Low concentration alcohols produced by state-of-theart biological fermentation restrict subsequent purification processes for chemical, pharmaceutical, biofuel, and other applications. Herein, a rarely reported cucurbituril[n] (n = 6, 8) is employed to pattern the thin-film composite membranes with controllable and quantifiable nanostrand structures through a host−guest strategy. The resulting nanofiltration membrane with such morphology is the first report that exhibits excellent separation performance for isopropyl alcohol (IPA) and water, condensing the initial 0.5 wt % IPA aqueous solution to 9.0 wt %. This not only provides a novel strategy for patterning nanostructural morphology but also makes nanofiltration membranes promising for alcohol condensation in the biological fermentation industry that may reduce energy consumption and postprocessing costs.
This
paper reveals the chemical, structural, and separation stability
of stacked molybdenum disulfide (MoS2) membranes and establishes
a low-cost and facile approach to developing stable, selective membranes
for efficient molecular separation in an organic solvent. MoS2 nanoflakes that were dominant by monolayer MoS2 sheets as prepared via direct chemical exfoliation (chem-MoS2) were found to be chemically and structurally instable, with
a sharp decrease in the level of solute rejection within a few days.
Few-layer MoS2 nanoflakes were then fabricated using a
hydrothermal method (hydro-MoS2). A “supportive”
drying process involving glycerol pretreatment and drying in an oven
was established to allow realignment of nanoflakes and adjustment
of interflake spacing. We have shown that the hydro-MoS2 membranes provide a mean interflake free spacing of ∼1 nm,
which is ideal for the separation of a model solute (Rose Bengal,
size of ∼1.45 nm) from the solvent isopropanol (size of 0.58
nm) with good long-term stability over a 7 day test.
The practical application of Li–S batteries is seriously hindered by intricate lithium polysulfide shuttling and sluggish electrochemical conversion kinetics. Separator modification has been demonstrated as an effective strategy to solve...
Molecular desalination is broadly used in chemical, food, and textile industries, which needs efficient and anti‐fouling separation technologies to reach this goal. Interfacial polymerization is one of the most promising routes to construct ultrahigh selective nanofiltration membranes. However, the irreversible hydrolysis of residual acyl chlorides makes Donnan charges of nascent films distribute unevenly which hinders fine molecular desalination and anti‐fouling. Here, we propose a pioneering solvation‐amination‐synergy strategy to synchronously inhibit the hydrolysis of residual acyl chlorides and promote their amination. The electroneutral nanofiltration membrane with high water permeance (13.2 L m−2 h−1 bar−1) is quantitatively fabricated that has superb anti‐fouling abilities and minimizes Donnan impacts on competitive ion penetrations, so it transmits Na2SO4 and NaCl while fully obstructs cationic or anionic dyes (< 500 Da). The ultrahigh molecule to ion selectivities outperform state‐of‐art nanofiltration membranes, which may provide a paradigm shift for scalable membrane fabrication for various industrial product desalination.
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