Superhydrophobic conjugated microporous polymers show good selectivity, fast adsorption kinetics, excellent recyclability and absorbencies for a wide range of organic solvents and oils, which make them the promising candidates for potential applications, including liquid-liquid separation, water treatment and so on.Superhydrophobic surfaces (water contact angle (CA) larger than 150 ) have generated extensive commercial and academic interest. [1][2][3][4][5][6][7] In recent years, there has been an increased interest in generation and utilization of the surface superhydrophobicity of a solid for direct separation or selective adsorption of oil or hydrophobic organic solvents from water. The first example for oil-water separation by using superhydrophobic and superoleophilic coating mesh has been reported by Jiang et al. 8 Along this line, more recently, the creation of nanometre-or micrometre-sized porous materials with excellent surface superhydrophobicity has been reported and successfully used for separation and adsorption of oils or organic solvents from water. For example, Yuan et al. reported the selective adsorption of oil from water by a superwetting nanowire membrane. 9 Similar selective adsorption performance has also been reported by Zhang et al. using superhydrophobic nanoporous polydivinylbenzene. 10 Due to their excellent selective adsorption performance, fast adsorption kinetics, good working capacity and recyclable use performance, these materials have great advantages over those traditional absorbent materials such as active carbons, 11,12 which suffer from a number of drawbacks, including slow adsorption kinetics, poor selectivity and limited working capacity. Owing to the global scale of severe water pollution arising from oil spills and industrial organic pollutants, the creation of efficient absorbent materials for separation and removal of oils or organic pollutants from water should be of great importance to address environmental issues. Broader contextOwing to the global scale of severe water pollution arising from oil spills and industrial organic pollutants, the creation of efficient absorbent materials for separation and removal of oils or organic pollutants from water should be of great importance to address environmental issues. Here we report for the first time the surface superhydrophobicity of the conjugated microporous polymers (CMP) as well as their excellent adsorption performance for oils and organic solvents. Due to their open pore structures and excellent surface superhydrophobicity, oils or non-polar organic solvents can be easily absorbed and separated from water by the CMP without adsorption of water. The CMP also show excellent adsorption performance for those polar organic solvents and toxic organic solvents with the absorbencies ranging approximately from 700 wt% to 1500 wt% for the HCMP-1 and 600 wt% to 2300 wt% for the HCMP-2, respectively. By loading the CMP, the hydrophilic sponge can be changed to be oleophilic to oil. With a loading of 7.0 mg cm À3 of the HCMP-1 ...
Modulating the crystal field environment
around the emitting ions
is an effective strategy to improve the luminescence performance of
the practical effective phosphor materials. Here, smaller Y3+ ions are introduced into substituting the Gd3+ sites
in Ba2GdNbO6:Mn4+ phosphor to modify
the optical properties, including the enhanced luminescence intensity,
redshift, and longer lifetime of the Mn4+ ions. The substitution
of smaller Y3+ ions leads to lattice contraction and then
strengthens pressure on the local structure, enhances lattice rigidity,
and suppresses nonradiative transition. Moreover, the prototype phosphor-converted
light-emitting diode (LED) demonstrates a continuous change photoelectric
performance with a correlated color temperature of 4883–7876
K and a color rendering index of 64.1–83.2, suggesting that
it can be one of the most prospective fluorescent materials applied
as a warm red component for white LEDss. Thus, the smaller ion partial
substitution can provide a concise approach to modulate the crystal
field environment around the emitting ions for excellent luminescence
properties of phosphors toward the modern artificial light.
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