Sublimation SVP – A Material Property Database for organic liquids, ices, and solids on Titan

Adopted saturation vapor pressure expressions (Psat) as functions of temperature (T) for observed species, s-g represents solid-gas transitions. The “Temp. (K)” column indicates the temperature range for which the SVP functions can be applied. Note that temperature ranges with brackets correspond to temperatures for which only extrapolated SVPs are available, and temperatures without brackets have experimentally determined SVP in the temperature range.

Species	Type	Saturation vapor pressure expressions P_sat(T) (bar)	Temp. (K)	Ref.	Input Temp. (K) & Output P_sat (bar)
CH₄	s-g	10^{4.31972−451.64/(T−4.66)}	[20.509]-48-90.686 (T_tri)	Dykyj et al. (1999)	P_sat = 0
C₂H₆	s-g	10^{6.6388−1009.6/(T−3.15)}	[<] 71-90.3560 (T_tri)	Dykyj et al. (1999)	P_sat = 0
C₂H₄	s-g	e^{15.4−2206/T−1.216×10⁴/T²+2.843×10⁵/T³−2.203×10⁶/T⁴}	[<] 77.3-103.966 (T_tri)	Fray & Schmitt (2009)	P_sat = 0
C₂H₂	s-g	e^{13.4−2536/T}	[<] 98.6-191.66 (T_tri)	Fray & Schmitt (2009)	P_sat = 0
C₄H₂	s-g	10^{7.3757−1958.25/T}	[<] 127-237.7 (T_tri)	Orton et al. (2014)	P_sat = 0
C₆H₆	s-g	10^{6.72391-2107.85/(T-16.45)}	[<] 134.8-278.6877 (T_tri)	Dykyj et al. (1999)	P_sat = 0
C₃H₈	s-g	e^{17.802−2985/T−3.423×10⁴/T²+1.163×10⁶/T³−1.488×10⁷/T⁴}	[50.0]-[85.4] (T_tri)	Yu et al. (2023)	P_sat = 0
C₃H₆	s-g	e^{16.425−2691/T−5.291×10⁴/T²+1.858×10⁶/T³−2.481×10⁷/T⁴}	[50.0]-[87.850] (T_tri)	Yu et al. (2023)	P_sat = 0
C₃H₄-a	s-g	10^{6.7534−1434.94/T}	[<] 106-136.7 (T_tri)	Dykyj et al. (1999)	P_sat = 0
C₃H₄-p	s-g	e^{16.795−3799.6/T}	[<] 169.87	Yu et al. (2023)	P_sat = 0
HCN	s-g	e^{54.889-5969.5/T-6.0411Ln(T)}	[<] 194.565-259.871 (T_tri)	Kroenlein et al. (2011)	P_sat = 0
HC₃N	s-g	10^{9.0744−3046.5/(T+36.176)}	[<] 164.9-280 (T_tri)	Yu et al. (2023)	P_sat = 0
CO₂	s-g	e^{20.0456−3274.96/T−0.6102Ln(T )}	[<] 69.697-216.5890 (T_tri)	Kroenlein et al. (2011)	P_sat = 0
CH₃CN	s-g	e^{21.542−5853.5/T−6.9785×10⁻³T−1.9407×10⁻⁴T^1.5}	[20]-[216.9]	Yu et al. (2023)	P_sat = 0
CH₃CN	s-g	e^{23.405−5655.0/T−0.72971Ln(T )−1.6902×10⁻³T−1.9407×10⁻⁴T^1.5}	[216.9]-[229.349] (T_tri)	Yu et al. (2023)	P_sat = 0
C₂H₅CN	s-g	e^{25.869−6428.6/T −2.1410×10⁻²T −2.0625×10⁻⁴T^1.5+2.7238×10⁻⁵T²}	[15]-[176.964]	Yu et al. (2023)	P_sat = 0
C₂H₅CN	s-g	e^{−366.46+436.73/T +75.442Ln(T )−0.22541T −2.0625×10⁻⁴T^1.5}	[176.964]-[180.4] (T_tri)	Yu et al. (2023)	P_sat = 0
C₂H₃CN	s-g	e^{23.485-5879.0/T-1.1719x10^-2T-1.0523x10^-5T²+5.0429x10^-9T³-1.1612x10^-12T⁴}	[12.5]-[162.5]	Yu et al. (2023)	P_sat = 0
C₂H₃CN	s-g	e^{20.896-5583.8/T-4.1416x10^-2Ln(T)-5.6792x10^-3T-1.0523x10^-5T²+5.0429x10^-9T³-1.1612x10^-12T⁴}	[162.5]-[189.642] (T_tri)	Yu et al. (2023)	P_sat = 0
C₂N₂	s-g	e^{16.53−4109/T}	[<] 156.3-245.29 (T_tri)	Fray & Schmitt (2009)	P_sat = 0
C₄N₂	s-g	e^19.09-6036/T	[125.0]-147.0-273.2-[293.0] (T_tri)	Fray & Schmitt (2009)	P_sat = 0