper electricity production from wind and solar PV. We also find that the replacement effect outweighs the flexibility effect. Since variations in solar-based systems are more regular and shorter (daily cycles), one could assume that DACCS is better suited for such systems, whereas our results point in the opposite direction showing that DACCS is more competitive in the wind-based systems. The result is sensitive to the price of biomass and to the amount of negative emissions required from the electricity sector. Our results show that the use of the LCOC as often presented in the literature as a main indicator for choosing between different CDR options might be misleading and that broader system effects need to be considered for well-grounded decisions.
10.	Lehtveer, Mariliis, 1983, et al. (författare) Estonian energy supply strategy assessment for 2035 and its vulnerability to climate driven shocks 2016 Ingår i: Environmental Progress and Sustainable Energy. - : Wiley. - 1944-7442 .- 1944-7450. ; 35:2, s. 469-478 Tidskriftsartikel (refereegranskat)abstract Estonia is a relatively small country with a limited supply of indigenous energy resources mainly consisting of oil shale, wood, and peat. Estonia is also the only country in Europe with a dominant electricity production by burning oil shale. Around 90% of the overall electric energy production in Estonia comes from the Narva Power Plants. This presents great challenges and problems due to massive emissions of greenhouse gases into the atmosphere as well as radiological impact on the environment. Therefore, the current energy supply strategy can be considered hazardous and an unpopular choice for future energy system planning. In this article, we analyze the current energy policy as well as inclusion of new strategies to produce electricity for Estonia for a target year of 2035. We use a computer model Model for Supply Strategy Alternatives and their General Environmental Impacts (MESSAGE) to provide optimization and aim in helping the policymakers in the Estonian decision making process. We also add a specific case in the MESSAGE model to examine the ability of the current electricity supply strategy to handle climate related shocks with a special focus on cold weather in two plausible cases; single cold winter and prolonged cold winter. Results indicate that unexpected demand shocks may cause serious losses in gross domestic product (GDP). Therefore, the authors come to the conclusion that extra capacity is highly recommendable for a number of reasons. We also find that nuclear power becomes economically preferable to oil shale with a CO2 tax of Euro20/t. Yet moving toward nuclear or other low CO2 alternatives presents certain challenges. (c) 2015 American Institute of Chemical Engineers Environ Prog, 35: 469-478, 2016
11.	Lehtveer, Mariliis, 1983, et al. (författare) How much can nuclear power reduce climate mitigation cost? – Critical parameters and sensitivity 2015 Ingår i: Energy Strategy Reviews. - : Elsevier BV. - 2211-467X. ; 6, s. 12-19 Tidskriftsartikel (refereegranskat)abstract Although large scale nuclear power deployment can reduce greenhouse gas emissions, potential for nuclear power to reduce climate mitigation cost is not well understood. We use an energy system model to estimate the relative savings in mitigation costs enabled by nuclear power as well as their robustness via scenario and Monte Carlo analysis. Nuclear power reduces mitigation costs in all explored scenarios, but the extent varies considerably. Nuclear power reduces costs significantly if carbon storage capacity is low but is replaceable if the capacity is abundant and technology available. The same holds for the cost of renewables. However, providing a full cost benefit analysis of nuclear power is beyond the scope of this paper.
12.	Lehtveer, Mariliis, 1983, et al. (författare) Managing variable renewables with biomass in the European electricity system: Emission targets and investment preferences 2020 Ingår i: Energy. - : Elsevier BV. - 0360-5442 .- 1873-6785. ; 213 Tidskriftsartikel (refereegranskat)abstract Biomass can help reaching climate goals in many sectors. In electricity generation it can complement variable renewables or, if coupled with carbon capture and storage (CCS), also provide negative emissions. This paper adds to the existing literature by focusing on the cost-efficiency of balancing variable renewables with biomass and by providing an indication on acceptance of these technologies. A dynamic optimization model is used to analyse the role of biomass in the European electricity system pending different emission targets for 2050. The results are compared with survey data on investment preferences for biomass technologies, and wind and solar power. The formulation of the emission target greatly influences the cost-efficient use of biomass, with more concentrated use observed, if bioenergy with CCS is allowed. This indicates that a Europe-wide emission target could be more cost-efficient than separate national targets. Both governmental and nongovernmental actors tend to be negative towards investing in biomass technologies, although with greater variation if combined with CCS, indicating possible challenges for implementation. Their attitudes towards wind and solar power are much more positive in all countries, supporting the continuation of the existing trend of an increasing share of variable renewables in the European electricity system.
13.	Lehtveer, Mariliis, 1983 (författare) Modelling the Role of Nuclear Power and Variable Renewables in Climate Change Mitigation 2016 Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract As the number of people on Earth and our energy needs have increased the system for providing this energy has become ever more complex and complicated and thus the need for more systematic understanding of it has grown. However, change in energy system is slow and many of the challenges that we face such as mitigating climate change need global solutions. Energy system models with long time span and global reach provide a way to analyse questions related to these challenges. This thesis focuses on capturing the role of nuclear power and variable renewables in global long term energy models.Papers I, II and IV assess the potential role nuclear power can play in global climate mitigation as well as identify the determining factors of this contribution whereas Paper III looks at the possible effects of phase out of Swedish nuclear power on European CO2 emissions and electricity prices. We show that nuclear power can reduce the climate change mitigation cost if allowed to remain or expand. The main factors determining the cost reduction potential are availability and cost of carbon capture and storage and cost of renewable and nuclear technologies. However, to decide whether to allow for a large scale expansion of nuclear power, the observed cost savings must be weighed against increased risks of accidental radiation releases from reactor operation, waste storage and nuclear weapons proliferation. To make this decision economic as well as non-economic factors should also be considered.To analyse such concerns we use post analysis of model scenarios in Paper I to assess the nuclear power expansion’s effect on nuclear weapons’ proliferation and apply the multi-criteria model analysis (MCMA) method in Paper IV to actively include criteria such as proliferation concern and energy security into optimisation. We find that MCMA method significantly improves the analysis of attainability of multiple simultaneous goals such in large-scale energy-systems models compared to simple scenario analysis that is presented in Paper I. The approach is more intuitive and requires minimal mathematical skills on the part of the user. MCMA method also avoids infeasible or dominated solutions that are caused by the stringent constraints applied in parametric optimisation.Paper V presents a method for capturing the effects of intermittency induced by variable renewables into the power system. Our results show that this approach manages to capture many aspects such as need for flexible generation capacity and curtailment at high penetration levels. We also find optimal electricity production mixes to vary significantly between regions due to different endowments of solar and wind resources. We show that adding electricity storage to the system will favour solar power but has only a minor effect on wind and nuclear power.
14.	Lehtveer, Mariliis, 1983, et al. (författare) Multi-criteria analysis of nuclear power in the global energy system: Assessing trade-offs between simultaneously attainable economic, environmental and social goals 2015 Ingår i: Energy Strategy Reviews. - : Elsevier BV. - 2211-467X. ; 8, s. 45-55 Tidskriftsartikel (refereegranskat)abstract To investigate the complex relationships among the energy-related challenges faced by humanity, we marry a large-scale energy systems model, MESSAGE, with a multi-criteria model analysis tool. Such an approach is applicable to other modelling frameworks and can significantly improve the analysis of multiple goals. We focus our study on nuclear power - a technology viewed differently by different stakeholders. We find that nuclear power plays an important role in global climate change mitigation efforts where energy security and affordability goals take precedence, but that the total amount of nuclear in the system is highly dependent on stakeholders' preferences. We also find synergies among climate mitigation and energy security goals, and also between these two goals and the reduced need for underground carbon storage.
15.	Lehtveer, Mariliis, 1983 (författare) Nuclear Power as a Climate Change Mitigation Option: a Modelling Approach 2014 Licentiatavhandling (övrigt vetenskapligt/konstnärligt)abstract Although nuclear power can provide electricity with very low life cycle carbon emissions and thus reduce the cost of climate change mitigation, it also brings along many specific challenges: accident risk, need for radioactive waste management and nuclear weapons proliferation risk. Due to this controversial nature nuclear power, among other energy forms, has been relatively little studied in a climate mitigation context. This thesis aims to provide some insight into the possible role of nuclear power in climate change mitigation.In the first paper we assess the impact of potential nuclear expansion and advanced nuclear cycles on climate change mitigation cost and reflect on this expansion’s relation to nuclear weapons proliferation risk. We find that nuclear power can reduce the mitigation cost around 20%, and new reactor types and advanced uranium extraction methods provide a significant part of the savings (10%). To materialize those savings however the number of reactors would need to increase tenfold by 2070, which implies an increase in enrichment and/or reprocessing facilities, technologies that are directly related to proliferation risk. We show that even if reprocessing can be made proliferation safe as some scientists believe, the switch to a closed fuel cycle that does not need enrichment will take more than the remainder of this century under a cost minimising condition, and therefore proliferation risk cannot be eliminated.In the second paper we investigate further the mitigation cost reducing ability of nuclear power by subjecting our model to numerous parameter variations and a Monte Carlo analysis. We observe that nuclear power can provide significant cost savings in almost all cases and that the expansion of nuclear power is dependent on climate policy. In addition we discovered that the capacity for carbon capture and storage plays a significant role in cases of a nuclear phase out and high climate sensitivity but is inconsequential if nuclear expansion is allowed.
16.	Lehtveer, Mariliis, 1983, et al. (författare) Nuclear power as a climate mitigation strategy - technology and proliferation risk 2015 Ingår i: Journal of Risk Research. - : Informa UK Limited. - 1466-4461 .- 1366-9877. ; 18:3, s. 273-290 Tidskriftsartikel (refereegranskat)abstract Recent years have witnessed renewed interest in nuclear power in large extent due to the need to reduce carbon emissions to mitigate climate change. Most studies of cost and feasibility of stringent climate targets that include nuclear power focus on the currently available light water reactor (LWR) technology. Since climate mitigation requires a long-term commitment, the inclusion of other nuclear technologies such as mixed oxide-fuelled LWRs and fast breeder reactors may better describe the future energy supply options. These different options also entail different nuclear weapon proliferation risks stemming from uranium enrichment or reprocessing of spent fuel. To investigate this relation, we perform a scenario analysis using the global energy transition model. Our results indicate that meeting a scenario with a 430 ppm CO2 target for 2100 is feasible without the involvement of nuclear power; however the mitigation costs increase by around 20%. Furthermore, a lasting contribution by nuclear power to climate change mitigation can only be achieved by alternative fissile material production methods and global diffusion of nuclear technologies. This in turn bears important implications for the risk of nuclear proliferation for several reasons. First, knowledge and competence in nuclear technology becomes more accessible, leading to the risk of nuclear programmes emerging in states with weaker institutional capacity. Additionally, even if the reprocessing step in a fast breeder cycle proves to be essentially proliferation resistant, the build-up of breeder reactor systems necessitates a long transition period with large-scale use of enrichment technology and its related proliferation risks. Our study does not include the costs posed on society by nuclear accident risk and by the need to upscale safeguards and regulatory capacity to deal with increased proliferation risk
17.	Lehtveer, Mariliis, 1983, et al. (författare) Using Resource Based Slicing to Capture the Intermittency of Variable Renewables 2016 Tidskriftsartikel (övrigt vetenskapligt/konstnärligt)abstract As the share of variable renewables – wind and solar PV – is expected to grow significantly in coming decades, it has become increasingly important to account for their intermittency in large scale energy models that are used to explore long term energy futures. In this paper we propose and evaluate one method for doing so, namely, resource based slicing. In addition we implement storage based on possible transitions between slices which allows us to explore new dynamics between intermittent generation and electricity storage in large scale models. Our preliminary results show that this approach manages to capture many aspects introduced by variable renewables such as need for flexible generation capacity and curtailment at high penetration levels. We show that adding electricity storage to the system will favour solar power but has only a minor effect on wind and nuclear power.
18.	Lehtveer, Mariliis, 1983, et al. (författare) Using resource based slicing to capture the intermittency of variable renewables in energy system models 2017 Ingår i: Energy Strategy Reviews. - : Elsevier BV. - 2211-467X. ; 18, s. 73-84 Tidskriftsartikel (refereegranskat)abstract As the share of wind and solar power is expected to grow significantly in coming decades, it has become increasingly important to account for their intermittency in large-scale energy system models and global integrated assessment models that are used to explore long term developments. However, the scope of these models often prohibits the use of a high intra-annual time resolution that can adequately capture the main characteristics of variable renewables. A more efficient representation is required. In this paper we evaluate resource-based slicing, i.e. selecting time slices based on wind and solar generation rather than e.g. season and time-of-day. We show that resource slicing can capture many aspects introduced by variable renewables such as the need for flexible generation capacity, curtailment at high penetration levels and interactions with baseload and storage technologies, while using only sixteen intra-annual time slices.
19.	Lehtveer, Mariliis, 1983, et al. (författare) Vi kan klara klimatmål utan kärnkraft 2014 Ingår i: Svenska Dagbladet. Tidskriftsartikel (övrigt vetenskapligt/konstnärligt)
20.	Lehtveer, Mariliis, 1983, et al. (författare) WHAT FUTURE FOR ELECTROFUELS? 2018 Konferensbidrag (övrigt vetenskapligt/konstnärligt)abstract Transport sector is seen as the most difficult sector to decarbonise. In recent years so called electrofuels have been proposed as one option for emissions reduction. Electrofuels – fuels made from electricity and carbon dioxide - can potentially help to manage variations in electricity production and reducethe need for biofuels as well as make use of current infrastructure and can be used in sectors where fuel switch is difficult such as aviation. We investigate the cost-effectiveness of electrofuels under climate mitigation constraint and find that electrofuels are unlikely to become cost-effective unless options for storing carbon are very limited.
21.	Lehtveer, Mariliis, 1983, et al. (författare) What Future for Electrofuels in Transport? Analysis of Cost Competitiveness in Global Climate Mitigation 2019 Ingår i: Environmental Science & Technology. - : American Chemical Society (ACS). - 0013-936X .- 1520-5851. ; 53:3, s. 1690-1697 Tidskriftsartikel (refereegranskat)abstract The transport sector is often seen as the most difficult sector to decarbonize. In recent years, so-called electrofuels have been proposed as one option for reducing emissions. Electrofuels-here defined as fuels made from electricity, water, and carbon dioxide-can potentially help manage variations in electricity production, reduce the need for biofuels in the transportation sector while utilizing current infrastructure, and be of use in sectors where fuel switching is difficult, such as shipping. We investigate the cost-effectiveness of electrofuels from an energy system perspective under a climate mitigation constraint (either 450 or 550 ppm of CO2 in 2100), and we find the following: (i) Electrofuels are unlikely to become cost-effective unless options for storing carbon are very limited; in the most favorable case modeled-an energy system without carbon storage and with the more stringent constraint on carbon dioxide emissions-they provide approximately 30 EJ globally in 2070 or approximately 15% of the energy demand from transport. (ii) The cost of the electrolyzer and increased availability of variable renewables appear not to be key factors in whether electrofuels enter the transport system, in contrast to findings in previous studies.
22.	Rosén, Sofia, 1994, et al. (författare) Modeling of a “Hydrogen Valley” to investigate the impact of a regional pipeline for hydrogen supply 2024 Ingår i: Frontiers in Energy Research. - 2296-598X. ; 12 Tidskriftsartikel (refereegranskat)abstract Introduction : The transition towards electrolysis-produced hydrogen in refineries and chemical industries is expected to have a potent impact on the local energy system of which these industries are part. In this study, three urban areas with hydrogen-intense industries are studied regarding how the energy system configuration is affected if the expected future hydrogen demand is met in each node individually, as compared to forming a “Hydrogen Valley,” in which a pipeline can be used to trade hydrogen between the nodes. Method : A technoeconomic, mixed-integer, linear optimization model is used to study the investments in and dispatch of the included technologies with an hourly time resolution, while minimizing the total system cost. Four cases are investigated based on the availability of offshore wind power and the possibility to invest in a pipeline. Results : The results show that investments in a pipeline reduces by 4%–7% the total system cost of meeting the demands for electricity, heating, and hydrogen in the cases investigated. Furthermore, investments in a pipeline result in greater utilization of local variable renewable electricity resources, as compared to the cases without the possibility to invest in a pipeline. Discussion : The different characteristics of the local energy systems of the three nodes in local availability of variable renewable electricity, grid capacity and available storage options compared to local demands of electricity, heating and hydrogen, are found to be the driving forces for forming a Hydrogen Valley.

Skapa referenser, mejla, bekava och länka

Länka till träfflistan

Träfflista för sökning "WFRF:(Lehtveer Mariliis 1983) "

Avgränsa träffmängd

År