Production Cost and Carbon Footprint of Biomass-Derived Dimethylcyclooctane as a High-Performance Jet Fuel Blendstock

Baral, Nawa Raj; Yang, Minliang; Harvey, Benjamin G.; Simmons, Blake A.; Mukhopadhyay, Aindrila; Lee, Taek Soon; Scown, Corinne D.

doi:10.1021/acssuschemeng.1c03772

Cited by 28 publications

(29 citation statements)

References 30 publications

(88 reference statements)

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“…Therefore, nickel-based catalysts are likely preferred for the hydrogenation of the isoprene cyclodimers. 51 However, the higher pressures and temperatures required to obtain complete conversion may partially offset the lower catalyst cost.…”

Section: Resultsmentioning

confidence: 99%

Thermal cyclodimerization of isoprene for the production of high-performance sustainable aviation fuel

Woodroffe

Harvey

2022

Energy Adv.

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Section: Resultsmentioning

confidence: 99%

Thermal cyclodimerization of isoprene for the production of high-performance sustainable aviation fuel

Woodroffe

Harvey

2022

Energy Adv.

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“…The CI of SAF derived from corn grain ethanol is 26% lower than the CI of petroleum jet fuel, and several cellulosic and advanced biomass feedstock have potential emission reductions of 33%–91% . For that reason, many previous studies have focused on developing the cellulosic pathways to SAF production. − …”

Section: Introductionmentioning

confidence: 99%

Life-Cycle Greenhouse Gas Emissions of Sustainable Aviation Fuel through a Net-Zero Carbon Biofuel Plant Design

Yoo

Lee

Wang

2022

ACS Sustainable Chem. Eng.

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Sustainable aviation fuels (SAFs) are being promoted to mitigate greenhouse gas (GHG) emissions in the aviation sector. Gevo, Inc. is designing a new biorefinery to produce net-zero-emission jet fuel and gasoline from corn feedstock by replacing conventional energy sources with renewable energy sources along with carbon capture and storage (CCS). In this study, we analyze the GHG reduction of the plant design for Gevo's Net-Zero 1 plant on a life-cycle basis. The lifecycle GHG emissions [also called carbon intensity (CI)] of Gevo's facility base case are estimated at 70.4 gCO 2 e/MJ when using conventional energy sources. Using four deep-decarbonization strategies to be deployed in the plant, GHG emissions can be reduced by 3.7, 11.5, 24.8, and 34 gCO 2 e/MJ through renewable hydrogen, renewable electricity, renewable heat sources, and CCS, respectively. Furthermore, sustainable and precision farming practices with increased yield would reduce the CI value further, to −34.6 gCO 2 e/ MJ. Given its design capacity, the operation of the Net-Zero 1 plant will result in a GHG reduction of 514,000 metric tons per year compared to the reference petroleum jet fuel and gasoline, while generating 170 million liters of SAFs and renewable gasoline a year with a CI of −3.5 gCO 2 e/MJ.

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“…26,27 Interestingly, the hydrogenated [4+4] dimers of isoprene have better fuel properties compared to conventional jet fuels (Jet-A), and a life-cycle assessment and technoeconomic analysis showed that the process can be further improved to reduce cost and emission to compete within the sustainable aviation fuel sector. 28 The [2+2] oligomerization of isoprene was not selective for dimers since also trimers and tetramers were formed in significant amounts.…”

Section: Introductionmentioning

confidence: 99%

A Combined Photobiological-Photochemical Route to C10 Cycloalkane Jet Fuels from Carbon Dioxide via Isoprene

Rana¹,

Gomes²,

Rodrigues³

et al. 2022

Preprint

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The hemiterpene isoprene is a volatile C5 hydrocarbon with industrial applications. It is generated today from fossil resources, but can also be made in biological processes. We have utilized engineered photosynthetic cyanobacteria for direct, light-driven production of bio-isoprene from carbon dioxide, and show that isoprene in a subsequent photochemical step, using either near-UV or simulated or natural solar light, can be dimerized into limonene, paradiprene, and isomeric C10H16 hydrocarbons (monoterpenes) in high yields under photosensitized conditions (above 90% after 44 hours with near-UV and 61% with simulated solar light). The optimal sensitizer in our experiments is di(naphth-1-yl)methanone which we use with a loading of merely 0.1 mol%. It can also easily be recycled for subsequent photodimerization cycles. The isoprene dimers generated are a mixture of [2+2], [4+2] and [4+4] cycloadducts, and after hydrogenation this mixture is nearly ideal as a drop-in jet fuel. Importantly the photodimerization can be carried out at ambient conditions. However, the high content of hydrogenated [2+2] dimers in our isoprene dimer mix lowers the flash point below the threshold (38 °C), yet, these dimers can be converted thermally into [4+2] and [4+4] dimers. When hydrogenated these monoterpenoids fully satisfy the criteria for drop-in jet fuels with regard to energy density, flashpoint, kinematic viscosity, density, and freezing point. Life-cycle assessment results show a potential to produce the fuel in an environmentally sustainable way.

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Production Cost and Carbon Footprint of Biomass-Derived Dimethylcyclooctane as a High-Performance Jet Fuel Blendstock

Cited by 28 publications

References 30 publications

Thermal cyclodimerization of isoprene for the production of high-performance sustainable aviation fuel

Thermal cyclodimerization of isoprene for the production of high-performance sustainable aviation fuel

Life-Cycle Greenhouse Gas Emissions of Sustainable Aviation Fuel through a Net-Zero Carbon Biofuel Plant Design

A Combined Photobiological-Photochemical Route to C10 Cycloalkane Jet Fuels from Carbon Dioxide via Isoprene

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