K_(2)FeO_(4)-FeCl_(3)联合强化剩余污泥厌氧消化产酸

通过碱性高铁酸钾(K_(2)FeO_(4))-FeCl_(3)预处理联合厌氧消化对剩余污泥进行减量化处理,探讨不同形态的铁源及不同铁浓度对以有机酸回收为目标的污泥减量化过程的影响,并寻找最适铁投加量.结果表明在预处理过程中碱性K_(2)FeO_(4)对污泥聚集体结构破坏起着重要作用.与空白相比,挥发性悬浮物固体(VSS)下降了26.79%,中值粒径(Dx(50))下降了90%,污泥沉降比(SV_(30))下降了33%,污泥沉降性能变好,减量效果明显.FeCl_(3)在预处理过程仅具有絮凝作用.在厌氧消化过程,经碱K_(2)FeO_(4)预处理后的污泥产酸量高于空白组.适量铁离子的增加可加速有机酸的产生速率.最适铁投加量20mg Fe/g VSS的K_(2)FeO_(4)及21mg Fe/g VSS的FeCl_(3)(即TFe投加量为41mg Fe/g VSS)的产酸效果最好,在消化第3d挥发性有机酸达到峰值(436.1mg COD/g VSS),是空白组峰值的4.45倍.当经过15d消化后,PO_(4)^(3-)-P去除率达69.8%,是仅投加K_(2)FeO_(4)预处理的2.03倍.此外,适量铁的投加还有利于产酸菌(Actinobacteria门和Chloroflexi门)富集,促进了厌氧消化产酸速率提升,而铁投加量高于48mg Fe/g VSS反而会抑制厌氧环境中产酸菌的活性.

基于K_(3)FeO_(4)负载的Fe-基载氧体反应性能模拟研究

本研究以密度泛函理论为基础,通过态密度、吸附能和活化能等电子结构性质,研究尖晶石结构的K_(3)FeO_(4)对Fe基载氧体反应性能的影响。结果表明,K_(3)FeO_(4)负载到α-Fe_(2)O_(3)(001)表面后,α-Fe_(2)O_(3)(001)表面微观电子结构发生改变,表面的Fe-O键长伸长,O-p轨道电子朝更高能级方向跃迁,氧原子电子活性提高。负载后,在三个晶格氧位处,CO与表面晶格氧反应的能垒均表现出降低趋势。这是因为负载K_(3)FeO_(4)能够提高表面氧原子活性,Fe-O键伸长使得断键更加容易,所需能量更小;此外,CO与K_(3)FeO_(4)中活性较强的氧原子成键,也与O_(2)位原子形成新的C−O键,以双齿碳酸盐形式吸附在表面α-Fe_(2)O_(3)(001),进而释放并生成CO_(2)。

微波碳化-K_(2)FeO_(4)活化制备生物炭及其对Cr^(6+)吸附性能

作者以柚子皮为原料,采用微波碳化-K_(2)FeO_(4)活化制备了磁性生物炭,对比了不同微波功率、不同炭化时间对磁性生物炭性能的影响。采用SEM、BET、XRD、XPS和FTIR对磁性生物炭进行表征,考察其对Cr^(6+)的吸附性能和机理。结果表明,与单纯微波碳化相比,微波碳化-K_(2)FeO_(4)活化增加了生物炭表面的含氧官能团,比表面积从3.08 m;/g提高到49.33 m;/g,且生成磁性γ-Fe_(2)O_(3)。磁性生物炭对水溶液中Cr^(6+)的吸附动力学和等温线分别符合准二级动力学方程和Langmuir吸附等温模型。在45 ℃的条件下,磁性生物炭对Cr^(6+)的最大吸附量为122.1 mg/g。

Effect of K_(2)CO_(3) doping on CO_(2) sorption performance of silicate lithium-based sorbent prepared from citric acid treated sediment

In this paper,a low-cost and environmental-friendly leaching agent citric acid(C_(6)H_(8)O_(7))was used to treat the sediment of Dianchi Lake(SDL)to synthesize lithium silicate(Li_(4)SiO_(4))based CO_(2)sorbent.The results were compared with that treated with strong acid.Moreover,the effects of preparation conditions,sorption conditions and desorption conditions on the CO_(2)sorption performance of prepared Li_(4)SiO_(4)were systematically studied.Under optimal conditions,the Li_(4)SiO_(4)sorbent was successfully synthesized and its CO_(2)sorption capacity reached 31.37%(mass),which is much higher than that synthesized from SDL treated with strong acid.It is speculated that the presence of some elements after C_(6)H_(8)O_(7)treatment may promote the sorption of synthetic Li_(4)SiO_(4)to CO_(2).In addition,after doping with K_(2)CO_(3),the CO_(2)uptake increases from the original 12.02%and 22.12%to 23.96%and 32.41%(mass)under the 20%and 50%CO_(2)partial pressure,respectively.More importantly,after doping K_(2)CO_(3),the synthesized Li_(4)SiO_(4)has a high cyclic stability under the low CO_(2)partial pressure.