@article {154, title = {When does a supramolecular synthon fail? Comparison of bridgehead-functionalized adamantanes: the tri- and tetra- amides and amine hydrochlorides}, journal = {Crystal Growth \& Design}, year = {2019}, month = {July 12, 2019}, type = {Full paper}, abstract = {

1,3,5-trisubstituted adamantane carboxamide and amine hydrochloride, Ad(CONH2)3 {\textperiodcentered} 2.5H2O and [Ad(NH3)3]Cl3 {\textperiodcentered} H2O (Ad = adamant-n-yl) respectively, crystallized from aqueous solutions, possess crystal structures with predictable H-bonded assembly, consistent with the C3v symmetry of the building blocks. The triamide structure consists of interpenetrated hexagonal networks, sustained by the well-known cyclic H-bonded bis-amide synthon, R22(8), which ensures linear connectivity. The structure of the triamine hydrochloride, assembled through the tetrahedral {RN+H3---(Cl-)3} synthon, features a remarkably symmetric assembly with narrow trigonal pore-channels, hosting water molecules. The structures of the tetrahedral 1,3,5,7-tetrasubstituted Ad(CONH2)4 and [Ad(NH3)4]Cl4, obtained similarly, demonstrate a formal prediction failure of synthon based approach. Instead of the anticipated bis-amide synthon based diamond network (1.485 g cm-3) analogous to the 5-fold interpenetrated paradigmatic structure of Ad(COOH)4, a non-interpenetrated assembly, sustained by a dense network of H-bonds, is realized (1.433 g cm-3). Lessened geometric regularity was also found in the tetrahydrochloride salt assembled via 5-connected nodes, {RN+H3---(Cl-)4}, which involve a bifurcated H-bond. The failures of the supramolecular synthons in these simple cases could be interpreted either in terms of symmetry and/or limitations associated with the {\textquoteleft}synthon-density{\textquoteright}. A potential machine learning approach oriented on heuristic retrosupramolecular synthesis relies on such selected high-weight conceptual cases.

}, keywords = {adamantane, amide, amine, crystal structure, H-bond, hydrochloride, prediction, supramolecular synthon, violation}, doi = {https://doi.org/10.1021/acs.cgd.9b00594}, url = {https://pubs.acs.org/doi/10.1021/acs.cgd.9b00594}, author = {Ishtvan Boldog and Guido Reiss and Kostiantyn V. Domasevitch and Tomas Base and Stefan Braese} } @article {142, title = {10-vertex closo-carborane: a unique ligand platform for porous coordination polymers}, journal = {CrystEngComm}, volume = {18}, year = {2016}, month = {06/2016}, pages = {2036-2040}, chapter = {2036}, abstract = {

1,10-dicarboxy-1,10-dicarba-closo-decaborane, a classical dicarboxylate spacer ligand type similar to the prototypal terephthalic acid, proved to be different not only from the latter, but also the closest relative, the 1,12-dicarboxy-closo-1,12-dicarbadecaborane regarding topology of the derived PCPs. Highly porous and robust compounds of zinc (rob net) and cobalt ({\textquoteright}quasi{\textquoteright} pcu) as well as a topologically unexpected copper compound (lvt) define the individuality of the 10-vertex carborane cage as a new fundamental spacer type in PCP chemistry. A combination of smaller sterics compared to the 12-vertex analogue, 45{\textdegree} preferred-orientation angle between the carboxylate planes and moderately low rotation barrier are held responsible for the uniqueness.

}, keywords = {10 vertex, carborane, Co, crystallography, Cu, MOF, porous coordination polymers, Zn}, doi = {10.1039/C5CE02501J}, url = {http://pubs.rsc.org/en/content/articlelanding/2016/ce/c5ce02501j$\#$!divAbstract}, author = {Ishtvan Boldog and Pablo J Bereciartua and Roman Bulanek and Monika Kucerakova and Marketa Tomandlova and Michal Dusek and Jan Machacek and Dirk De Vos and Tomas Base} } @article {139, title = {Self-Assembled p-Carborane Analog of p-Mercaptobenzoic Acid on Au{111}}, journal = {Chemistry of Materials}, year = {2015}, month = {06/2015}, type = {Article}, abstract = {

Thep-carborane cluster analog of p-mercaptobenzoic acid, 1

}, keywords = {boron compounds, carborane, crystallography, scanning tunneling microscopy, self-assembly}, doi = {10.1021/acs.chemmater.5b02263}, url = {http://pubs.acs.org/doi/pdf/10.1021/acs.chemmater.5b02263}, author = {John C Thomas and Ishtvan Boldog and Harsharn S Auluck and Pablo J Bereciartua and Michal Dusek and Jan Machacek and Zdenek Bastl and Paul S Weiss and Tomas Base} }