Tang Xin Ting scite author profile

Industrial operations, domestic and agricultural activities worldwide have had major problems with various contaminants caused by environmental pollution. Heavy metal pollution in wastewater also a prominent issue; therefore, a well built and economical treatment technology is demanded for pollution-free wastewater. The present work emphasized pure cellulose extracted from jute fiber and further modification was performed by a free radical grafting reaction, which resulted in poly(methyl acrylate) (PMA)-grafted cellulose and poly(acrylonitrile)-grafted cellulose. Subsequently, poly(hydroxamic acid) and poly(amidoxime) ligands were prepared from the PMA-grafted cellulose and PAN-grafted cellulose, respectively. An adsorption study was performed using the desired ligands with heavy metals such as copper, cobalt, chromium and nickel ions. The binding capacity (qe) with copper ions for poly(hydroxamic acid) is 352 mg g−1 whereas qe for poly(amidoxime) ligand it was exhibited as 310 mg g−1. Other metal ions (chromium, cobalt and nickel) show significance binding properties at pH 6. The Langmuir and Freundlich isotherm study was also performed. The Freundlich isotherm model showed good correlation coefficients for all metal ions, indicating that multiple-layers adsorption was occurred by the polymer ligands. The reusability was evaluated and the adsorbents can be reused for 7 cycles without significant loss of removal performance. Both ligands showed outstanding metals removal capacity from the industrial wastewater as such 98% of copper can be removed from electroplating wastewater and other metals (cobalt, chromium, nickel and lead) can also be removed up to 90%.

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Highly Active Cellulose-Supported Poly(hydroxamic acid)–Cu(II) Complex for Ullmann Etherification

Fui

Ting

Sarjadi

et al. 2021

ACS Omega

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Highly active natural pandanus-extracted cellulose-supported poly(hydroxamic acid)–Cu(II) complex 4 was synthesized. The surface of pandanus cellulose was modified through graft copolymerization using purified methyl acrylate as a monomer. Then, copolymer methyl acrylate was converted into a bidentate chelating ligand poly(hydroxamic acid) via a Loosen rearrangement in the presence of an aqueous solution of hydroxylamine. Finally, copper species were incorporated into poly(hydroxamic acid) via the adsorption process. Cu(II) complex 4 was fully characterized by Fourier transform infrared (FTIR), field emission scanning electron microscopy (FE-SEM), energy-dispersive X-ray (EDX), transmission electron microscopy (TEM), inductively coupled plasma optical emission spectrometry (ICP-OES), thermogravimetric analysis (TGA), X-ray diffraction (XRD), and X-ray photoelectron spectroscopy (XPS) analyses. The cellulose-supported Cu(II) complex 4 was successfully applied (0.005 mol %) to the Ullmann etherification of aryl, benzyl halides, and phenacyl bromide with a number of aromatic phenols to provide the corresponding ethers with excellent yield [benzyl halide (70–99%); aryl halide (20–90%)]. Cu(II) complex 4 showed high stability and was easily recovered from the reaction mixture. It could be reused up to seven times without loss of its original catalytic activity. Therefore, Cu(II) complex 4 can be commercially utilized for the preparation of various ethers, and this synthetic technique could be a part in the synthesis of natural products and medicinal compounds.

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Bio-heterogeneous Cu(0)NC@PHA for n-aryl/alkylation at room temperature

et al. 2021

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Influences of Central Units and Terminal Chains on the Banana-Shaped Liquid Crystals

2020

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Azo-functionalized materials are one of the appealing groups of the functionalized materials owing to their photoswitching behaviour and have been explored for various potential applications viz., optical data storage, sensor, display devices, nonlinear materials and molecular switches. Recently, azo-functionalized bent-core liquid crystals (BCLCs) have gained significant attention because they have dual properties of BCLCs and azobenzene, which enables to generate new multifaceted functional and smart materials. In this report, the recently synthesized azobenzene containing bent-core mesogens and its subclass, the so-called hockey stick and V-shaped molecules are summarized. The mesomorphic behaviour of reported BCLCs affected by the type of central core unit, the nature, number and position of the lateral substituents and the type and length of the terminal chain are discussed. The photoisomerization process of these photoresponsive BCLCs in solid, solution and mesophase, as well as the impact of light on the chemical and electrical properties of them, are discussed.

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Waste fiber-based cellulose supported polymer ligands for toxic metals removal from industrial wastewater

Rahman

Fui

Ting

et al. 2020

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Toxic metals pollution in the wastewater is a drastic situation hence a powerful and economical treatment technology is needed for the water purification. For that reason some pure cellulosic materials were extracted from waste fiber and further modification of the cellulose was performed by free radical grafting reaction resulting the poly (methyl acrylate)-grafted cellulose and poly(acrylonitrile)-grafted cellulose. Consequently, poly (hydroxamic acid) and poly (amidoxime) ligands were prepared from the grafted cellulose. The adsorption capacity (qe)of some toxic metals ions with the polymer ligands was found excellent, e.g. copper capacity (qe) for poly (hydroxamic acid) is 375 mg/g whereas qe for poly (amidoxime) ligand is 355 mg/g at pH 6. Other metal ions (iron, chromium, cobalt, zinc and nickel) show significance binding properties at pH 6. The Langmuir and Freundlich isotherm studies were also performed and Freundlich isotherm model showed good correlation coefficients for all metal ions, indicating that multiple-layers adsorption occurred. The both polymeric ligands showed outstanding toxic metals removal magnitude, up to 90-98% of toxic metal ions can be removed from industrial wastewater.

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Tang Xin Ting

Polymer Ligands Derived from Jute Fiber for Heavy Metal Removal from Electroplating Wastewater

Highly Active Cellulose-Supported Poly(hydroxamic acid)–Cu(II) Complex for Ullmann Etherification

Bio-heterogeneous Cu(0)NC@PHA for n-aryl/alkylation at room temperature

Influences of Central Units and Terminal Chains on the Banana-Shaped Liquid Crystals

Waste fiber-based cellulose supported polymer ligands for toxic metals removal from industrial wastewater

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