Equivalence of NH < inf > 4 < /inf > < sup > + < /sup > , NH < inf > 2 < /inf > NH < inf > 3 < /inf > < sup > + < /sup > , and OHNH < inf > 3 < /inf > < sup > + < /sup > in directing the noncentrosymmetric diamondoid network of O-H⋯O < sup > - < /sup > hydrogen bonds in dihydrogen cyclohexane tricarboxylate

Abstract

The assembly of hexagonal and diamond network architectures from functionalized tectons of trigonal and tetrahedral symmetry, respectively, is an important activity in crystal engineering. We report a novel supramolecular transformation for the synthesis of diamond network structures from the trigonal molecule, 1,3-cis,5-cis-cyclohexanetricarboxylic acid (H3CTA). Crystal structures of some salts of the trigonal anion, H2CTA -, with tetrahedral counterions is analyzed in H2CTA -·NH4+ 1, H2CTA -·MeNH3+ 2, H2CTA -·EtNH3+ 3, H2CTA -·NH2NH3+ 4, and H 2CTA-·OHNH3+ 5. The trigonal anion functions as a tetrahedral self-complementary node in the presence of NH4+ counterion (salt 1) via two COOH donors and COOH - as a double hydrogen-bond acceptor. The triply interpenetrated diamondoid network of O-H⋯O- hydrogen bonds in 1 is reproduced in isostructural 3D nets of 4 and 5 by substituting NH4+ by NH2NH3+ and OHNH3+ (Π = 0.025, 0.027). The SHG activity of noncentrosymmetric diamondoid solids 1,4, and 5 (space group Cc) is comparable to that of the nonlinear optical (NLO) material potassium dihydrogen phosphate (KDP) (0.3 x urea). However, salts 2 and 3 (space groups P21/c and P1) have hexagonal and square grid layers of H2CTA- anions because the ammonium cation in these structures is devoid of the fourth strong hydrogen-bond donor group to extend crystal growth to the 3D diamond network. Thus, RNH3+counterions may be used to control the anionic network of the H 2CTA- molecule based on a tetrahedral node in 1, 4, and 5, a trigonal node in 2, and a square node in 3. The function of cyclohexane tricarboxylate as a four-connected node, shown for the first time in a trigonal molecule, is in contrast to the usual role of the trimesate anion as a three-connected node in molecular complexes. © 2005 American Chemical Society.