A Noble-Gas-Centered Coordinate for Within-Period Atomic Property Trends

Abstract

We introduce a single dimensionless landscape function J chem() = ( ) - 1, = (1+5)/2, on the noble-gas-centred coordinate = d/Lp ∈ [0,1), and show that it organizes four central atomic observables: first ionization energy 1, electron affinity EA, Mulliken electronegativity M, and Pearson chemical hardness η, on one periodic-table axis. The outward step J chem+ delivers IE1; the inward gap J chem- = J chem(1) - J chem() delivers EA and η; M follows by Mulliken's identity. Three results establish the empirical content. (i) The within-period IE1 envelope reproduces the full noble-gas-to-alkali ordering across periods 2--6: of 34 atoms compiled across periods 2-4, 26 lie on the predicted monotone descent and the 8 upward deviations occur exactly at the textbook anomaly sites \p3, d5, f7, s2, d10\. (ii) Two golden-ratio identities, IE1(Gp)/ IE1(Gp+1) ≈ 1/4 on three heavy noble-gas pairs and IE1(halogen)/ IE1(alkali) ≈ 2 on four within-period pairs, agree with NIST data to MAD ≈ 1\% and ≈ 5\%, respectively. (iii) The shared kernel J chem- provides single-parameter analytical fits to EA across periods 4--6 (MAE 0.3--0.4~eV), to Pearson hardness η across periods 2--4 (MAE 1~eV on noble-gas maxima up to 10.8~eV), and to Mulliken M across a 15-atom four-class benchmark (R2 = 0.73). At the period-averaged scale level, the shared-kernel relation EA/η ≈ C(p)EA/C(p)η is supported on period-4 NIST data: the empirical nine-atom mean EA/η = 0.180 agrees with the predicted constant 0.182 to better than 1\%, although individual-atom scatter (σ ≈ 0.13) is much larger.