Your search keyword '"Kandel, S. Alex"' showing total 3 results

1. Enantiopure molecules form apparently racemic monolayers of chiral cyclic pentamers.

Author

Heiner, Benjamin R., Handy, Kaitlyn M., Devlin, Angela M., Soucek, Jewel L., Pittsford, Alexander M., Turner, David A., Petersen, Jacob P., Oliver, Allen G., Corcelli, Steven A., and Kandel, S. Alex

Abstract

Ultra-high vacuum scanning tunneling microscopy (UHV-STM) was used to investigate two related molecules pulse-deposited onto Au(111) surfaces: indoline-2-carboxylic acid and proline (pyrrolidine-2-carboxylic acid). Indoline-2-carboxylic acid and proline form both dimers and C5-symmetric "pinwheel" pentamers. Enantiomerically pure S-(−)-indoline-2-carboxylic acid and S-proline were used, and the pentamer structures observed for both were chiral. However, the presence of apparently equal numbers of 'right-' and 'left-handed' pinwheels is contrary to the general understanding that the chirality of the molecule dictates supramolecular chirality. A variety of computational methods were used to elucidate pentamer geometry for S-proline. Straightforward geometry optimization proved difficult, as the size of the cluster and the number of possible intermolecular interactions produced an interaction potential with multiple local minima. Instead, the Amber force field was used to exhaustively search all of phase space for chemically reasonable pentamer structures, producing a limited number of candidate structures that were then optimized as gas-phase clusters using density functional theory (DFT). The binding energies of the two lowest-energy pentamers on the Au(111) surface were then calculated by plane-wave DFT using the VASP software, and STM images predicted. These calculations indicate that the right- and left-handed pentamers are instead two different polymorphs. [ABSTRACT FROM AUTHOR]

Published

2024

2. C–H···O Hydrogen Bonding in Pentamers of Isatin

Author

Silski, Angela M., Brown, Ryan D., Petersen, Jacob P., Coman, Joseph M., Turner, David A., Smith, Zach M., Corcelli, Steven A., Poutsma, John C., and Kandel, S. Alex

Abstract

Self-assembled monolayers of 1H-indole-2,3-dione (isatin), 3-methyl 2-oxindole, and 7-fluoroisatin are observed on the Au(111) surface via scanning tunneling microscopy (STM). We observed that isatin forms pentamers with density functional theory providing support for a cyclic structure stabilized by both N–H···O and C–H···O hydrogen bonds between neighboring molecules. The C–H···O bond is made between the 7-position C–H acting as the hydrogen bond donor and the 3-position carbonyl as the hydrogen bond acceptor, and calculations show that the isatin pentamer structure is 12 kJ/mol more stable than the dimer. When the 3-position carbonyl is removed and replaced with a methyl group (3-methyl 2-oxindole), we observe a monolayer with a mixture of catemer chains and pentameric clusters that are qualitatively different from those of isatin. Pentamer formation is completely broken when the 7-position hydrogen is removed and replaced with fluorine; the monolayer of 7-fluoroisatin is composed of a mixture of close packed ordered domains and hexamer clusters. The role of C–H···O bonding in forming isatin pentamers is supported by electrospray ionization mass spectrometry measurements, which show a propensity for isatin cluster formation, including magic-number isatin pentamers, while 3-methyl 2-oxindole and 7-fluoroisatin show relatively little clustering under the same conditions.

Published

2024

3. Structural Polymorphism as the Result of Kinetically Controlled Self-Assembly

Author

Brown, Ryan D., Corcelli, Steven A., and Kandel, S. Alex

Abstract

Traditionally, the goal of self-assembly and supramolecular chemistry is to engineer an equilibrium structure with a desired geometry and functionality; this is achieved through careful choice of molecular monomers, growth conditions, and substrate. Supramolecular assemblies produced under nonequilibrium conditions, in contrast, can form metastable structures with conformations quite different from those accessible in equilibrium self-assembly. The study of nonequilibrium growth of clusters potentially impacts the study of nucleation in atmospheric aerosols, nucleation in organic crystallization, and mesoscale organization for systems ranging from biological molecules to molecular electronics. In our experiments, we prepare surface monolayers of small organic and organometallic molecules through direct injection of a solution onto a substrate in high vacuum. During this process, the rapid evaporation of small solution droplets in high vacuum can lead to nonequilibrium growth conditions. The resulting structures are then characterized by scanning tunneling microscopy.

Published

2024