Aviation Fuel Characterization at Operationally Relevant Conditions

Robert McCormick; Gina Fioroni; David Montgomery; Jon Luecke; Shashank Yellapantula

doi:10.2172/3015001

Aviation Fuel Characterization at Operationally Relevant Conditions

National Laboratory of the Rockies

Research output: NLR › Presentation

Abstract

To accelerate approval and potentially expand the allowable property range for aviation fuels, we are using high performance computing simulations to reveal fuel property effects on aviation combustor performance. These simulations are supported by fuel property measurements over temperatures and pressures that the fuel experiences in an aircraft engine and by validated chemical kinetics models for SAF combustion. Here we report density, viscosity, and surface tension results for conventional jet fuel and multiple synthetic fuels from -30 degrees Celsius to 200 degrees Celsius (-40 degrees Celsius for viscosity) and 1 atm to 70 atm including an assessment of method repeatability. Properties of surrogate mixtures are also investigated. Distillation, ICN, LHV, flashpoint, and Cp are also reported, and data are being used to develop models to predict fuel properties from composition (GCxGC).

Original language	American English
Number of pages	17
DOIs	https://doi.org/10.2172/3015001
State	Published - 2025

Publication series

Name	Presented at the International Conference on Sustainable Aviation Research (ICSAR), 9-11 July 2025, Dublin, Ireland

NLR Publication Number

NLR/PR-2A00-95728

Keywords

jet fuel
properties
property prediction models
synthetic aviation fuel

Access to Document

10.2172/3015001

https://www.nrel.gov/docs/fy26osti/95728.pdf

Cite this

@misc{a5b4050236c4406d83d5c798c4e259fa,

title = "Aviation Fuel Characterization at Operationally Relevant Conditions",

abstract = "To accelerate approval and potentially expand the allowable property range for aviation fuels, we are using high performance computing simulations to reveal fuel property effects on aviation combustor performance. These simulations are supported by fuel property measurements over temperatures and pressures that the fuel experiences in an aircraft engine and by validated chemical kinetics models for SAF combustion. Here we report density, viscosity, and surface tension results for conventional jet fuel and multiple synthetic fuels from -30 degrees Celsius to 200 degrees Celsius (-40 degrees Celsius for viscosity) and 1 atm to 70 atm including an assessment of method repeatability. Properties of surrogate mixtures are also investigated. Distillation, ICN, LHV, flashpoint, and Cp are also reported, and data are being used to develop models to predict fuel properties from composition (GCxGC).",

keywords = "jet fuel, properties, property prediction models, synthetic aviation fuel",

author = "Robert McCormick and Gina Fioroni and David Montgomery and Jon Luecke and Shashank Yellapantula",

year = "2025",

doi = "10.2172/3015001",

language = "American English",

series = "Presented at the International Conference on Sustainable Aviation Research (ICSAR), 9-11 July 2025, Dublin, Ireland",

type = "Other",

}

TY - GEN

T1 - Aviation Fuel Characterization at Operationally Relevant Conditions

AU - McCormick, Robert

AU - Fioroni, Gina

AU - Montgomery, David

AU - Luecke, Jon

AU - Yellapantula, Shashank

PY - 2025

Y1 - 2025

N2 - To accelerate approval and potentially expand the allowable property range for aviation fuels, we are using high performance computing simulations to reveal fuel property effects on aviation combustor performance. These simulations are supported by fuel property measurements over temperatures and pressures that the fuel experiences in an aircraft engine and by validated chemical kinetics models for SAF combustion. Here we report density, viscosity, and surface tension results for conventional jet fuel and multiple synthetic fuels from -30 degrees Celsius to 200 degrees Celsius (-40 degrees Celsius for viscosity) and 1 atm to 70 atm including an assessment of method repeatability. Properties of surrogate mixtures are also investigated. Distillation, ICN, LHV, flashpoint, and Cp are also reported, and data are being used to develop models to predict fuel properties from composition (GCxGC).

AB - To accelerate approval and potentially expand the allowable property range for aviation fuels, we are using high performance computing simulations to reveal fuel property effects on aviation combustor performance. These simulations are supported by fuel property measurements over temperatures and pressures that the fuel experiences in an aircraft engine and by validated chemical kinetics models for SAF combustion. Here we report density, viscosity, and surface tension results for conventional jet fuel and multiple synthetic fuels from -30 degrees Celsius to 200 degrees Celsius (-40 degrees Celsius for viscosity) and 1 atm to 70 atm including an assessment of method repeatability. Properties of surrogate mixtures are also investigated. Distillation, ICN, LHV, flashpoint, and Cp are also reported, and data are being used to develop models to predict fuel properties from composition (GCxGC).

KW - jet fuel

KW - properties

KW - property prediction models

KW - synthetic aviation fuel

U2 - 10.2172/3015001

DO - 10.2172/3015001

M3 - Presentation

T3 - Presented at the International Conference on Sustainable Aviation Research (ICSAR), 9-11 July 2025, Dublin, Ireland

ER -

Aviation Fuel Characterization at Operationally Relevant Conditions

Abstract

Publication series

NLR Publication Number

Keywords

Access to Document

Fingerprint

Cite this