TY - JOUR
T1 - A review of gas-surface interaction models for orbital aerodynamics applications
AU - Livadiotti, Sabrina
AU - Crisp, Nicholas H.
AU - Roberts, Peter C.E.
AU - Worrall, Stephen D.
AU - Oiko, Vitor T.A.
AU - Edmondson, Steve
AU - Haigh, Sarah J.
AU - Huyton, Claire
AU - Smith, Katharine L.
AU - Sinpetru, Luciana A.
AU - Holmes, Brandon E.A.
AU - Becedas, Jonathan
AU - Domínguez, Rosa María
AU - Cañas, Valentín
AU - Christensen, Simon
AU - Mølgaard, Anders
AU - Nielsen, Jens
AU - Bisgaard, Morten
AU - Chan, Yung An
AU - Herdrich, Georg H.
AU - Romano, Francesco
AU - Fasoulas, Stefanos
AU - Traub, Constantin
AU - Garcia-Almiñana, Daniel
AU - Rodriguez-Donaire, Silvia
AU - Sureda, Miquel
AU - Kataria, Dhiren
AU - Belkouchi, Badia
AU - Conte, Alexis
AU - Perez, Jose Santiago
AU - Villain, Rachel
AU - Outlaw, Ron
N1 - Funding Information:
The DISCOVERER project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No 737183. Disclaimer: This publi-cation reflects only the views of the authors. The European Commission is not liable for any use that may be made of the information contained therein.
PY - 2020/11/27
Y1 - 2020/11/27
N2 - Renewed interest in Very Low Earth Orbits (VLEO) - i.e. altitudes below 450 km - has led to an increased demand for accurate environment characterisation and aerodynamic force prediction. While the former requires knowledge of the mechanisms that drive density variations in the thermosphere, the latter also depends on the interactions between the gas-particles in the residual atmosphere and the surfaces exposed to the flow. The determination of the aerodynamic coefficients is hindered by the numerous uncertainties that characterise the physical processes occurring at the exposed surfaces. Several models have been produced over the last 60 years with the intent of combining accuracy with relatively simple implementations. In this paper the most popular models have been selected and reviewed using as discriminating factors relevance with regards to orbital aerodynamics applications and theoretical agreement with gas-beam experimental data. More sophisticated models were neglected, since their increased accuracy is generally accompanied by a substantial increase in computation times which is likely to be unsuitable for most space engineering applications. For the sake of clarity, a distinction was introduced between physical and scattering kernel theory based gas-surface interaction models. The physical model category comprises the Hard Cube model, the Soft Cube model and the Washboard model, while the scattering kernel family consists of the Maxwell model, the Nocilla-Hurlbut-Sherman model and the Cercignani-Lampis-Lord model. Limits and assets of each model have been discussed with regards to the context of this paper. Wherever possible, comments have been provided to help the reader to identify possible future challenges for gas-surface interaction science with regards to orbital aerodynamic applications.
AB - Renewed interest in Very Low Earth Orbits (VLEO) - i.e. altitudes below 450 km - has led to an increased demand for accurate environment characterisation and aerodynamic force prediction. While the former requires knowledge of the mechanisms that drive density variations in the thermosphere, the latter also depends on the interactions between the gas-particles in the residual atmosphere and the surfaces exposed to the flow. The determination of the aerodynamic coefficients is hindered by the numerous uncertainties that characterise the physical processes occurring at the exposed surfaces. Several models have been produced over the last 60 years with the intent of combining accuracy with relatively simple implementations. In this paper the most popular models have been selected and reviewed using as discriminating factors relevance with regards to orbital aerodynamics applications and theoretical agreement with gas-beam experimental data. More sophisticated models were neglected, since their increased accuracy is generally accompanied by a substantial increase in computation times which is likely to be unsuitable for most space engineering applications. For the sake of clarity, a distinction was introduced between physical and scattering kernel theory based gas-surface interaction models. The physical model category comprises the Hard Cube model, the Soft Cube model and the Washboard model, while the scattering kernel family consists of the Maxwell model, the Nocilla-Hurlbut-Sherman model and the Cercignani-Lampis-Lord model. Limits and assets of each model have been discussed with regards to the context of this paper. Wherever possible, comments have been provided to help the reader to identify possible future challenges for gas-surface interaction science with regards to orbital aerodynamic applications.
KW - Gas-surface interaction
KW - Orbital aerodynamics
KW - Very low earth orbit
UR - http://www.scopus.com/inward/record.url?scp=85097211788&partnerID=8YFLogxK
U2 - 10.1016/j.paerosci.2020.100675
DO - 10.1016/j.paerosci.2020.100675
M3 - Article
AN - SCOPUS:85097211788
SN - 0376-0421
VL - 119
JO - Progress in Aerospace Sciences
JF - Progress in Aerospace Sciences
M1 - 100675
ER -