Key points are not available for this paper at this time.
The atomic heats of vanadium, in the normal and superconducting states, have been determined from just above the transition temperature, T₂=5. 03^K, down to 1. 1^. After corrections to the 1948 temperature scale had been made, the normal state atomic heat could be represented by C₍=+ (125) ^4R (T{) }^3, with = (9. 260. 03) 10^-3 joule mole^-1 deg^-2 and =3385^K. The entropy difference, S₍-Sₒ, between the normal and superconducting states, extrapolated to 0^, was found to vanish, in accordance with the third law of thermodynamics. The critical field values deduced from S₍-Sₒ gave H₀=1310 oersteds; at higher temperatures they were in agreement with initial penetration fields previously reported. The most interesting result of this work was that below about 0. 7T₂ the electronic contribution to the atomic heat of the metal in the superconducting state could be represented by an exponential expression of the form C₄ₒ{T₂}=ae^-b{T₂T} with a=9. 17 and b=1. 50; such an exponential relation is consistent with a single-electron model of a superconductor involving a gap of the order of kT₂ per electron in the spectrum of available energy levels.
Corak et al. (Tue,) studied this question.