Daniel K. Macharia scite author profile

Nanostructured photothermal membranes hold great potential for solar-driven seawater desalination; however, their pragmatic applications are often limited by substantial salt accumulation. To solve this issue, we have designed and prepared flexible and washable carbon-nanotube-embedded polyacrylonitrile nonwoven fabrics by a simple electrospinning route. The wet fabric exhibits a strong photoabsorption in a wide spectral range (350–2500 nm), and it has a photoabsorption efficiency of 90.8%. When coated onto a polystyrene foam, the fabric shows a high seawater evaporation rate of 1.44 kg m–2 h–1 under simulated sunlight irradiation (1.0 kW m–2). With a high concentration of simulated seawater as the model, the accumulation of solid salts can be clearly observed on the surface of the fabric, resulting in a severe decay of the evaporation rate. These salts can be effortlessly washed away from the fabric through a plain handwashing process. The washing process has a negligible influence on the morphology, photoabsorption, and evaporation performance of the fabric, demonstrating good durability. More importantly, a larger fabric can easily be fabricated, and the combination of washable fabrics with various parallel PS foams can facilitate the construction of large-scale outdoor evaporation devices, conferring the great potential for efficient desalination of seawater under natural sunlight.

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Recyclable CNT-coupled cotton fabrics for low-cost and efficient desalination of seawater under sunlight

Kou

et al. 2019

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Effect of dye structure on color removal efficiency by coagulation

Mcyotto

Wei

Macharia

et al. 2021

Chemical Engineering Journal

230

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UV/NIR-Light-Triggered Rapid and Reversible Color Switching for Rewritable Smart Fabrics

Macharia

Ahmed

Zhu

et al. 2019

ACS Appl. Mater. Interfaces

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Remote, rapid, and ink-free printing/erasure on fabrics has great potential to revolutionize specialized clothing in numerous applications including fashion/aesthetic and security fields, but the construction of such smart fabrics has not been realized due to underlying obstacles in obtaining suitable photoreversible color-switching systems (PCSS). To address this problem, we have prepared TiO2–x nanorods as photocatalytic and photothermal component. With redox dyes as reversible color indicators and hydroxyethyl cellulose (HEC) as polymer matrix, TiO2–x /dye/HEC-based PCSS is coated on poly(dimethylsiloxane)-treated cotton fabric. Under 365 nm light irradiation, discoloration occurs in 180 s, resulting from the efficient photocatalytic reduction of the dye. On the contrary, when the colorless fabric is irradiated by 808 nm light, recoloration occurs in a very short time (∼100 s), far lower than the traditional heating mode (30–8 min at 90–150 °C). This rapid recoloration should be attributed to the localized high temperature (164.3–184.5 °C) induced by photothermal effect of TiO2–x . Particularly, when TiO2–x /dye/HEC-based PCSS is extended to coat commercial clothes (such as T-shirts), red/green/blue figures/letters can be rapidly and remotely printed by UV-light pen and then erased by near-infrared light, with high cycle stability. Therefore, such rewritable smart fabric represents an attractive alternative to regular clothes in meeting the increasing aesthetic or camouflage needs.

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MOF-derived CuS@Cu-MOF nanocomposites for synergistic photothermal-chemodynamic-chemo therapy

Geng

Macharia

et al. 2022

Chemical Engineering Journal

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