Sustainable hydrochar as an efficient persulfate activator for cost-effective degradation of bisphenol A.

Chemosphere Pub Date : 2024-09-01 Epub Date: 2024-09-03 DOI:10.1016/j.chemosphere.2024.143262

Xian Zhang, Ze Liu, Hafiz Ihsan Ul Haq Khan, Diederik P L Rousseau, Stijn Van Hulle

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Abstract

This study explored Mason pine-derived hydrochar (MPHC) as an effective adsorbent and persulfate (PS) activator for degrading bisphenol A (BPA). Increasing MPHC dosage from 0.25 to 2.0 g L^-1 raised BPA removal from 42% to 87%. Similarly, at the same MPHC dosage range and fixed PS concentration (8 mM), BPA removal by MPHC/PS increased from 66% to 91%. Additionally, at a fixed MPHC dosage (1.0 g L^-1), higher PS concentrations (2-32 mM) resulted in an overall BPA removal increase from 78% to 99%. The optimal pH for BPA removal by MPHC was at pH 3, while for MPHC/PS was at pH 9. BPA degradation by MPHC was optimal at pH 3, whereas MPHC/PS was at pH 3 and pH 9. Additionally, pH 7 favored BPA adsorption for both MPHC and MPHC/PS. The study also considered the influence of coexisting anions and humic acid (HA). PO₄^3- and NO₃^- influence adsorption on MPHC, but these anions' effect on MPHC/PS is limited. Furthermore, the existence of HA had minimal influence on BPA removal by MPHC/PS. The contributions of different reactive species by MPHC for BPA degradation are as follows: electron-hole (h⁺) 2%, singlet oxygen (¹O₂) 7%, superoxide radicals (O₂^•-) 13%, electron (e^-) 2%, hydroxyl radical (^•OH) 3%, whereas the remaining 48% removal was the contribution of adsorption. For MPHC/PS, adsorption accounted for 39 %, more reactive species were involved in degradation, and the donations are (h⁺) 3%, sulfate radicals (SO₄^•-) 3%, (¹O₂) 19%, (O₂^•-) 15%, (e^-) 2%, and (^•OH) 2%. Additionally, the performance of MPHC remains stable after three operational cycles. The preparation cost of MPHC is 3.01 € kg^-1. These results highlight the potential of MPHC as an environmentally friendly material for activating PS and removing organic pollutants, suggesting its promising application in future environmental remediation efforts.

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可持续炭化氢作为一种高效的过硫酸盐活化剂，可经济有效地降解双酚 A。

本研究探讨了梅森松衍生炭（MPHC）作为一种有效的吸附剂和过硫酸盐（PS）活化剂降解双酚 A（BPA）的问题。将 MPHC 的用量从 0.25 g L-1 提高到 2.0 g L-1，双酚 A 的去除率从 42% 提高到 87%。同样，在相同的 MPHC 用量范围和固定的 PS 浓度（8 mM）下，MPHC/PS 对双酚 A 的去除率从 66% 提高到 91%。此外，在固定的 MPHC 用量（1.0 g L-1）和较高的 PS 浓度（2 至 32 mM）条件下，双酚 A 的总体去除率从 78% 提高到 99%。MPHC 去除双酚 A 的最佳 pH 值为 pH 值 3，而 MPHC/PS 的最佳 pH 值为 pH 值 9。此外，pH 值 7 对 MPHC 和 MPHC/PS 的双酚 A 吸附均有利。研究还考虑了共存阴离子和腐殖酸（HA）的影响。PO43- 和 NO3- 会影响对 MPHC 的吸附，但这些阴离子对 MPHC/PS 的影响有限。此外，HA 的存在对 MPHC/PS 去除双酚 A 的影响微乎其微。不同活性物种对 MPHC 降解双酚 A 的贡献如下：电子-空穴（h+）2%、单线态氧（1O2）7%、超氧自由基（O2--）13%、电子（e-）2%、羟自由基（-OH）3%，而其余 48% 的去除率是吸附的贡献。对于 MPHC/PS，吸附作用占 39%，更多的反应物参与了降解，其贡献率分别为（h+）3%、硫酸根（SO4--）3%、（1O2）19%、（O2--）15%、（e-）2% 和（-OH）2%。此外，MPHC 的性能在三个运行周期后保持稳定。MPHC 的制备成本为 3.01 欧元 kg-1。这些结果凸显了 MPHC 作为一种环境友好型材料在活化 PS 和去除有机污染物方面的潜力，表明其在未来的环境修复工作中具有广阔的应用前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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