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Physical Properties of Common Chemicals

Physical Properties of Some Common Chemicals  

* Note: User should verify data from published sources such as NCR or Langes Handbook, MSDS, etc..
Number1
Component"ARGON"
Mole Wt39.95
Freeze Point, K83.8
Boiling Point, K87.3
Critical Temp, K150.8
Critical Pressure, Atm48.1
Critical Volume, cc/g-mole74.9
Critical Compress, Z(c)0.29
Acentric Factor, omega0
Liq Density @ ref_ temp, g/cc1.37
Ref Temp_ for Liquid Density, K90
Dipole Moment, Debyes0
Vapor Capacity Parameter A, Temp in K, Cpvap in cal/g-mol-K4.97
Vapor Capacity Parameter B, Temp in K, Cpvap in cal/g-mol-K0
Vapor Capacity Parameter C, Temp in K, Cpvap in cal/g-mol-K0
Vapor Capacity Parameter D, Temp in K, Cpvap in cal/g-mol-K0
Liquid Viscosity Parmeter B, log(v)=B*(1/T-1/C), T in K, V in Cp107.57
Liquid Viscosity Parmeter C, log(v)=B*(1/T-1/C), T in K, V in Cp58.76
Std Heat of Formation, kcal/g-mole0
Std Energy of Formation, kcal/g-mole0
Antoine Coeff A, ln(P) = A-B/(T+C), P in mm Hg, T in K15.23
Antoine Coeff B, ln(P) = A-B/(T+C), P in mm Hg, T in K700.51
Antoine Coeff C, ln(P) = A-B/(T+C), P in mm Hg, T in K-5.84
Vap Pressure Max Temp, K94
Vap Pressure Min Temp K81
Harlacher Vapor Press Coeff A, ln(pvp = A + B/T+C*ln(T)+(D*pvp/(T^2)), pvp as mm Hg, T in K31.17
Harlacher Vapor Press Coeff B, ln(pvp = A + B/T+C*ln(T)+(D*pvp/(T^2)), pvp as mm Hg, T in K-1039.64
Harlacher Vapor Press Coeff C, ln(pvp = A + B/T+C*ln(T)+(D*pvp/(T^2)), pvp as mm Hg, T in K-2.38
Harlacher Vapor Press CoeffDA, ln(pvp = A + B/T+C*ln(T)+(D*pvp/(T^2)), pvp as mm Hg, T in K0.26
Heat of Vapor, Normal BP, cal/g-mole1560
Expr1"ARGON"


 

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