Two-dimensional
(2D) layered MoSe2 has been demonstrated
to be a promising electrode material for new energy storage systems.
However, its nature of poor conductivity and the undesirable interlayer
spacing hinder its further application. In this paper, a general and
simple plasma-enhanced chemical vapor deposition method is proposed
to produce 2D heterolayer-structured MoSe2-carbon (MoSe2/C) with carbon atoms inserted in the MoSe2 layers.
After morphology optimization, when applying flat-type MoSe2/C-200 nanosheets with an enlarged interlayer spacing of 0.79 nm
as the anode and activated carbon as the cathode, the assembled sodium-ion
hybrid capacitors can reach a maximum energy/power density of 116.5
W h kg–1/107.5 W kg–1 and exhibit
superior cycling durability (91.3% capacitance retention after 4000
cycles at 1 A g–1). The good electrochemical property
can be ascribed to the enlarged interlayer spacing that can offer
fast diffusion channels for Na ions, and the carbon layer sandwiched
in the MoSe2 layer can not only enhance the electron transfer,
accelerating the reaction kinetics, but also alleviate the volume
change of MoSe2, ensuring the good stability of the electrode.
The proposed approach can also be extended to other 2D transition
metal chalcogenide (TMC) materials for constructing the TMC/C heterostructures
for the application in energy storage systems.
The corrosion mechanism of the low carbon low alloy steel with Al2O3 particles and rare earth (RE) oxide particles was compared in a simulated marine environment. It is shown that when the Al2O3-containing particles are introduced, the number density of nonmetallic particles of the steel increases twice, and the average particle size decreases from approximately 2.4 μm to 1.4 μm. With the introduction of Al2O3-containing particles, the amount of pitting corrosion increases. Furthermore, pitting corrosion occurs more uniformly owing to the fineness of the Al2O3 particles, thereby leading to smaller, shallower pits after the Al2O3 particles are shed. Hence, the corrosion performance of the steel with Al2O3 particles is significantly improved than that of the steel without Al2O3 particles. By adding RE oxide particles into steel, the nonmetallic particles in steel are refined but not as effectively as that achieved by adding the Al2O3-containing particles. Different from Al2O3 particles, Cu is obviously enriched in the location of RE oxide particles at the initial corrosion stage, which makes the steel exhibit the best corrosion resistance. Cu enrichment is attributed to the mobile Cu present in the rust layer and to the micro acid region formed around the RE oxide particles.
Fullerene‐like boron clusters (borofullerenes) are rising stars in the field of cluster chemistry. In this work, density functional theory calculations revealed that the recently reported small borofullerenes Bn (n = 28, 38, and 40) are all highly reactive and tend to form dimers and even trimers spontaneously. In addition, the non‐covalent modification of these borofullerenes by various cycloparaphenylene nanorings can form stable host‐guest systems with substantial intermolecular charge transfer at both ground and excited states. Our results demonstrate that the borofullerenes are versatile platform for exohedral functionalization, and are very promising candidates for the design of novel nanomaterials with desirable properties.
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