We achieved a dense IO hybrid superhydrophobic porous coordination polymer (PCP), [Pb(H-BTMB)(DMF)] (1), by solvothermal methods. The single-crystal XRD structure of 1 indicated that it has a three-dimensional M-L-M framework with one-dimensional M-O-M connectivity leading to an IO network. The new PCP obtained exhibited open metal sites (OMSs) by losing a coordinated DMF molecule. The degassed phase displayed selective adsorption of CO gas over N, CH, and CH gases. Additionally, it has a superhydrophobic surface with a contact angle of 156.4° at room temperature and it is stable even at 90 °C, displaying a contact angle of 135.3°.
We demonstrate a
new de novo synthetic methodology
to achieve high-temperature-stable compelled composite superhydrophobic
porous coordination polymers (PCPs). These new PCPs were achieved
based on coordination capabilities of first-row transition metal ions
such as Co2+, Ni2+, and Zn2+. The
obtained composite PCPs containing a [Zn2M2O]6+ (M = Co or Ni) bimetallic cluster core with open metal sites
(OMSs) exhibited distinct isosteric heats of adsorption and surface
areas due to the difference in their open metal Lewis acidic sites
of solvent-free state. Additionally, these composite PCPs exhibit
remarkable superhydrophobic properties with contact angles of 159.3°
and 160.8° respectively for Zn–Co and Zn–Ni analogues.
This superhydrophobic surface survives even at high temperature for
longer time periods. As projected, these new composite PCPs exhibit
better surface area and heats of adsorption compared to the PESD-1
(Zn) analogue due to a larger number of OMSs. Moreover, they display
selective adsorption toward aromatic solvents such as benzene and
toluene over aliphatic solvents such as cyclohexane due to corrugated
and terminated aromatic hydrocarbon moieties toward the interactive
surface. They also exhibit oil spill cleanup from the water surface
in the powder form as well as pellet form up to 385 wt %. This study
certainly offers a roadmap for designing and engineering new composite
superhydrophobic porous materials for better water and thermal stability
along with OMSs. This type of PCP exhibits a wide range of applications
especially in catalysis, separation technology, and securing environmental
problems such as oil spill cleanup in seawater.
Synthesis, characterization, and antibacterial active studies of 12 coumarin derivatives were described in this study. Synthesis was achieved by the reaction of 4‐carbonyl chloride with 1,2‐dichloroethane as a solvent, in moderate to good yields. The structures of all the newly synthesized molecules were assigned by spectral data and elemental analysis. The synthesized compounds were screened for their antibacterial activities strains using paper disc method.
We prepared two new superhydrophobic functionalized coordination
polymers (SFCPs) [Zn4(OH)2(BTMB)2(4,4′-Bipy)2]∞ ⊃ solvent, 1, and [Cd4(OH)2(BTMB)2(4,4′-Bipy)3]∞ ⊃ solvent, 2, by
solvothermal methods. For 1, the single-crystal XRD structure
revealed that it contains two crystallographically distinct Zn
2+
ions with two different types
of coordination geometries of 4 and 6, exhibiting
a unique superhydrophobic behavior with microporosity. Compound 1 exhibits superhydrophobicity with a contact angle of 155.5°
(at 30 °C), which is stable even at high temperatures, whereas
for the SFCP 2, all of the Cd
2+
ions have only 6-coordination and exhibit a superhydrophobic
character at room temperature with a contact angle of 156.7°(at
30 °C). However, surprisingly, this superhydrophobic character
is stable only up to 60 °C, above which it is converted to hydrophilic
nature, in contrast to the SFCP 1. Moreover, in this
study, we also report a selective gas adsorption study of two C2 gases
with similar kinetic diameters (∼3.9 Å) of ethylene over
ethane.
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