91 research outputs found
DonorâAcceptor Fluorophores for Visible-Light-Promoted Organic Synthesis: Photoredox/Ni Dual Catalytic C(sp<sup>3</sup>)âC(sp<sup>2</sup>) Cross-Coupling
We
describe carbazolyl dicyanobenzene (CDCB)-based donorâacceptor
(DâA) fluorophores as a class of cheap, easily accessible,
and efficient metal-free photoredox catalysts for organic synthesis.
By changing the number and position of carbazolyl and cyano groups
on the center benzene ring, CDCBs with a wide range of photoredox
potentials are obtained to effectively drive the energetically demanding
CÂ(sp<sup>3</sup>)âCÂ(sp<sup>2</sup>) cross-coupling of carboxylic
acids and alkyltrifluoroborates with aryl halides via a photoredox/Ni
dual catalysis mechanism. This work validates the utility of DâA
fluorophores in guiding the rational design of metal-free photoredox
catalysts for visible-light-promoted organic synthesis
Pseudocapacitive Properties of Two-Dimensional Surface Vanadia Phases Formed Spontaneously on Titania
Pseudocapacitive
properties of V<sub>2</sub>O<sub>5</sub>-based adsorbates supported
on TiO<sub>2</sub> nanoparticles, which form spontaneously as two-dimensional
(2-D) nonautonomous surface phases (complexions) at thermodynamic
equilibria, have been systematically measured. Surprisingly, surface
amorphous films (SAFs), which form naturally at thermodynamic equilibria
at 550â600 °C with self-regulating or âequilibriumâ
thicknesses on the order of 1 nm, exhibit superior electrochemical
performance at moderate and high scan rates (20â500 mV/s) that
are of prime importance for supercapacitor applications, as compared
with submonolayer and monolayer adsorbates formed at lower equilibration
temperatures. This study suggests a new direction to design and fabricate
a novel class of supercapacitors and other functional devices via
utilizing 2-D interfacial phases that can form spontaneously via facile,
cost-effective, and highly scalable synthesis routes
Carbazolic Porous Organic Framework as an Efficient, Metal-Free Visible-Light Photocatalyst for Organic Synthesis
We report the visible-light-promoted
photocatalytic activity of
a highly porous carbazolic organic framework, Cz-POF-1, toward three
prototypic organic transformations: net reductive dehalogenation of
phenacyl bromide and its derivatives, net oxidative hydroxylation
of arylboronic acids, and redox-neutral Îą-alkylation of aldehydes.
We show that the extended Ď-conjugation in Cz-POF-1 enhances
its visible light absorption, and the large porosity accelerates the
reaction rate. For Îą-alkylation of aldehydes, Cz-POF-1 requires
less strict reaction conditions and can be easily recovered and reused
for up to 10 times. This work reveals a bright future for Cz-POFs
as a new generation of metal-free photocatalysts for organic synthesis
Comparison Studies of Interfacial Electronic and Energetic Properties of LaAlO<sub>3</sub>/TiO<sub>2</sub> and TiO<sub>2</sub>/LaAlO<sub>3</sub> Heterostructures from First-Principles Calculations
By
using first-principles electronic structure calculations, we studied
electronic and energetic properties of perovskite oxide heterostructures
with different epitaxial growth order between anatase TiO<sub>2</sub> and LaAlO<sub>3</sub>. Two types of heterostructures, i.e., TiO<sub>2</sub> film grown on LaAlO<sub>3</sub> substrate (TiO<sub>2</sub>/LaAlO<sub>3</sub>) and LaAlO<sub>3</sub> film grown on TiO<sub>2</sub> substrate (LaAlO<sub>3</sub>/TiO<sub>2</sub>), were modeled. The
TiO<sub>2</sub>/LaAlO<sub>3</sub> model is intrinsically metallic
and thus does not exhibit an insulator-to-metal transition as TiO<sub>2</sub> film thickness increases; in contrast, the LaAlO<sub>3</sub>/TiO<sub>2</sub> model shows an insulator-to-metal transition as
the LaAlO<sub>3</sub> film thickness increases up to 4 unit cells.
The former model has a larger interfacial charge carrier density (<i>n</i> âź 10<sup>14</sup> cm<sup>â2</sup>) and smaller
electron effective mass (0.47<i>m</i><sub>e</sub>) than
the later one (<i>n</i> âź 10<sup>13</sup> cm<sup>â2</sup>, and 0.70<i>m</i><sub>e</sub>). The interfacial
energetics calculations indicate that the TiO<sub>2</sub>/LaAlO<sub>3</sub> model is energetically more favorable than the LaAlO<sub>3</sub>/TiO<sub>2</sub> model, and the former has a stronger interface
cohesion than the later model. This research provides fundamental
insights into the different interfacial electronic and energetic properties
of TiO<sub>2</sub>/LaAlO<sub>3</sub> and LaAlO<sub>3</sub>/TiO<sub>2</sub> heterostructures
Fine Tuning the Redox Potentials of Carbazolic Porous Organic Frameworks for Visible-Light Photoredox Catalytic Degradation of Lignin <i>β-</i>Oâ4 Models
We report a facile
approach to fine tune the redox potentials of
Ď-conjugated porous organic frameworks (POFs) by copolymerizing
carbazolic electron donor (D) and electron acceptor (A) based comonomers
at different ratios. The resulting carbazolic copolymers (CzCPs) exhibit
a wide range of redox potentials that are comparable to common transition-metal
complexes and are used in the stepwise photocatalytic degradation
of lignin β-O-4 models. With the strongest oxidative capability,
CzCP100 (D:A = 0:100) exhibits the highest efficiency for the oxidation
of benzylic β-O-4 alcohols, while the highly reductive CzCP33
(D:A = 66:33) gives the highest yield for the reductive cleavage of
β-O-4 ketones. CzCPs also exhibit excellent stability and recyclability
and represent a class of promising heterogeneous photocatalysts for
the production of fine chemicals from sustainable lignocellulosic
biomass
Advances in developing thermally conductive polymers
Polymers, with various advantages including lightweight, low cost, flexibility and ease of processing, are popular choices for thermal management in flexible electronics, photovoltaics, fuel cells, etc. In this perspective, we review the recent progress of developing uniaxial thermally conductive polymers and three-dimensional polymers with high thermal conductivity, discuss new opportunities in applying machine learning methods to search for thermally conductive polymers, and finally point out current key challenges and future directions in simulations and experimental measurements. The useful insights in this perspective can guide the rational design of thermally conductive polymers for advanced thermal management. This paper delineates the advantages and recent progress of pristine polymers with high thermal conductivity and provides significant insights on future directions in the simulations and experimental measurements of thermally conductive pristine polymers.</p
Metal-Free Electrocatalytic Aerobic Hydroxylation of Arylboronic Acids
Hydroxylation of
arylboronic acids to aryl alcohols was realized
by a scalable electrocatalytic method. The present electrochemical
hydroxylation employs low-cost methyl viologen as an organic cathodic
electrocatalyst and involves O<sub>2</sub> as a green and sustainable
reactant. The electrochemical kinetic studies shown here can be a
powerful tool to gain rich mechanistic and kinetic information and
thus an in-depth understanding of the electrocatalytic mechanism
An OrderâDisorder Transition in Surface Complexions and Its Influence on Crystal Growth of Boron-Rich Nanostructures
Controlled
fabrication of boron-rich nanostructures was achieved by manipulating
the processing temperature: high-temperature processing (1400â1500
°C) produced mainly tabular platelets with parallel twinning
cross sections, whereas low-temperature processing (1100â1200
°C) facilitated the growth of star-shaped nanowires with cyclic
twinning cross sections. This study revealed that this growth habit
transition was related to the structural order of the adsorbed Ba
atoms in nanoscale surficial films, which is a type of surface complexion
(stable equilibrium phase-like surface states). It is demonstrated
that an orderâdisorder transition in these surface complexions
can play a critical role in determining the growth habits of crystals
Tetranuclear Gadolinium(III) Porphyrin Complex as a Theranostic Agent for Multimodal Imaging and Photodynamic Therapy
We
describe herein the elaborate design of a GdÂ(III)âporphyrin
complex as a theranostic agent for multimodal imaging and photodynamic
therapy. Far-red-emitting (665 nm) and high relaxivity (14.1 mM<sup>â1</sup> s<sup>â1</sup>) with 107% increase upon binding to HSA (human
serum albumin) (29.2 mM<sup>â1</sup> s<sup>â1</sup>)
together with efficiently generating singlet oxygen upon exposure
to far-red light irradiation at 650 Âą 20 nm demonstrate that
this GdÂ(III)âporphyrin complex with four GdÂ(III)âDTTA
units bound to tetraphenylporphyrin acts as a potentially theranostic
agent with excellent performance for magnetic resonance imaging, optical
imaging, and photodynamic therapy
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