posted on 2012-05-02, 00:00authored byQian Sun, Yan-Qin Wang, Ai-Ling Cheng, Kun Wang, En-Qing Gao
Solvothermal reactions of m-phenylenediacrylic
acid (H2mpda) and zinc(II) salts in the presence of different
bis(pyridyl) ancillary ligands afforded a series of supramolecular
interpenetrated coordination architectures with formula [Zn(mpda)(bpee)]n (1), [Zn(mpda)(bpea)]n (2), and [Zn(mpda)(bpp)]n·2.5H2O (3) (bpee =
1,2-bis(4-pyridyl)ethylene, bpea = 1,2-bis(4-pyridyl)ethane, bpp =
1,3-bis(4-pyridyl)propane). X-ray analyses revealed that all of the
compounds feature tetrahedral-based coordination geometry around Zn(II),
two-dimensional (2D) 44 coordination networks with different
linkers, and parallel 2D→2D interpenetration, which is stabilized
by interlayer hydrogen-bonding interactions. The arc-shaped mpda ligand
collaborates with quasi-linear bpee or bpea to generate 2D achiral
networks with chair-shape windows in 1 and 2, but with two different arc-shaped ligands (mpda and bpp); the single
network in 3 is homochiral and has boat-shaped windows.
The different shapes of the networks result in different interpenetration
modes. Both networks of 1 and 2 exhibit
3-fold parallel interpenetration and give trilayers. Differently,
two layers of the same handedness in 3 interpenetrate
to give a homochiral bilayer featuring double helical motifs, and
the alternating stacking of oppositely handed bilayers renders the
compound racemic. The interpenetration mode and the formation of the
double helices in 3 benefit not only from the arc shape
of the two bridging ligands but also from the match of the two ligands
in length.