Sustainable Aviation Fuel

From MIT Technology Roadmapping
Jump to navigation Jump to search

Roadmap Creators: Daiki Terakado and Sean Hwang

Time Stamp: 5 December 2023

Technology Roadmap Sections and Deliverables

Our technology roadmap identifier is shown as:

  • 2SAF - Sustainable Aviation Fuel

This indicates that we are dealing with a “level 2” roadmap at the product level, where “level 1” would indicate a market level roadmap and “level 3” or “level 4” would indicate an individual technology roadmap.

Roadmap Overview

Sustainable aviation fuel (SAF) is a strong candidate to deal with global warming in the context of aviation, using low carbon footprint resources such as biomass, waste oil, CO2, and water. SAF has a good compatibility with the present aircraft. SAF has similar characteristics to the current jet fuel and can be mixed with it, so the architecture of aircraft does not need to change. On the other hand, another strong alternative for low carbon footprint fuel is hydrogen, which needs the rearchitecting of the aircraft because of its small density and temperature, affecting the vehicle size (see following figure left). The following right figure coming from FAA shows SAF is the key toward the ambitious goal of "net zero CO2 emissions" in aviation.

Saf overview1.png

Netzero aviation.png

For producing SAF, there are several pathways depending on feedstock and the way of conversion from feedstock to SAF. However, each pathway has advantages and disadvantages such as cost, scalability, and technological readiness. This roadmap tries to identify the impactful technologies on the feasibility of SAF, and show their development plan.

Design Structure Matrix (DSM) Allocation

Saf tree.png Saf dsm1.png

The above 2SAF tree shows the relationship between other technologies related to the SAF. Specifically, the enabling technologies to SAF, by key feedstocks and processes, are considered. The enabling of SAF with the use of existing feedstocks are indicated with the connection of 2SAF to 3HEF, 3ATJ, 3FTC, 3PTL, 4BAF, 4CLS, 4CNB, and 4WCO. The enabling of SAF through various processes are shown through 2SAF connections to 4ROI, 4NTF, 4HPS, 4SEX, 4FNT, 4GAS, 4FTS, 4ELS, 4ICS, and 4MES. The connections of SAF to Level 3 and 4 technologies are shown in the DSM. In the following section, further details on the SAF production architecture is presented using Object-Process-Model (OPM).

Roadmap Model using OPM

The Object-Process-Model (OPM) of the 2SAF - Sustainable Aviation Fuel roadmap is presented in the figure with the Object-Process-Language (OPL) below. This diagram shows the processes (Pretreating, and SAF Converting) for producing SAF with the representative pathways with different types of feedstocks. We include four different representative SAF producing categories: 1) Hydroprocessed Esters and Fatty Acids (HEFA) with recycled oils, alges, bio-oils, and animal fat, 2) Alcohol-to-Jet (AtJ) with Sugar/Strach rich crops, 3) Fischer-Tropsch (FT) with coal, natural gas, and biomass, and 4) Power-to-Liquid (PtL) with water and CO2.

Overview OPL1
Overview OPL2
Overview OPL3

Saf overview opd.png

Three functional zoom-up views of the OPM are shown in the following figures.

PtL Pretreating (FT pathway)

Saf zoom ptlpre opd.png

AtJ Converting

Saf zoom atj opd.png

AtJ Converting(Methanol pathway)

Saf zoom atj mt opd.png

Figures of Merit

To begin with, we show the needs of stakeholders in the following figure. We identify three stakeholders; airlines, governments, and top management of companies.

Needs.png

With this in mind, we set FOMs for our roadmap to cover the satisfaction of the needs of stake holders. The first four (shown in bold) are identified as FoMs for our roadmap: SAF unit cost, fuel consumption, CO2-eq emission, and feedstock availability. We chose CO2-eq as an indicator of greenhouse gas emission since it includes not only CO2 but also other greenhouse gases. These are used for analyzing the trade-off of the technology choice of SAF production. The last one, the compliance to ASTM requirements is important, but is not dealt with in our current roadmap. This is because it is highly related to quality assurance and transportation, which are currently out of scope due to the early phase of R&D. Those are potential topics to add for future roadmap updates.

Saf fom.png

As mentioned in the selection of FoMs, the cost is a key to assess SAF. Here, we summarize the governing equations given in the literature[[Bergero2023]]. The right figure is an example of the SAF cost with a)Power-to-Liquid (PtL) , c)Hydroprocessed Esters and Fatty Acids (HEFA), and e)Fischer-Tropsch (FT) [Bergero2023]. As pointed with the black arrows, the SAF and current jet fuel costs place at up-right and upper-middle to bottom-left, respectively, where the utopia point is bottom-left. Thus, the direction of technology advancement of SAF with these figures goes from up-right to bottom-left, as shown in the red arrows.

Saf goveq cost.png Saf cost ex.png

Alignment with Company Strategic Drivers

Our “company” is a SAF producer specializing in high-conversion Power to Liquid (PtL) type that is looking to enable net-zero CO2 emissions in aviation fuel. Specifically, our company is targeting a 30% total market share of the SAF market, with plans on enabling airline operations with SAF by 2035. The details of the strategic driver, alignments, and targets are as presented below:

File:Saf strategic driver.png

Positioning of Company vs. Competition

The following table shows the comparison between different SAFs. Our “company” is a Power to Liquid (PtL) type SAF producer. To create the table, different sources are referred:ORear2022 for feedstocks and producers, DOE_SAF_data for feedstocks and fuel blending ratio, Detsios2023 for CO2-eq emission, AtJ price, and the technology readiness level, Bergero2023 for other prices. Our technology has a huge potential for the reduction of CO2, but the price is the most expensive and the technology readiness level is the lowest currently.

Company table.png

In the figure below, the company position in cost (price) v.s. conversion efficiency is shown. AtJ does not have data for the conversion efficiency, so it is represented with the dotted line. By reducing the feedstock costs and the conversion efficiency, the company will acquire the competitive position with higher conversion efficiency, leading high volume production. Note that there is a room of cost reduction much more than the other technologies as shown in Bergero2023.

Company fom.png

Technical Model

The figure below shows the morphological matrix for our 2SAF roadmap. Each design choice is highly connected with the pathways: HEFA, AtJ, FT, and PtL. The connections of design choices are shown in the OPM. It is noted that, in SAF conversion, there are some shared choices between different pathways. Thus, those processes can be considered as the possibility of scaling even if we choose one pathway for the first step.

File:Mor matrix.png

For the quantitative analysis, we consider three important models: cost, CO2 emission, and performance. The detailed explanation for each model is explained in the following subsections.

Unit cost model
One of the biggest challenges for SAF is cost as explained in section 1.4: Figures of Merit. We use the cost equations shown in the governing equations in chapter 1.4. Based on the equations, the sensitivity of each parameter is assessed in the following figures.

Hefa tonado.png

Ft tonado.png

PtL tonado.png

The normalized tornado charts show that the same order of sensitivity between feedstocks and conversion efficiency, though latter has more impact. We show the reference values used for the sensitivity analysis set based on the current cost (Bergero2023) in the following table.

Cost tornado ref.png

For FT, we do not have an equation for this roadmap, so we refer the represented values for 2022 shown in Destsios2023. The values are ranged in 1.6 - 2.6 USD/l, assuming 1Euro = 1.05USD.

CO2-eq emission model
It is difficult to find an equation, which assesses the impact of each design parameter on CO2 emission between variety of pathways. However, Detsios2023 summarizes the impact of each pathway on the CO2 emission (see following figure, where the doted line shows the current fossil jet fuel). We use the values for our trade-off analysis, assuming those values will not change much in the future. This approach would be plausible, thinking about the technology readiness level is 9 for HEFA, 8-9 for FT and AtJ, and 5-8 for PTL shown in Detsios2023. In the figure, FT and PtL are capable of large CO2 reduction compared with the current jet fuel.

Co2 model.png

Fuel consumption model
The impact of SAF on the performance is also important to be assessed. We choose the fuel consumption equation relative to the current fossil fuel of Jet A-1 shown in Kroyan2022. The equation is shown in the following figure. Once choosing a SAF, the fuel consumption relative to the Jet A-1 can be computed with the given properties of viscosity, density, and lower heating value. The equations are derived empirically with various types of SAF. The model shows a good agreement with the broad range of data used for its validation.

Fuel eq.png

The tornado chart is shown as follows. The density is much smaller impact compared with the viscosity and the lower heating value.

Fuel tornado.png

As the reference, we choose HEFA in the source B(54) referred in Kroyan2023. The reference values are shown in the following table.

Fuel tornado ref.png

To show the sample computational results, the fuel consumption v.s. the blending ratio for the approved SAFs of HEFA, AtJ, FT, and SIP (out of scope in this roadmap) are shown in the following figure, excerpting from Kroyan2022. It should be noted that there is non-negligible impact up to 3.5% on the fuel consumption with 100% blending ratio assumed. Also, Kroyan2022 reported that there is no clear trends between fuel properties and jet engine performance, so we assume the performance change occurs with thrust fixed.

Fuel astm.png

Feedstock availability model

Technical model integration

Tech overview.png
(((sentence will be updated))) The sample trade-off analysis is also shown in the following figures. It is assumed that the drastic change for conversion efficiency is difficult since the conversion process has become matured. Also, for HEFA and AtJ, the the cost reduction capability of feedstocks such as bio-fuel, animal fat, and cellulose are small, while the feedstocks of CO2 and H2 have a room for the cost reduction. With this figures, PtL is only capable of reducing the cost drastically, though significant effort is needed. We should also note that the cost of PtL is still higher than those of HEFA and FT even the 50% cost reduction of hydrogen and carbon cost, and 10% conversion efficiency improvement is assumed.

Financial Model

The overview of the financial model is shown in the follwowing figure.

File:Fin overview.png

For financial assessment, we use the net present value (NPV) analysis. To compare the candidates of project, delta NPV (DNPV) analysis is conducted, reflecting the results given in section 1.8 Technology Modeling. The key assumptions are summarized:

  • For simplicity, the free cash flow is obtained with three categories: R&D, revenue, and manufacturing. For R&D phase, a beta distribution and five year is assumed. Also, the operation phase (for revenue an manufacturing) is set to be 20 years with 5-year linear ramp up. (Other detailed assumptions are shown later).
  • The discount rate is set to 7% to compute the discounted cash flow and NPV.
  • In manufacturing, the learning curve is set to 0.8.

Assumptions for cash flow computation
HEFA conversion process development is set to be the baseline since HEFA is currently most matured pathway or technology.

  • R&D budget is assumed to be $2M
  • Manufacturing cost is computed with SAF Unit cost (after improvement) × market share increase (from 2040 – 2020 in EU) × target market share (30%)
  • Revenue is computed with 30% profit margin considered to the manufacturing cost

The flight demonstration project, collaborating with an aircraft manufacture is assumed to be led by the aircraft manufacturer, and the R&D budget is used for necessary testing and inspection requested by the manufacturer. Thus, for simplification, NPV is computed with only R&D cost is reduced to be 25% to the baseline.

Other projects are computed with the following assumptions

  • R&D cost is computed with the expected annual investment in 2040 in EU weighted to the baseline
  • Manufacturing cost is modified from the baseline, assuming that it is inversely proportional to SAF Unit cost, and is proportional to market share increase (from 2040 – 2020 in EU) and the unit cost reduction rate (by the project).
  • Revenue is computed with 30% profit margin considered to the manufacturing cost.

Note that the expected annual investment and market share in EU refer McKinsey/ETC2021

The sample computational results are summarized in the following tables and figures *The full DNPV analysis is shown in section 1.9 List of R&D projects.

Fin tab.png

Hefa conv.png

PtL H2.png

Flight Demo.png

List of R&D Projects

We pick up six candidates of the R&D project for the 2SAF roadmap. To select the projects for our roadmap, we asses them using DNPV analysis, reflecting the results of SAF unit cost given in section 1.8 Technology Model (see detailed assumptions in section 1.8 Financial Model).

The results are summarized in the table shown below. Based on the rank of DNPV analysis, we choose three projects of 1) flight demonstration, 2) PtL hydrogen facility development, and 3) CO2 capturing facility development. It should be noted that the DNPV analysis does not take the CO2 emission and performance model. However, PtL has a great potential of CO2 reduction and performance would be similar to FT as shown in section 1.8. Thus, those technical factors do not change the given results by DNPV analysis.

Rd tab.png

Cost ave rd.png

The time development of the discounted cash flow for each project is shown in the following figures.

Hefa conv.png

FT conv.png

PtL H2.png

PtL CO2.png

PtL Conv.png

Flight Demo.png

Key Publications, Presentations and Patents

A thorough survey of literature available in the public domain has been perused to gauge the current progression of various available SAF technologies [1]. Published in 2019, the survey details and highlights the theory and the multiple pathways behind key SAF technologies[1]. Figure P1 is presented below to illustrate the extensive search results of research publications related to SAF since 1960.

Keypublications.png
Figure P1. Web of Science data ( > 1960) of bio-aviation fuel publications, with bio-aviation (jet) fuel as main index, and ‘technical, policy, economics, environmental, LCA, combustion chemistry and properties as sub-indices [1]

One key enabling patent for the production of SAF that closely tracks the findings of the extensive literature survey from Figure P1 was granted in Jan 14, 2014 in the United States as Patent No. US8629310B2 (Classification:C10L1/06 and other 34 more classifications) [2]. Granted to associates from the Phillips 66 Company regarding “Transportation Fuels from Biomass Oxygenates", the patent describe a process through which “biocrude” or “oxygenate feedstocks derived from biomass” are converted into hydrocarbons through condensation/oligomerization and hydrodeoxygenation processes [2]. The key figure describing the patent processes are shown below in Figure P2:

Patentdrawing.png
Figure P2. US8629310B2 Patent Process Highlight[2]

This patent is especially relevant to the SAF technology because it presents one of the key pathways for aviation fuels to be produced from non-fossil sources. Numerous research papers that have been published describing the “oxygenic precursors from carbohydrates” conversion into SAF, and many are outlined in [1]. While the patent provides only a summary and does not detail the entire process through which the hydrocarbons are generated, it is nonetheless useful to see that it leverages methods that have been published regarding pathways that have enabled the “production of bio-aviation fuel and precursors through an improved fatty acid and biosynthetic pathway” [1] while also touching upon elements of pathways that enable the “production of bio-aviation fuel and precursors through the alcohol biosynthetic pathway” [1] as an option. Further analysis of the “fatty acid pathways” are cited in [1], among which [3] and [4] are especially relevant for understanding the microbial production of alkanes, which is a key enabler for the technology behind the patent.

Another key patent is in the category of Direct Air Capture (DAC), which extracts CO2 directly from the atmosphere[5]. DAC recently receives a lot of attention as a source of the feedstock of power to liquid (PtL) type SAF, because it is capable of producing SAF, reducing the amount of CO2 in the atmosphere [6]. US20170106330A1 (Classification:B01D53/0423 and other 6 more classifications) [7] is a design for DAC chamber as shown in Figure P3. DAC is one of our main focus areas for the development in the 2SAF roadmap, so the DAC related patent is quite important to be examined.

US20170106330A1.png
Figure P3. US20170106330A1 Direct Air Capture Device [7]

Technology Strategy Statement

The technology strategy statement of the 2SAF roadmap is shown as follows: Our target is to achieve the 30% global market share, using power to liquid (PtL) technology in the sustainable aviation fuel by 2040, resulting in large contribution to the green aviation. To achieve the goal, CO2 capturing facility development is conducted by 2028. The target is 50% carbon feedstock unit cost reduction. Next, a flight demonstration, collaborating with aircraft industry is conducted to increase the technology readiness level (TRL) of our PtL technology by 2030. Finally, we will invest H2 facility development, targeting 50% hydrogen cost reduction by 2035. Those projects allow us to reach our technical and business targets for 2040.

File:Arrow chart.png

References

[1] M. Wang, R. Dewil, K. Maniatis, J. Wheeldon, T. Tan, J. Baeyens and Y. Fang, "Biomass-derived aviation fuels: Challenges and perspective," Progress in Energy and Combustion Science, vol. 74, pp. 31-49, 2019.
[2] E. Lotero, K. Fjare, T. Shi, S. Pansare and Y. Bao, "Transportation Fuels from Biomass Oxygenates". USA Patent US8629310B2, 14 January 2014.
[3] A. Schirmer, M. A. Rude, X. Li and S. B. Del Cardayre, "Microbial biosynthesis of alkanes," Science, vol. 329, no. 5991, pp. 559-562, 2010.
[4] Y. J. Choi and S. Y. Lee, "Microbial production of short-chain alkanes," Nature, vol. 502, no. 7472, pp. 571-574, 2013.
[5] K. Kackner, H-J Ziock and P. Grimes, "Carbon Dioxide Extraction from Air: Is It An Option?," InProceedings of the 24th Annual TechnicalConference on Coal Utilization&Fuel System, LA-UR-99-0583,1999.
[6] Y. J. Choi and S. Y. Lee, "Microbial production of short-chain alkanes," Energy Convers. Manag., vol. 292, 117427, 2023.
[7] C. Gebald, W. Meier, N. Repond, T. Ruesch, J. A. Wurzbacher, "Direct air capture device". USA Patent US20170106330A1, 20 April 2017.