2D perovskites have recently been shown to exhibit significantly improved environmental stability. Derived from their 3D analogues, 2D perovskites are formed by inserting bulky alkylammonium cations in‐between the anionic layers. However, these insulating organic spacer cations also hinder charge transport. Herein, such a 2D perovskite, (iso‐BA)2(MA)3Pb4I13, that contains short branched‐chain spacer cations (iso‐BA+) and shows a remarkable increase of optical absorption and crystallinity in comparison to the conventional linear one, n‐BA+, is designed. After applying the hot‐casting (HC) technique, all these properties are further improved. The HC (iso‐BA)2(MA)3Pb4I13 sample exhibits the best ambient stability by maintaining its initial optical absorption after storage of 840 h in an environmental chamber at 20 °C with a relative humidity of 60% without encapsulation. More importantly, the out‐of‐plane crystal orientation of (iso‐BA)2(MA)3Pb4I13 film is notably enhanced, which increases cross‐plane charge mobility. As a result, the highest power conversion efficiencies (PCEs) measured from for current density versus voltage curves afford 8.82% and 10.63% for room‐temperature and HC‐processed 2D perovskites based planar solar cells, respectively. However, the corresponding steady‐state PCEs are remarkably lower, which is presumably due to the significant hysteresis phenomena caused by low charge extraction efficiency at interfaces of C60/2D perovskites.
Electrocatalytic water oxidation using the oxidatively robust 2,7-[bis(2-pyridylmethyl)aminomethyl]-1,8-naphthyridine ligand (BPMAN)-based dinuclear copper(II) complex, [Cu2(BPMAN)(μ-OH)](3+), has been investigated. This catalyst exhibits high reactivity and stability towards water oxidation in neutral aqueous solutions. DFT calculations suggest that the O-O bond formation takes place by an intramolecular direct coupling mechanism rather than by a nucleophilic attack of water on the high-oxidation-state Cu(IV)=O moiety.
Water oxidation is the key step in natural and artificial photosynthesis for solar-energy conversion. As this process is thermodynamically unfavorable and is challenging from a kinetic point of view, the development of highly efficient catalysts with low energy cost is a subject of fundamental significance. Herein, we report on iron-based films as highly efficient water-oxidation catalysts. The films can be quickly deposited onto electrodes from Fe(II) ions in acetate buffer at pH 7.0 by simple cyclic voltammetry. The extremely low iron loading on the electrodes is critical for improved atom efficiency for catalysis. Our results showed that this film could catalyze water oxidation in neutral phosphate solution with a turnover frequency (TOF) of 756 h(-1) at an applied overpotential of 530 mV. The significance of this approach includes the use of earth-abundant iron, the fast and simple method for catalyst preparation, the low catalyst loading, and the large TOF for O2 evolution in neutral aqueous media.
Water oxidation is the key step in both natural and artificial photosynthesis to capture solar energy for fuel production. The design of highly efficient and stable molecular catalysts for water oxidation based on nonprecious metals is still a great challenge. In this article, the electrocatalytic oxidation of water by Na[(L)Co], where L is a substituted tetraamido macrocyclic ligand, was investigated in aqueous solution (pH 7.0). We found that Na[(L)Co] is a stable and efficient homogeneous catalyst for electrocatalytic water oxidation with 380 mV onset overpotential in 0.1 M phosphate buffer (pH 7.0). Both ligand- and metal-centered redox features are involved in the catalytic cycle. In this cycle, Na[(L)Co] was first oxidized to [(L)CoOH] via a ligand-centered proton-coupled electron transfer process in the presence of water. After further losing an electron and a proton, the resting state, [(L)CoOH], was converted to [(L)Co═O]. Density functional theory (DFT) calculations at the B3LYP-D3(BJ)/6-311++G(2df,2p)//B3LYP/6-31+G(d,p) level of theory confirmed the proposed catalytic cycle. According to both experimental and DFT results, phosphate-assisted water nucleophilic attack to [(L)Co═O] played a key role in O-O bond formation.
Photocatalytic conversion of CO2 to reduced carbon states
using sunlight and an earth-abundant catalyst could provide a critically
needed source of renewable energy. Very few earth-abundant catalysts
have shown CO2 to CH4 reactivity, and significant
opportunities exist to improve catalyst durability. Through the strategic
design of a novel, redox-active bipyridyl-N-heterocyclic
carbene macrocyclic ligand complexed with nickel, CO2 is
converted into the energy-rich solar fuel, CH4, photocatalytically
with a photosensitizer in the presence of water. Up to 19 000
turnovers of CH4 from CO2 are observed. An exceptional
turnover number of 570 000 for CH4 production via
a photodriven formal hydrogenation of CO to CH4 was also
found. This unique reactivity from a tunable, highly durable macrocyclic
framework was studied via a series of photocatalytic and electrocatalytic
reactions varying the atmospheric composition, as well as by isotopic
labeling experiments and quantum yield calculations to evaluate the
effect of ligand structure on product generation.
This review covers all aspects of 9-borafluorene chemistry, from the first attempted synthesis in 1960 to the present. This class of molecules consists of a tricyclic system featuring a central antiaromatic BC 4 ring with two fused arene groups. The synthetic routes to all 9-borafluorenes and their adducts are presented. The Lewis acidity and photophysical properties outlined demonstrate potential utility as sensors and in electronic materials. The reactivity of borafluorenes reveals their prospects as reagents for the synthesis of other boron-containing molecules. The appealing traits of 9-borafluorenes have stimulated investigations into analogues that bear different aromatic groups fused to the central BC 4 ring. Finally, we offer our views on the challenges and future of borafluorene chemistry.
A series of nickel complexes featuring redox-active macrocycles is reported for electrocatalytic CO2 reduction. A remarkable structure-activity relationship is elucidated from the series through electrochemical studies and DFT calculations, wherein a fine electronic balance between metal and ligand redox chemistry dictates selectivity for CO2 reduction versus the competing proton reduction reaction.
Simply mixing a Cu(II) salt and 1,2-ethylenediamine
(en) affords
precursors for both heterogeneous or homogeneous water oxidation catalysis,
depending on pH. In phosphate buffer at pH 12, the Cu(II) en complex
formed in solution is decomposed to give a phosphate-incorporated
CuO/Cu(OH)2 film on oxide electrodes that catalyzes water
oxidation. A current density of 1 mA/cm2 was obtained at
an overpotential of 540 mV, a significant enhancement compared to
other Cu-based surface catalysts. The results of electrolysis studies
suggest that the solution en complex decomposes by en oxidation to
glyoxal, following Cu(II) oxidation to Cu(III). At pH 8, the catalysis
shifts from heterogeneous to homogeneous with a single-site mechanism
for Cu(II)/en complexes in solution. A further decrease in pH to 7
leads to electrode passivation via the formation of a Cu(II) phosphate
film during electrolyses. As the pH is decreased, en, with pK
b ≈ 6.7, becomes less coordinating and
the precipitation of the Cu(II) film inhibits water oxidation. The
Cu(II)-based reactivity toward water oxidation is shared by Cu(II)
complexation to the analogous 1,3-propylenediamine (pn) ligand over
a wide pH range.
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