Isotopic Dependence of Vapor Pressure in Xenon

Abstract

The vapor pressure isotopic effect (VPIE) of xenon has been measured using cryogenic distillation. The still is calibrated with argon and krypton and yields a measurement of ln(p ₁₃₀/p ₁₃₆) ≃ (0.26 ± 0.04) × 10^-3, where p ₁₃₀ and p ₁₃₆ are the vapor pressures of ¹³⁰Xe and ¹³⁶Xe at the nominal boiling point, respectively. The dependence of the VPIE across the isotopes for the three elements is found to be approximately linear with atomic mass, and all values are consistent with theoretical expectations.

Figure 1

Experimental setup showing gas entering the top of the still, with samples extracted from the top and bottom to be sent to the mass spectrometer.

Figure 2

Mass spectra for (a) argon, (b) krypton, and (c) xenon.

Figure 3

Average fractional difference between the top and bottom of the column, δ_i, for each isotope of (a) argon, (b) krypton, and (c) xenon. The data can be described by a linear dependence on the isotopic mass m_i, and results from the fit δ_i = p₁m_i + p₀ are presented for each fluid.

Figure 4

VPIE between fluids isotopes as a function of (a) T* and (b) . The lines represent values from numerical simulations for argon (dashed), krypton (dot-dashed), and xenon (solid), while the filled regions are the corresponding expectations from eq 2³ accounting for uncertainties in the parameters. Open data points are those presented in Tables 1 and 2 for argon (diamonds), krypton (squares), and xenon (circle) representing the average for the same temperature, while solid points with error bars are measurements from this work.