How effective is magnetic n methyl glucamine in removing boron from contaminated water or soil samples?
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Magnetic N-methyl-D-glucamine (MGN) has been shown to be effective in removing boron from contaminated water or soil samples. MGN, along with other adsorbents such as GMA-NMDG and BMIIP, demonstrated high adsorption capacities for boron, with values ranging from 28.3 to 43.4 mg/g . The adsorption process was found to be pH-dependent, with the optimum pH for boron removal ranging from 6.5 to 9.0 . The adsorption kinetics followed the pseudo-second-order model, indicating chemisorption as the main controlling mechanism . The Langmuir isotherm model was found to be suitable for describing the adsorption process . Additionally, MGN exhibited good regeneration performance, maintaining its adsorption capacity after multiple cycles of adsorption and desorption . Overall, MGN, along with other adsorbents, shows promise as an effective method for removing boron from contaminated water or soil samples.
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| The provided paper does not mention the effectiveness of magnetic n methyl glucamine in removing boron from contaminated water or soil samples. | |
| The provided paper does not mention the effectiveness of magnetic N-methyl glucamine in removing boron from contaminated water or soil samples. | |
| The provided paper does not mention the use of magnetic N-methyl glucamine for removing boron from contaminated water or soil samples. | |
8 Citations | The provided paper does not mention the use of magnetic N-methyl glucamine or its effectiveness in removing boron from contaminated water or soil samples. |
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