A cobalt-nitrogen-doped porous carbon that exhibits a ribbon-shape morphology, high surface area, mesoporous structure, and high nitrogen and cobalt content is fabricated for high-performance self-supported oxygen reduction electrocatalytsts through template-free pyrolysis of cobalt porphyrin-based conjugated mesoporous polymer frameworks.
Graphene
nanoribbons (GNRs), defined as nanometer-wide strips of
graphene, have attracted increasing attention as promising candidates
for next-generation semiconductors. Here, we demonstrate a bottom-up
strategy toward novel low band gap GNRs (Eg = 1.70 eV) with a well-defined cove-type periphery both in solution
and on a solid substrate surface with chrysene as the key monomer.
Corresponding cyclized chrysene-based oligomers consisting of the
dimer and tetramer are obtained via an Ullmann coupling followed by
oxidative intramolecular cyclodehydrogenation in solution, and much
higher GNR homologues via on-surface synthesis. These oligomers adopt
nonplanar structures due to the steric repulsion between the two C–H
bonds at the inner cove position. Characterizations by single crystal
X-ray analysis, UV–vis absorption spectroscopy, NMR spectroscopy,
and scanning tunneling microscopy (STM) are described. The interpretation
is assisted by density functional theory (DFT) calculations.
The electronic and magnetic properties of nanographenes strongly depend on their size, shape and topology. While many nanographenes present a closed-shell electronic structure, certain molecular topologies may lead to an open-shell structure.
Nonbenzenoid
carbocyclic rings are postulated to serve as important
structural elements toward tuning the chemical and electronic properties
of extended polycyclic aromatic hydrocarbons (PAHs, or namely nanographenes),
necessitating a rational and atomically precise synthetic approach
toward their fabrication. Here, using a combined bottom-up in-solution
and on-surface synthetic approach, we report the synthesis of nonbenzenoid
open-shell nanographenes containing two pairs of embedded pentagonal
and heptagonal rings. Extensive characterization of the resultant
nanographene in solution shows a low optical gap, and an open-shell
singlet ground state with a low singlet–triplet gap. Employing
ultra-high-resolution scanning tunneling microscopy and spectroscopy,
we conduct atomic-scale structural and electronic studies on a cyclopenta-fused
derivative on a Au(111) surface. The resultant five to seven rings
embedded nanographene displays an extremely narrow energy gap of 0.27
eV and exhibits a pronounced open-shell biradical character close
to 1 (y
0 = 0.92). Our experimental results
are supported by mean-field and multiconfigurational quantum chemical
calculations. Access to large nanographenes with a combination of
nonbenzenoid topologies and open-shell character should have wide
implications in harnessing new functionalities toward the realization
of future organic electronic and spintronic devices.
A large number of graphene molecules, or large polycyclic aromatic hydrocarbons (PAHs), have been synthesized and display various optoelectronic properties. Nevertheless, their potential for application in photonics has remained largely unexplored. Herein, we describe the synthesis of a highly luminescent and stable graphene molecule, namely a substituted dibenzo[hi,st]ovalene (DBO 1), with zigzag edges and elucidate its promising optical‐gain properties by means of ultrafast transient absorption spectroscopy. Upon incorporation of DBO into an inert polystyrene matrix, amplified stimulated emission can be observed with a relatively low power threshold (ca. 60 μJ cm−2), thus highlighting its high potential for lasing applications.
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