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Investigation of Fire Safety Characteristics of Alternative Aviation FuelsVikrant E Goyal (8081456) 05 December 2019 (has links)
<div>Due to the depletion of fossil fuel reserves and emission challenges associated with its usage, there is a need for alternative aviation fuels for future propulsion. The alternative fuels with handling, storage and combustion characteristics similar to conventional fuels can be used as “drop-in” fuels without significant changes to the existing aviation infrastructure. Fire safety characteristics of alternative aviation fuels have not been studied intensively and therefore research is needed to understand these characteristics. In this study, fire safety characteristics namely hot surface ignition (HSI) and flame spread phenomena are investigated for alternative aviation fuels. </div><div><br></div><div>HSI is defined as the process of a flammable liquid coming in contact with a hot surface and evaporating, mixing and reacting with the surrounding oxidizer with self-supporting heat release (combustion). If all the conditions are adequate, the fuel may completely turn into combustion products following the ignition process. This work presents results from more than 5000 ignition tests using a newly developed reproducible test apparatus. A uniform surface temperature stainless steel plate simulating the wall of a typical exhaust manifold of an aircraft engine is used as the hot surface. Ignition tests confirmed that the ignition event is transient and initiates at randomly distributed locations on the hot surface. The results show many significant differences and some similarities in the ignition characteristics and temperatures of the different fuels. In this work, hot surface ignition temperatures (HSITs) are measured for nine hydrocarbon liquids. Five of these fuels are piston engine based, three fuels are turbine-engine based and one fuel is a pure liquid, heptane. The piston engine based fuels are given by FAA and are confidential and hence labeled as test fuels A, B, C, D for this study. The HSITs of these fuels are measured and compared against a baseline fuel 100 LL aviation gasoline (100LL Avgas). HSITs of conventional turbine engine based fuels namely Jet-A, JP-8, and JP-5 are also measured. </div><div><br></div><div>Flame spread along liquid fuel has been one of the important combustion phenomena that still requires more in-depth research and analysis for the deep understanding of the chemical processes involved. Flame spread rate determines how fast the flame spreads along the fuel surface and it is an important parameter to study for fire safety purposes. For the flame spread rates study, a novel experimental apparatus is designed and fabricated. The experimental apparatus consists of a rectangular pan, a fuel heating system, an autonomous lid actuation system, a CO2 fire extinguisher system, and a laser ignition system. The flame spread phenomenon is studied for a conventional aviation fuel namely, Jet-A and three alternative aviation fuels namely, hydro-processed ester fatty acids (HEFA-50), Fischer-Tropsch – IPK (FT-IPK) and synthetic iso-paraffin (SIP). The experiments are conducted for a wide range of initial fuel temperatures ranging from 25°-100°C for Jet-A, HEFA-50, FT-IPK and from 80-140°C for SIP as the flash-point of SIP is 110°C and is ~3 times higher than that of other three fuels. The flame spread rate of all fuels increases exponentially with increasing fuel’s initial temperature. Flame spread rate is as low as ~5 cm/sec for Jet-A, HEFA-50, FT-IPK for 25°C initial fuel temperature and goes to as high as 160 cm/sec for 80°C initial fuel temperature. For SIP based jet fuel, flame spread rate is ~160 cm/sec for initial fuel temperature of 140°C. Additionally, it was also found that the flame propagation consists of two types of flames: a precursor blue flame located ahead of the main yellow flame. These flames are more evident over the fuels’ surface with initial fuel temperatures higher than their respective flash-points. The precursor blue flame propagates like a premixed flame and the main yellow flame propagates like diffusion combustion.</div><div><br></div><div>This dissertation includes eight chapters. Chapter 1 gives an overview
of the work done until now in the field of hot surface ignition. Following this
review, the experimental apparatus designed and fabricated for this study are
discussed in Chapter 2. This chapter also talks about the test matrix, data
acquisition tools and concludes with the data analysis method. In Chapter-3,
HSITs of 3 turbine engine based fuels and 5 piston engine based fuels are
reported. This chapter also discusses the effect of drop height and curvature
(flat v/s cylindrical) for two fuels, Jet-A, and heptane. This concludes the
work done in the field of HSI in this dissertation. Chapter 4 talks about the
past work reported by various researchers in the field of flame spread
phenomenon and key learnings from their work. Chapter 5 discusses the
experimental apparatus designed and fabricated for flame spread phenomenon
study. In chapter-6, flame spread rates of 4 alternative aviation fuels are
reported. This chapter also discusses the flame spread mechanism associated
with slower (liquid-phase controlled) and faster (gas-phase controlled) flame
propagation. Chapter 7 discusses flame propagation which consists two types of
flames: a precursor blue flame and a main yellow flame. Chapter 8 concludes the
key findings of the hot surface ignition and flame spread phenomenon study in this
research work </div><div><br></div>
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Applying the Principle of Corresponding States to Multi-component Hydrocarbon Mixtures (Jet Fuels)Evanhoe, Matthew January 2015 (has links)
No description available.
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Assessing the Integration of Sustainable Aviation Fuels (SAFs) : Balancing Environmental Impact, Economic Viability, and Aircraft Performance in the Aviation IndustryAlvarez Sarró, Jesús January 2024 (has links)
This thesis examines the role of Sustainable Aviation Fuels (SAFs) in advancing the sustainability goals of the aviation industry, focusing on their environmental impacts, economic feasibility, and compatibility with existing aircraft performance. The research primarily involves a comprehensive literature review and analysis of existing studies to evaluate the potential of SAFs to reduce carbon emissions significantly—up to 80% relative to conventional jet fuels depending on the feedstock and processing methods used. The economic analysis reveals that while SAFs are currently more costly than traditional fuels, regulatory incentives and technological advancements could decrease these costs, making SAFs more competitive. Performance-wise, SAFs are shown to be viable "drop-in" options, requiring minimal modifications to aircraft or fuel infrastructure, thus facilitating easier adoption across the industry. The study concludes that despite the challenges, SAFs are indispensable for the aviation sector’s transition towards net-zero emissions. It emphasizes the need for enhanced collaboration among governments, industry stakeholders, and researchers to scale production and integrate SAFs into the global fuel mix effectively.
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Developing Mass Spectrometric Methods for Distinguishing Isomers, Characterizing Complex Mixtures and Determining the Capability of Organic Compounds to Swell Aircraft O-ring SealsMark Romanczyk (6263273) 10 May 2019 (has links)
<p>The
research described in this dissertation focuses on several areas: developing
analytical methods to distinguish structural isomers, identifying the chemical
compositions of aviation fuels and evaluating the effectiveness of organic
dopants to swell aircraft o-ring seals. Chapter 2 discusses fundamental aspects
of mass spectrometry, and ionization methods and the instrumentation used to
complete this research. </p>
<p>Chapter
3 discusses and compares two activation methods used to distinguish ionized
structural isomers. Ionized naphthene-containing aromatic
structural isomers were subjected to collision-activated dissociation (CAD) in
an ion trap (ITCAD) and to medium-energy collision-activated dissociation
(MCAD) in an octupole collision cell, both in the energy-resolved mass
spectrometry mode (ERMS). MCAD was shown to be superior over ITCAD at the
structural differentiation of the ionized isomers. </p>
<p>Determination
of the chemical compositions of petroleum-based jet and diesel fuels, potential
alternative fuels and fuel blending components by using a GCxGC/(EI)TOF MS is discussed in
chapter 4. The ability to determine the chemical compositions
of fuels and to correlate the identified compounds and their concentrations to the
physical and chemical properties and aircraft performance of the fuels is vital
for the development of future resilient, alternative fuels. The chemical compositions of petroleum-based
fuels were found to be different from potential alternative fuels.</p>
<p>Chapter
5 discusses the effectiveness of aromatic and nonaromatic compounds in swelling
air craft o-ring seals, which prevents leaks in the fuel circulation systems. The aim of this study was to identify aromatic
and nonaromatic compounds that most effectively swell o-ring seals. Steric effects were shown to decrease the efficiency of the
compounds to swell seals. Ethylbenzene and indane were found to swell o-ring
seals more effectively than any other compounds studied, including a currently
approved alternative fuel. </p>
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NON-REACTING SPRAY CHARACTERISTICS OF ALTERNATIVE AVIATION FUELS AT GAS TURBINE ENGINE CONDITIONSDongyun Shin (10297850) 06 April 2021 (has links)
<div>The aviation industry is continuously growing amid tight restrictions on global emission</div><div>reductions. Alternative aviation fuels have gained attention and developed to replace the</div><div>conventional petroleum-derived aviation fuels. The replacement of conventional fuels with</div><div>alternative fuels, which are composed solely of hydrocarbons (non-petroleum), can mitigate</div><div>impacts on the environment and diversify the energy supply, potentially reducing fuel costs.</div><div>To ensure the performance of alternative fuels, extensive laboratory and full-scale engine</div><div>testings are required, thereby a lengthy and expensive process. The National Jet Fuel Combustion</div><div>Program (NJFCP) proposed a plan to reduce this certification process time and</div><div>the cost dramatically by implementing a computational model in the process, which can be</div><div>replaced with some of the testings. This requires an understanding of the influence of chemical/</div><div>physical properties of alternative fuels on combustion performance. The main objective</div><div>of this work is to investigate the spray characteristics of alternative aviation fuels compared</div><div>to that of conventional aviation fuels, which have been characterized by different physical</div><div>liquid properties at different gas turbine-relevant conditions.</div><div>The experimental work focuses on the spray characteristics of standard and alternative</div><div>aviation fuels at three operating conditions such as near lean blowout (LBO), cold engine</div><div>start, and high ambient pressure conditions. The spray generated by a hybrid pressureswirl</div><div>airblast atomizer was investigated by measuring the drop size and drop velocity at</div><div>a different axial distance downstream of the injector using a phase Doppler anemometry</div><div>(PDA) measurement system. This provided an approximate trajectory of the largest droplet</div><div>as it traveled down from the injector. At LBO conditions, the trend of decreasing drop size</div><div>and increasing drop velocity with an increase in gas pressure drop was observed for both</div><div>conventional (A-2) and alternative aviation fuels (C-1, C-5, C-7, and C-8), while the effect of</div><div>fuel injection pressure on the mean drop size and drop velocity was observed to be limited.</div><div>Moreover, the high-speed shadowgraph images were also taken to investigate the effect of</div><div>the pressure drop and fuel injection pressures on the cone angles. Their effects were found</div><div>to be limited on the cone angle.</div><div><div>The spray characteristics of standard (A-2 and A-3) and alternative (C-3) fuels were</div><div>investigated at engine cold-start conditions. At such a crucial condition, sufficient atomization</div><div>needs to be maintained to operate the engine properly. The effect of fuel properties,</div><div>especially the viscosity, was investigated on spray drop size and drop velocity using both</div><div>conventional and alternative aviation fuels. The effect of fuel viscosity was found to be minimal</div><div>and dominated by the effect of the surface tension, even though it showed a weak trend</div><div>of increasing drop size with increasing surface tension. The higher swirler pressure drop</div><div>reduced the drop size and increased drop velocity due to greater inertial force of the gas for</div><div>both conventional and alternative aviation fuels at the cold start condition. However, the</div><div>effect of pressure drop was observed to be reduced at cold start condition compared to the</div><div>results from the LBO condition.</div><div>The final aspect of experimental work focuses on the effect of ambient pressures on the</div><div>spray characteristics for both conventional (A-2) and alternative (C-5) aviation fuels. Advanced</div><div>aviation technology, especially in turbomachinery, has resulted in a greater pressure</div><div>ratio in the compressor; therefore, greater pressure in combustors for better thermal efficiency.</div><div>The effect of ambient pressure on drop size, drop velocity, and spray cone angle was</div><div>investigated using the PDA system and simultaneous Planar Laser-Induced Fluorescence</div><div>(PLIF) and Mie scattering measurement. A significant reduction in mean drop size was</div><div>observed with increasing ambient pressure, up to 5 bar. However, the reduction in the mean</div><div>drop size was found to be limited with a further increase in the ambient pressure. The effect</div><div>of the pressure drop across the swirler was observed to be significant at ambient pressure of</div><div>5 bar. The spray cone angle estimation at near the swirler exit and at 25.4 mm downstream</div><div>from the swirler exit plane using instantaneous Mie images was found to be independent of</div><div>ambient pressure. However, the cone angle at measurement plane of 18 mm in the spray</div><div>was observed to increase with increasing ambient pressure due to entrainment of smaller</div><div>droplets at higher ambient pressure. Furthermore, the fuel droplet and vapor distribution in</div><div>the spray were imaged and identified by comparing instantaneous PLIF and Mie images.</div><div>Lastly, a semi-empirical model was also developed using a phenomenological three-step</div><div>approach for the atomization process of the hybrid pressure-swirl airblast atomizer. This</div><div>model includes three sub-models: pressure-swirl spray droplet formation, droplet impingement, and film formation, and aerodynamic breakup. The model predicted drop sizes as a</div><div>function of ALR, atomizing gas velocity, surface tension, density, and ligament length and</div><div>diameter and successfully demonstrated the drop size trend observed with fuel viscosity,</div><div>surface tension, pressure drop, and ambient pressure. The model provided insights into the</div><div>effect of fuel properties and engine operating parameters on the drop size. More experimental</div><div>work is required to validate the model over a wider range of operating conditions and</div><div>physical fuel properties.</div><div>Overall, this work provides valuable information to increase understanding of the spray</div><div>characteristics of conventional and alternative aviation fuels at various engine operating</div><div>conditions. This work can provide valuable data for developing an advanced computational</div><div>combustor model, ultimately expediting the certification of new alternative aviation fuels.</div></div>
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Aircraft Emissions Modelling for SAF Based on Flight Trajectory / Modellering av flygplansutsläpp för SAF baserad på flygbanaGarcia Domene, Maria January 2024 (has links)
Sustainable aviation fuels are one of the proposals that the aviation industry is adopting to reduce its impact on the environment. These are obtained by applying chemical processes to biological and non-biological resources, and their main objective is to replace conventional (fossil-derived) aviation fuel in their entirety. There are currently seven approved production pathways and two co-processing processes. Understanding the real impact of these fuels on the amount of emissions produced by an aircraft along a trajectory is essential to further develop sustainable proposals and regulations. So to understand how the use of these fuels affects total emissions, the model developed by Boeing to estimate aircraft emissions has been adapted to sustainable aviation fuels using the Lower Heating Value as a proposal throughout this project. The methodology has been applied to a real flight between Stockholm Airport and Bordeaux Airport. Four different scenarios, characterized by varying fuel blends, have been studied: exclusive use of kerosene, 10% sustainable fuel blend, an equal 50% blend of each fuel, and sustainable fuel only. The analysis has been performed for five different types of non-conventional fuels; Shell FT-SPK, Sasol FT-SPK, UOP HEFA-SPK, Coconut HEFA-SPK and Hevo ATJ-SPK. At large, two trends have been detected in the effect of these fuels on total emissions; some types of SAF have increased CO and HC emissions and reduced NOx emissions compared to kerosene, and others whose behavior has been the reverse. In addition, the percentage of fuel used has an impact on total emissions. It can be concluded that no non-conventional fuel type among those studied has been found to produce a reduction in all types of emissions, however, given that their life cycle is circular, they do contribute to making the aviation sector more sustainable by reducing CO2. The results can help to better understand the impact of this type of fuel, as well as provide valuable information for decision-making in the implementation of sustainable strategies in the aviation industry. / Hållbara flygbränslen är en av de förslag som flygindustrin antagit för att minska sin påverkan på miljön. Dessa bränslen framställs genom att tillämpa kemiska processer på biologiska och icke-biologiska resurser, och deras främsta mål är att helt ersätta konventionellt (fossilbaserat) flygbränsle. För närvarande finns det sju godkända produktionsvägar och två sambehandlingsprocesser. För att förstå den verkliga påverkan av dessa bränslen på mängden utsläpp som produceras av ett flygplan längs en bana är det nödvändigt att vidareutveckla hållbara förslag och regler. För att förstå hur användningen av dessa bränslen påverkar totala utsläpp har modellen utvecklats av Boeing för att uppskatta flygutsläpp anpassats till hållbara flygbränslen genom att använda lägre värmevärde som förslag i hela detta projekt. Metoden har tillämpats på en verklig flygning mellan Stockholms flygplats och Bordeaux flygplats. Fyra olika scenarier, karakteriserade av varierande bränsleblandningar, har studerats: enbart användning av flygbränsle, 10% hållbar bränsleblandning, en jämn fördelning av 50% av varje bränsle, och enbart hållbart bränsle. Analysen har utförts för fem olika typer av icke-konventionella bränslen; Shell FT-SPK, Sasol FT-SPK, UOP HEFA-SPK, Coconut HEFA-SPK och Hevo ATJ-SPK. Generellt sett har två trender observerats beträffande dessa bränsles effekter på totala utsläpp; vissa typer av hållbara bränslen har ökat CO- och HC-utsläppen och minskat NOx-utsläppen jämfört med flygbränsle, medan andra har haft motsatt beteende. Dessutom har procentandelen bränsle som används en påverkan på totala utsläpp. Det kan dras slutsatsen att ingen av de studerade icke-konventionella bränsletyperna har visat sig minska alla typer av utsläpp. Men med tanke på att deras livscykel är cirkulär bidrar de till att göra flygsektorn mer hållbar genom att minska CO2. Resultaten kan hjälpa till att bättre förstå denna typ av bränsles påverkan och tillhandahålla värdefull information för beslutsfattande vid införandet av hållbara strategier inom flygindustrin.
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Quenching Distance of Premixed Jet-A/Air MixturesShatakshi Gupta (11023203) 16 May 2024 (has links)
<p>Quenching distance is a fundamental property of hydrocarbon fuel-air mixtures and is a crucial parameter guiding process and equipment design for fire hazard mitigation. Many industrial equipment such as flame arrestors and burners rely on the fundamental principle of flame quenching, i.e., a premixed flame cannot pass through confined spaces below a critical width, given by the Quenching Distance (QD) of the fuel-air mixture. Through the efforts spanning over more than a century, QD is found to depend on various parameters such as temperature, pressure, fuel-air equivalence ratio, and the characteristics of hydrocarbons comprising the fuel. Many investigations on flame quenching behavior have focused on simple fuels such as Hydrogen, Methane, and hydrocarbons upto n-Decane. However, there is a lack of quenching distance data on aviation fuels like Jet-A likely due to the fact that QD property of these fuels is less relevant in practical combustor applications. But in this era of miniaturization, there are several upcoming technologies that will utilize jet fuels or kerosene in confined spaces. For example, a recently proposed Printed Circuit Heat Exchanger (PCHE) is being considered for jet engine performance enhancement by cooling down the compressor discharge air using fuel prior to injection. The cooled air can be used to improve turbine cooling allowing for improvement of the thermal efficiency of the jet engine. However, a major cause of concern during the PCHE operation is the accidental internal fuel leakage from high pressure fuel microchannels into the surrounding air microchannels. Under the severe operating conditions of a jet engine (T >800K, P >10bar), the leaking fuel upon mixing with air pose ignition and sustained combustion risks. This must be evaluated against the competing phenomenon of flame arrestment, since the channel sizes in PCHEs are very small (in the order of a few hundred micrometers). Thus, it becomes imperative to measure the quenching distance of jet fuels to design the microscale passages, predict and mitigate fire hazards to ensure safe operation.</p><p> </p><p>In the present work, the quenching distance of homogeneous, quiescent Jet-A/air mixtures at 473K, 1atm under various equivalence ratios (lean to rich) have been studied. For this purpose, experiments were setup using the ASTM Standard Method that involves using flanged electrodes to measure the parallel-plate QD of quiescent, pre-vaporized fuel-air mixtures under various conditions. Validation tests were carried out with Methanol/air mixtures at 373K, 1atm for different equivalence ratios. For tests with Jet-A/air mixtures, the QD variation with equivalence ratio follows similar trends as that of n-Decane/air. On further analyzing the QD variation with equivalence ratio, we see that the QD minimizes on fuel rich conditions with increasing molecular weight of the fuel which is consistent with the trend shown in literature. The flame propagation behavior shows considerable differences on the lean and the rich sides.</p><p> </p><p>Moreover, the quenching distance of quiescent Methanol/air and Jet-A/air mixtures have been estimated using three different models taken from literature. Model parameters were calculated using Chemkin Pro simulations of the premixed flames at the similar initial conditions as the experiments. On comparing the experiment data with model predictions, we observe that the models agree well with experiment data for Methanol/air mixtures, whereas they fail to capture the QD variation with equivalence ratio for Jet-A/air mixtures. The disagreement may arise because of the high molecular weight of Jet-A that causes the Lewis number to be non-unity unlike Methanol/air mixtures. Therefore, an empirical power law relation has been developed for estimating the QD of hydrocarbon/air mixtures to the incorporate the Lewis number effect. The model agrees well with Jet-A/air QD data from experiments over the entire equivalence ratios. This will help to further our understanding of the complex fuel combustion and flame quenching for better risk mitigation.</p>
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Pathway for Sustainable Aviation : Analysis of Science-Based Targets for Aviation / Väg till en hållbar flygindustri : Analys över vetenskapsbaserade mål för flygindustrinLindfors, Sebastian January 2023 (has links)
In order for the aviation industry to meet the targets of the Paris agreement and reach net-zero by 2050, significant amounts of greenhouse-gas emissions are to be reduced. However, as the industry is essentially dependent on conventional jet fuel, it becomes necessary for alternative technologies to develop and phase out fossil-based fuels. The thesis aims to provide valuable insights into the challenges and potentials of alternative technologies, which include sustainable aviation fuel (SAF), hydrogen, and electric-powered aviation. Additionally, the thesis investigated the Science-Based Targets initiative, and challenged the interim 1.5oC aviation pathway. The findings emphasize the crucial role of stakeholder cooperation in achieving net-zero emissions by 2050. Moreover, the thesis underscores the need for significant investments in alternative technologies, in order to enable growth and make the solutions increasingly attractive compared to conventional jet fuel. Collaboration and innovation are essential for attaining environmental targets while balancing economic growth. The thesis also highlights the urgency of policies and regulations to promote additional SAF production investments in order to vastly increase the supply. Furthermore, while the Science-Based Targets initiative (SBTi) is an effective means of securing airlines' commitment to the Paris Agreement, the thesis concludes that the SBTi 1.5oC interim pathway for airlines is overly optimistic. While the SBTi 1.5oC interim pathway’s SAF estimates for 2050 could be achieved, the thesis suggests around 2 to 4 times lower SAF supply for 2030 compared to the SBTi’s estimates. This further emphasizes the airlines' difficulties in following the 1.5oC pathway and the need for the industry to accelerate its transformation and make space for alternative solutions in order to meet the environmental targets. / För att flygindustrin ska nå målen i Parisavtalet och uppnå netto-nollutsläpp år 2050 måste betydande mängder växthusgasutsläpp minskas. Eftersom branschen är i grunden beroende av konventionellt flygbränsle blir det nödvändigt att utveckla alternativa teknologier för att fasas ut fossilbaserade bränslen. Avhandlingens syfte är att ge värdefulla insikter i utmaningarna samt möjligheterna med alternativa teknologier, vilket inkluderar hållbart flygbränsle (SAF), väte och elektriskt driven flygning. Dessutom undersökte avhandlingen Science-Based Targets-initiativet och utmanade det interimistiska 1.5°C-målet för flygindustrin. Resultaten betonar den avgörande rollen som samarbetande intressenter spelar för att uppnå netto-nollutsläpp år 2050. Dessutom understryker avhandlingen behovet av betydande investeringar i alternativa teknologier för att möjliggöra tillväxt och göra lösningarna allt mer attraktiva jämfört med konventionellt flygbränsle. Samarbetet och innovationen är nödvändiga för att uppnå miljömålen samtidigt som ekonomisk tillväxt möjliggörs. Avhandlingen betonar också brådskan med att införa policys och regleringar för att främja ytterligare produktion av hållbart flygbränsle (SAF) för att drastiskt öka tillgången. Medan Science-Based Targets-initiativet (SBTi) är ett effektivt sätt att säkerställa flygbolagens åtagande att uppfylla Parisavtalet, drar avhandlingen slutsatsen att SBTi:s interimistiska 1.5°C-mål för flygindustrin är alltför optimistiskt. Medan SBTi:s SAF-estimat för 2050 skulle kunna uppnås, föreslår avhandlingen en SAF-tillgång som är ungefär 2-4 gånger lägre för 2030 jämfört med SBTi:suppskattningar. Detta understryker ytterligare svårigheterna för flygbolag att hålla sig till 1.5oC målet samt nödvändigheten för flygindustrin att accelerera omställningen och skapa utrymme för alternativa lösningar för att uppnå miljömålen.
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