Brilliant green

About: Brilliant green is a research topic. Over the lifetime, 627 publications have been published within this topic receiving 12495 citations.

Efficient Capture of Organic Dyes and Crystallographic Snapshots by a Highly Crystalline Amino-Acid-Derived Metal-Organic Framework.

Abstract: The presence of residual organic dyes in water resources or wastewater treatment systems, derived mainly from effluents of different industries, is a major environmental problem with no easy solution. Herein, an ecofriendly, water-stable metal-organic framework was prepared from a derivative of the natural amino acid l-serine. Its functional channels are densely decorated with highly flexible l-serine residues bearing hydroxyl groups. The presence of such a flexible and functional environment within the confined environment of the MOF leads to efficient removal of different organic dyes from water: Pyronin Y, Auramine O, Methylene Blue and Brilliant Green, as unveiled by unprecedented snapshots offered by single-crystal X-ray diffraction. This MOF enables highly efficient water remediation by capturing more than 90 % of dye content, even at very low concentrations such as 10 ppm, which is similar to those usually found in industrial wastewaters. Remarkably, the removal efficiency is improved in simulated contaminated mineral water with multiple dyes.

Removal of Brilliant Green dye from water by modified Bambusa Tulda : adsorption isotherm, kinetics and thermodynamics study

Abstract: The present research is based on the removal of Brilliant Green dye from synthetic wastewater which is one of the emerging hazardous contaminant. Adsorption technology was used to remove Brilliant Green dye using sodium carbonate-treated Bambusa Tulda as bio-adsorbent to replace costly activated carbon. Initial experiment shows the best removal of Brilliant Green dye done by sodium carbonate-treated Bambusa Tulda as compared to hydrochloric acid-treated Bambusa Tulda and distilled washed Bambusa Tulda. Scanning electron microscope, Fourier transform infrared spectroscopy and energy diffractions and X-ray analysis were done to identify functional group, surface characteristic and elemental constituents of sodium carbonate-treated Bambusa Tulda. The adsorption parameters have direct influence onto sodium carbonate-treated Bambusa Tulda for Brilliant Green dye removal. Optimum removal (98%) of dye was obtained at equilibrium time 60 min at pH 7, adsorbent dose 10 g/l, rotation per minute 200 and 298 K. Experimental data were fitted into four isotherm models and Langmuir isotherm best fitted with maximum adsorption capacity = 41.67 mg/g. Kinetics rate data fit better in pseudo-second-order model. Activation energy was observed as 16.802 kJ/mole, and the adsorption was diffusion control process. The chemical oxygen demand values of Brilliant Green dye decreased from 136 to 72 mg/l after the adsorption of Brilliant Green with sodium carbonate-treated Bambusa Tulda. Thus, it can be concluded that sodium carbonate-treated Bambusa Tulda is an efficient adsorbent and an alternative to activated carbon for the removal of Brilliant Green dye from synthetic wastewater.

Decolorization of Textile Dyes by Wet Oxidation Using Activated Carbon as Catalyst

Abstract: A commercial activated carbon, Industrial React FE01606A, without impregnation of any metal, was used as a catalyst in the wet oxidation of three dyes commonly found in textile wastewaters, Orange G, Methylene Blue, and Brilliant Green Runs were carried out in a three phase fixed-bed reactor by feeding concurrently an aqueous phase containing 1000 mg/L of the dye and an oxygen gas flow rate of 90 mL/min Temperature was set to 160 °C, and the pressure in the reactor was fixed to 16 bar The catalyst showed high catalytic activity in dye conversion and color removal The catalyst kept stable during the time tested on stream (200 h) Total decolorization is obtained at short residence times, but some refractory organic intermediates are obtained (mineralization achieved an asymptotic value about 40-60% depending on the dye) The toxicity of the inlet and outlet effluent was measured by the Microtox bioassay, and the oxidation intermediates identified and quantified explained the obtained toxicity evolution

Adsorption of Brilliant Green Dye on Biochar Prepared From Lignocellulosic Bioethanol Plant Waste

Abstract: This study was aimed at the adsorption of Brilliant Green (BG) on hydrolyzed rice straw biochar, which was obtained from a lignocellulosic bioethanol process. Rice straw biochar (RBC) possessed surface properties such as a Brunauer–Emmett–Teller (BET) surface area of 232.31 m2/g, a total pore volume of 0.30 cm3/g, and an average pore width of 5.22 nm. Adsorption studies were carried out to investigate the effect of experimental factors such as pH (2–10), biochar dose (0.05–1.25 g/L), contact time (30–480 min), and temperature (30 to −50°C) on the adsorption of BG. The Langmuir isotherm (R2 = 0.998) fitted well to the adsorption data for initial dye concentrations of 20–500 mg/L, implying that BG adsorption occurred in the form of a monolayer on RBC. Adsorption kinetics was well fitted by the pseudo-second order kinetic model (R2 ≥ 0.988) for all tested dye concentrations. The thermodynamic study revealed that BG adsorption on RBC was spontaneous, favorable, and a physical process. The maximum adsorption capacity of RBC was found to be 111.11 mg/g. These results showed that RBC, prepared from the waste of the bioethanol process, can be effectively used as a promising cheap adsorbent to remove dyes from aqueous solution. This approach of product diversification (bioethanol along with biochar) may lead to a cost effective and cleaner production of bioethanol.