PBC@δ-MnO_(2)活化过硫酸盐降解孔雀石绿:非自由基机制

采用水热法制备了磷酸化黍糠基生物炭负载δ-MnO_(2)(PBC@δ-MnO_(2))纳米复合催化剂,利用SEM对催化剂进行表征,研究了其活化过二硫酸盐(PDS)降解孔雀石绿(MG)的效果及其去除机理。考察了初始pH、PDS浓度、PBC@δ-MnO_(2)投加量等反应条件对MG去除的影响。分析PBC@δ-MnO_(2)/PDS体系中的主要活性物质,推测该反应体系中可能的反应机制。结果表明,在PBC@δ-MnO_(2)/PDS体系中,随着初始pH、PDS浓度、PBC@δ-MnO_(2)投加量的升高,MG去除率也逐渐增大,当PBC@δ-MnO_(2)投加量为0.2 g/L,PDS浓度为0.5 mmol/L,初始pH为5时,MG的去除率可达到92.61%。自由基猝灭试验和EPR分析表明,单线态氧(^(1)O_(2))是PBC@δ-MnO_(2)/PDS体系中的主要活性物种,对MG的去除起主导作用。

生物炭负载硫化纳米零价铁活化过硫酸盐降解酸性大红GR的研究

麻黄草具有良好的比表面积和丰富的官能团,已被证实其产物具有优秀的吸附性能。纳米零价铁作为一种强反应性的过渡金属粒子,可以高效活化过硫酸盐并降解污染物。研究采用麻黄草作为原材料制备生物炭,负载硫化纳米零价铁活化过硫酸盐降解酸性大红GR。通过批次试验探究炭的烧制温度、铁的负载比、硫铁比、硫化时间、材料投加量、PS投加量、pH对S-nZVI@BC体系降解酸性大红GR的影响。结果表明,当条件设置为pH值5、烧制温度600℃、铁的负载比0.6、硫铁比1.0、硫化时间1 h、材料投加量0.2 g/L、PS投加量0.4 mmol/L时,反应60 min后S-nZVI@BC体系对酸性大红GR的降解率最高达85%。通过自由基淬灭试验可以确定,SO-4·是反应的主要活性物质。硫化对于纳米零价铁/过硫酸盐体系的降解效果虽无明显增益,但可以有效降低铁的逸出,降低二次污染。

Sensitivity and detection limit of dual-waveguide coupled microring resonator biosensors

We show that a linear relation exists between the device sensitivity and the quality （Q） factor of a dual- waveguide coupled microring resonator optical biosensor when the optimal conditions are satisfied. We also show that the detection limit depends on the loss coefficient and signal-to-nosie ratio （SNR） of the overall system, rather than the circumference of the ring. For a microring resonator sensor whose Q factor is 20000, the detection limit is found to be about 10-7 with 30-dB SNR, which is in good agreement with reported experimental data. These results indicate that loss reduction is the top priority in the design and fabrication of highly sensitive microring resonator optical biosensors.