Hopping or Tunneling? Tailoring the Electron Transport Mechanisms through Hydrogen Bonding Geometry in the Boron-Doped Diamond Molecular Junctions

Diverse Self-Assembled Molecular Architectures Promoted by C-H···O and C-H···Cl Hydrogen Bonds in a Triad of α-Diketone, α-Ketoimine, and an Imidorhenium Complex: A Unified Analysis Based on XRD, NEDA, SAPT, QTAIM, and IBSI Studies

X-ray structural elucidation, supramolecular self-assembly, and energetics of existential noncovalent interactions for a triad comprising α-diketone, α-ketoimine, and an imidorhenium complex are highlighted in this report. Molecular packing reveals a self-assembled 2D network stabilized by the C-H···O H-bonds for the α-diketone (benzil), and the first structural report of Brown and Sadanaga stressing on the prevalence of only the van der Waals forces seems to be an oversimplified conjecture. In the α-ketoimine, the imine nitrogen atom undergoes intramolecular N···H interaction to render itself inert toward intermolecular C-H···N interaction and exhibits two types of C-H···O H-bonds in consequence to generate a self-assembled 2D molecular architecture. The imidorhenium complex features a self-aggregated 3D packing engendered by the interplay of C-H···Cl H-bonds along with the ancillary C-H···π, C···C, and C···Cl contacts. To the best of our knowledge, in rhenium chemistry, this imidorhenium complex unravels the first example of self-associated 3D molecular packing constructed by the directional hydrogen bonds of C-H···Cl type. The presence of characteristic supramolecular synthons, viz., R2 2(12), R2 2(16), and R2 2(14), in the α-diketone, α-ketoimine, and imidorhenium complex, respectively, has prompted us to delve into the energetics of noncovalent interactions. Symmetry-adapted perturbation theory analysis has authenticated a stability order: R2 2(14) > R2 2(12) > R2 2(16) based on the interaction energy values of -25.97, -9.93, and -4.98 kcal/mol, respectively. The respective average contributions of the long-range dispersion, electrostatic, and induction forces are 58.5, 32.8, and 8.7%, respectively, for the intermolecular C-H···O interactions. The C-H···Cl interactions experience comparable contribution from the dispersion force (57.9% on average), although the electrostatic and induction forces contribute much less, 28.0 and 14.1%, respectively, on average. The natural energy decomposition analysis has further attested that the short-range, interfragment charge transfer occurring via the lp(O/Cl) → σ*(C-H) routes contributes 17-25% of the total attractive force for the C-H···O and C-H···Cl interactions. Quantum theory of atoms in molecules analysis unfolds a first-order exponential decay relation (y = 8.1043e -x/0.4095) between the electron density at the bond critical point and the distance of noncovalent interactions. The distances of noncovalent interactions in the lattices are internally governed by the individual packing patterns rather than the chemical nature of the H-bond donors and acceptors. Intrinsic bond strength index analysis shows promise to correlate the electron density at BCP with the SAPT-derived interaction energy for the noncovalent interactions. Two factors: (i) nearly half the HOMO-LUMO energy difference for the imidorhenium complex (∼30 kcal/mol) compared to the organics, and (ii) ∼60% localization of HOMO over the mer-ReCl3 moiety clearly indicate an enhanced polarizability of the complex facilitating the growth of weak C-H···Cl H-bonds.

Naphthalene diimide-Annulated Heterocyclic Acenes: Synthesis, Electrochemical and Semiconductor Properties and their Multifaceted Applications

Acenes and Naphthalene Diimides (NDIs) stand as distinguished classes of organic compounds, each possessing unique and intriguing properties that have garnered significant attention across various scientific disciplines. Acenes, characterized by linearly fused aromatic rings, have captivated researchers due to their diverse electronic structures and promising applications in materials science. On the other hand, NDIs, known for their distinctive electron-accepting properties, exhibit remarkable versatility in fields ranging from organic electronics, supramolecular to spin chemistry. In this review, we navigate through the fascinating realms of both acenes and NDIs before converging our focus on the highly diverse and distinctive subgroup of NDI-annulated heterocyclic acenes. This potentially important subgroup, has emerged as a subject of intense investigation, encapsulating their fascinating synthesis, optical and electrochemical characteristics, and multifaceted applications that span the realms of chemistry, physics, and biology. Through the exploration of their synthetic strategies, unique properties, and diverse applications, this review aims to offer a comprehensive understanding of the pivotal role played by NDI-based heterocyclic acenes in contemporary multidisciplinary research and technological innovation.

Characterization and Application of Supramolecular Junctions

The convergence of supramolecular chemistry and single-molecule electronics offers a new perspective on supramolecular electronics, and provides a new avenue toward understanding and application of intermolecular charge transport at the molecular level. In this review, we will provide an overview of the advances in the characterization technique for the investigation of intermolecular charge transport, and summarize the experimental investigation of several non-covalent interactions, including π-π stacking interactions, hydrogen bonding, host-guest interactions and σ-σ interactions at the single-molecule level. We will also provide a perspective on supramolecular electronics and discuss the potential applications and future challenges.