Anion-Assisted Formation of Discrete Homodimeric and Heterotetrameric Assemblies by Benzene Based Protonated Heteroaryl Receptors ArunachalamM. ChakrabortySourav MarivelS. GhoshPradyut 2012 Anion-assisted formation of discrete homodimeric and heterotetrameric assemblies by benzene based protonated heteroaryl receptors <b>L</b><sup><b>1</b></sup>–<b>L</b><sup><b>6</b></sup> have been studied thoroughly by single crystal X-ray diffraction studies. Crystallographic results elucidate the fact that protonated tripodal receptor <b>L</b><sup><b>1</b></sup> formed staggered homodimeric capsular assemblies <b>2</b> and <b>3</b> with CF<sub>3</sub>COO<sup>–</sup> and ClO<sub>4</sub><sup>–</sup> ions, respectively. Protonation of <b>L</b><sup><b>3</b></sup> with trimesic acid also showed the formation homodimeric assembly, <b>6</b>. In all these cases the anions are hydrogen bonded to the receptor molecules and show remarkable influence on the outcome of the self-assembly process to form discrete capsules. The necessity of the alkyl substitution on the benzene platform has been established from complexes <b>8</b>, <b>9</b>, and <b>10</b>, which were obtained upon protonation of <b>L</b><sup><b>6</b></sup> with HNO<sub>3</sub>, HI, and HClO<sub>4</sub>, respectively. Interestingly, when a 1:1 mixture of <b>L</b><sup><b>1</b></sup> (tripodal) and <b>L</b><sup><b>5</b></sup> (dipodal) were treated with HClO<sub>4</sub> and HBF<sub>4</sub>, discrete heterotetrameric assemblies have been isolated as complexes <b>11</b> and <b>12</b>. The detailed solid state structural analysis of these complexes revealed the formation of heterotetrameric assemblies assisted by anion–water clusters. Correlation of these solid state structural assemblies with our previously reported complexes <b>1</b>, <b>4</b>, <b>5</b>, and <b>7</b> has also been described. The role of anionic templates in assisting the formation of discrete capsular assemblies from receptors possessing heteroaryl units and 1,3,5-methyl substituted benzene platform has been established.