Despite being studied for almost two centuries, aromaticity has always been a controversial concept. We previously proposed a unified aromatic rule for π-conjugated systems by two-dimensional (2D) superatomic-molecule theory, where benzenoid rings are treated as period 2 2D superatoms (3π-◊N, 4π-◊O, 5π-◊F, 6π-◊Ne) and, further, bond to form 2D superatomic molecules. Herein, to build a 2D periodic table, we further extend the theory to period 3 (7π-◊P, 8π-◊S, 9π-◊Cl, 10π-◊Ar) and period 1 (1π-◊H, 2π-◊He) elements. Various polycyclic π-conjugated species, namely, C18H16, C14H12, C18H14, [C21H15]-, and C2B4H4, are treated as ◊Cl2, ◊Cl◊F, ◊S◊F2, ◊P◊F3, and ◊H2 superatomic molecules, respectively, where each 2D superatom achieves π electronic shell-closure via superatomic lone pairs and/or two supercenter-two electron (2sc-2e) bonds. Due to the special π electron arrangement and small superatomic orbital energy gaps, period 3 superatoms engage in novel DD, PD orbital interactions and PD, SD2 hybridizations. This work replenishes the 2D periodic table and their bonding rules.