Description of SF6 behavior within the state range from the triple point to supercritical fluid

“…The scaling (singular) part of the equation of state p scal , comprising besides values p c , ρ c , and T c fitting constants q, k, M -a p , and C 1 , taking into account the expansion of the integral member [20], has the form…”

“…For such a function, we selected [20] Y = ωerfc( |τ|)exp(-μ(Δρ) 2 ), (1) where ω = ρ/ρ с and erfc( |τ|) is the Laplace function (error function). Function (1) is associated with a proba bility of W ~ exp(-λτ 2 -μ(Δρ) 2 ) of the occurrence (damping) of fluctuations of temperature and density at some point of state T, ρ [5].…”

“…The regular part p reg of the combined equation of state is a modification of p reg , applied previously in [20], and contains eight system dependent (adjust able) constants A 1 -A 8 :…”

“…A unified thermal equa tion of state, approximating precision P-ρ-T data with sufficient accuracy, can give a description of the caloric properties with an accuracy not worse than the experimental and calculation of the properties of the system in regions where there are no experimental data or the obtaining of them is difficult. Modification of the regular eight constant EOS [11,20], as shown in this article, is suitable to describe the caloric prop erties of СО 2 and SF 6 .…”

“…These include the classic cubic EOS of the van der Waals type having a critical point; among the contemporary examples, the three constant Kaplun-Meshalkin EOS [17] and the Patel Teja EOS [8] are the most appropriate. Of the large number of regular few con stant EOS (four or more adjustable constants), let us mention only those having some physical justification: cubic EOS [18], which is a combination of the equa tions described in [17] and [8] (five constants), and the recently proposed EOSs, unified for the gas and liquid states of matter [19,20] (seven to nine constants). However, regular models of EOSs, despite fairly accu rate predictions of the thermodynamic properties away from the critical point, do not describe the singu lar behavior of the thermodynamic functions in the critical region.…”

Description of heat capacity C v of simple liquids using a thermal equation of state including regular and scaling parts

“…The scaling (singular) part of the equation of state p scal , comprising besides values p c , ρ c , and T c fitting constants q, k, M -a p , and C 1 , taking into account the expansion of the integral member [20], has the form…”

“…For such a function, we selected [20] Y = ωerfc( |τ|)exp(-μ(Δρ) 2 ), (1) where ω = ρ/ρ с and erfc( |τ|) is the Laplace function (error function). Function (1) is associated with a proba bility of W ~ exp(-λτ 2 -μ(Δρ) 2 ) of the occurrence (damping) of fluctuations of temperature and density at some point of state T, ρ [5].…”

“…The regular part p reg of the combined equation of state is a modification of p reg , applied previously in [20], and contains eight system dependent (adjust able) constants A 1 -A 8 :…”

“…A unified thermal equa tion of state, approximating precision P-ρ-T data with sufficient accuracy, can give a description of the caloric properties with an accuracy not worse than the experimental and calculation of the properties of the system in regions where there are no experimental data or the obtaining of them is difficult. Modification of the regular eight constant EOS [11,20], as shown in this article, is suitable to describe the caloric prop erties of СО 2 and SF 6 .…”

“…These include the classic cubic EOS of the van der Waals type having a critical point; among the contemporary examples, the three constant Kaplun-Meshalkin EOS [17] and the Patel Teja EOS [8] are the most appropriate. Of the large number of regular few con stant EOS (four or more adjustable constants), let us mention only those having some physical justification: cubic EOS [18], which is a combination of the equa tions described in [17] and [8] (five constants), and the recently proposed EOSs, unified for the gas and liquid states of matter [19,20] (seven to nine constants). However, regular models of EOSs, despite fairly accu rate predictions of the thermodynamic properties away from the critical point, do not describe the singu lar behavior of the thermodynamic functions in the critical region.…”

Description of heat capacity C v of simple liquids using a thermal equation of state including regular and scaling parts

The Thermodynamic Properties of CO2 up to 200 MPa Including the Critical Region, Calculated by a New Combined Equation of State with Few Parameters

Studies of the thermophysical properties of substances and materials at the Novosibirsk Scientific Center of the Siberian Branch of the Russian Academy of Sciences, 2002–2012