We first demonstrate
the influence of d-elements
on the electronic-state alternation of molecules coupled with proton
transfer in d–π hybridized electron
systems. Compact and planar metal complexes with protonated 2,3-pyrazinedithiolates
(L), M(HL)2 (M = Ni, Pd, and Pt), were synthesized and subsequently determined
to be assembled by hydrogen bond (H-bond) interactions between pyrazine
moieties. Structural and theoretical investigations revealed that
these complexes are regarded as d–π
hybridized electron systems based on a M(S2C2)2 core, especially, significant d–π
hybridization in the Pt(S2C2)2 core
was indicated. The pH-dependent optical and electrochemical measurements
revealed that the Ni complex has a higher proton-accepting character
and a stronger pH dependence for redox potential compared with the
Pt complex. This indicates that the Ni complex has a larger amount
of π-electron density on ligands than the Pt complex because
the significant d–π hybridization in
the Pt complex could reduce the amount of π-electron reconstructed
by attaching/detaching proton. Cyclic voltammetry of Ni and Pt complexes
that form an H-bonded multimer showed a potential splitting at the
first redox wave (ΔE1/2 = 0.28 V
for M = Ni and 0.17 V for M = Pt) corresponding to a mixed-valence
state coupled with proton transfer. The ΔE1/2 values indicate that the change in electronic states by
proton transfer is remarkable in the Ni complex, but moderate in the
Pt complex. These experimental results lead that the d-element substitution plays a role in controlling the degree of proton–electron
coupling in d–π hybridized electron
systems.