改性生物炭负载纳米零价铁活化过硫酸盐降解活性蓝19的机理及老化研究

采用磷酸改性的黍糠基生物炭作为纳米零价铁(Nanoscale zero-valent iron,nZVI)载体,成功制备出一种高效非均相活化材料一磷酸改性生物炭负载纳米零价铁(nZVI@PBC),用来活化过硫酸盐(Persulfate,PS)降解印染废水中的典型染料—活性蓝(Reactive Blue 19,RB19)...     

3种生物质炭对活性艳蓝KN-R的吸附简

选择由玉米秸秆、稻壳和稻草秸秆在825℃制成的生物质炭作为吸附剂,通过模拟实验,研究其对溶液中活性艳蓝KN-R的吸附特性,考察了pH值、时间、溶液初始浓度和生物质炭用量对吸附效果的影响。结果表明,当pH为2.0时,玉米秸秆炭和稻壳炭对活性艳蓝的吸附量均达到最大,而pH对稻草秸秆炭的影响不大;三者达到吸附平衡的时间分别为180、300和360 min,最大吸附量分别为114.05、54.60和68.19 mg/g。等温吸附过程可以用Langmuir方程来描述;动力学实验表明,吸附过程更符合拟二级动力学模型;热力学数据分析发现,吸附过程是自发进行的吸热过程。     

生物炭修复Cd,Pb污染土壤的研究进展

随着矿产开采、冶炼等工业活动以及污水灌溉、施用污泥和劣质化肥等农业活动的进行,Cd,Pb等有害重金属不断进入农业环境中,对农田、菜地等造成污染。生物炭作为重要的土壤改良剂,在对Cd,Pb污染土壤的修复中表现出巨大的潜力。从生物炭的特性及制备、修复效果及其影响因素、修复机理等方面,对近年来国内外有关生物炭修复Cd,Pb污染土壤的研究成果和现状进行了总结,并对生物炭修复Cd,Pb污染土壤的发展前景和未来研究方向进行了展望。     

磁性生物炭负载Mg-Fe水滑石的制备及其吸附水中Cd（Ⅱ）和Ni（Ⅱ）的性能

合成了一种高吸附容量的磁性生物炭负载Mg-Fe水滑石复合材料（L-BC）,并用于去除水中的Cd²⁺和Ni²⁺。表征结果表明,采用浸渍联合热解法成功制备了磁性生物炭（M-BC）,水热合成法成功地将Mg-Fe水滑石负载在M-BC上。动力学研究结果表明,Cd²⁺和Ni²⁺吸附符合伪二级动力学模型,化学吸附为速率控制步骤。等温吸附研究结果表明,L-BC对Cd²⁺和Ni²⁺的吸附符合Langmuir模型,为单分子层化学吸附,最大吸附量分别为263.156 mg/g和43.291 mg/g。吸附机理主要为Mg-Fe水滑石层间CO₃^2-和表面羟基与Cd²⁺和Ni²⁺产生表面共沉淀。L-BC具有良好的吸附和重复利用性能,是一种很有前景的去除Cd²⁺和Ni²⁺的吸附材料。     

Penicillin fermentation residue biochar as a high-performance electrode for membrane capacitive deionization

● We have provided an activated method to remove the toxicity of antibiotic residue. ● PFRB can greatly improve the salt adsorption capacity of MCDI. ● The hierarchical porous and abundant O/N-doped played the key role for the high-capacity desalination. ● A new field of reuse of penicillin fermentation residue has been developed. Membrane capacitive deionization (MCDI) is an efficient desalination technology for brine. Penicillin fermentation residue biochar (PFRB) possesses a hierarchical porous and O/N-doped structure which could serve as a high-capacity desalination electrode in the MCDI system. Under optimal conditions (electrode weight, voltage, and concentration) and a carbonization temperature of 700 °C, the maximum salt adsorption capacity of the electrode can reach 26.4 mg/g, which is higher than that of most carbon electrodes. Furthermore, the electrochemical properties of the PFRB electrode were characterized through cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS) with a maximum specific capacitance of 212.18 F/g. Finally, biotoxicity tests have showed that PFRB was non-biotoxin against luminescent bacteria and the MCDI system with the PFRB electrode remained stable even after 27 adsorption–desorption cycles. This study provides a novel way to recycle penicillin residue and an electrode that can achieve excellent desalination.     

生物质炭对土壤重金属形态转化及其有效性的影响

为了解土壤重金属形态转化及其有效性对生物质炭修复措施的响应,以Cd、Cu、Pb和Zn复合污染水稻土为供试土样,添加不同粒径(1 mm和0.25 mm)和不同施用量(0、1%和5%)的竹炭(BB)、稻草炭(RSB)进行为期1年的恒温((25±1)℃)培养试验后,检测土壤p H、有效磷含量及重金属DTPA有效态含量的变化,并采用BCR连续浸提法分析生物质炭对土壤中重金属元素化学形态再分配的影响.结果表明:稻草炭的施用显著(p0.05)提高了土壤的p H值,且在RSB-5%(0.25 mm)处理下效果最显著;稻草炭的施用显著(p0.05)提高了土壤的有效磷含量,且5%用量比1%用量效果更明显;而竹炭的施用对土壤p H值和有效磷含量均无显著性影响;RSB-5%(0.25 mm)处理对降低土壤中Cd、Cu、Pb和Zn有效态含量的效果最佳,分别减少了34.5%、50.1%、52.5%和52.1%;在细粒径(0.25 mm)稻草炭处理下,酸溶态Cd和Cu向可还原态和可氧化态转化,酸溶态Zn向可还原态转化;在粗粒径(1 mm)竹炭处理下,酸溶态Cu和Zn向可还原态、可氧化态和残渣态转化;酸溶态Pb在稻草炭处理下向可还原态和可氧化态转化,且细粒径比粗粒径效果更佳;竹炭和稻草炭的施用改变了土壤中上述重金属各形态的分配,且5%用量比1%用量效果更明显.     

Phosphorus recovery from biogas fermentation liquid by Ca–Mg loaded biochar

Shortage in phosphorus (P) resources and P wastewater pollution is considered as a serious problem worldwide. The application of modified biochar for P recovery from wastewater and reuse of recovered P as agricultural fertilizer is a preferred process. This work aims to develop a calcium and magnesium loaded biochar (Ca–Mg/biochar) application for P recovery from biogas fermentation liquid. The physico-chemical characterization, adsorption efficiency, adsorption selectivity, and postsorption availability of Ca-Mg/biochar were investigated. The synthesized Ca–Mg/biochar was rich in organic functional groups and in CaO and MgO nanoparticles. With the increase in synthesis temperature, the yield decreased, C content increased, H content decreased, N content remained the same basically, and BET surface area increased. The P adsorption of Ca–Mg/biochar could be accelerated by nano-CaO and nano-MgO particles and reached equilibrium after 360 min. The process was endothermic, spontaneous, and showed an increase in the disorder of the solid–liquid interface. Moreover, it could be fitted by the Freundlich model. The maximum P adsorption amounts were 294.22, 315.33, and 326.63 mg/g. The P adsorption selectivity of Ca–Mg/biochar could not be significantly influenced by the typical pH level of biogas fermentation liquid. The nano-CaO and nano-MgO particles of Ca–Mg/biochar could reduce the negative interaction effects of coexisting ions. The P releasing amounts of postsorption Ca–Mg/biochar were in the order of Ca–Mg/B600 > Ca–Mg/B450 > Ca–Mg/B300. Results revealed that postsorption Ca–Mg/biochar can continually release P and is more suitable for an acid environment.     

生物炭对重污染土壤镉形态及油菜吸收镉的影响

为了解不同种类和用量的生物炭对土壤镉形态及油菜吸收镉的影响,通过室外盆栽试验,以湖南某冶炼区周边重镉污染土壤为供试土壤,湘油27号为供试作物,于油菜移栽前7d分别添加w为0.1％和1％的竹炭和柠条炭,分析土壤镉形态和成熟期油菜各器官镉含量.结果表明,添加生物炭能降低土壤镉的有效性和油菜各器官中镉含量.柠条炭降低油菜吸收累积镉的效果比竹炭更明显,且随着生物炭量的增加阻控效果更明显.相比于对照组,施用生物炭后土壤中w(可交换态镉)最大可降低16.64％;油菜根部、茎秆、油荚和籽粒w(镉)最大可分别降低34.06％ 、39.74％、33.15％和49.81％.综合结果表明,添加w=1％柠条炭处理组处理效果最佳.     

酸/碱改性香蒲生物炭对水中磷的去除及其机制研究

雨水径流中存在的磷污染问题严重威胁生态环境,而传统的雨水径流处理设施,如雨水花园、渗滤沟等,对磷的去除率较低且成本较高.以湿地中收割的香蒲为原材料,酸改性后制备的生物炭（TH7）的除磷效果非常好,明显优于碱改性生物炭（TOH7）：与原生物炭（T7）相比,酸改性生物炭大大提高了磷的去除效率,可从T7的65%提高至94%,而碱改性生物炭无除磷效果.TH7的表面孔隙发达,比表面积高达434.2m²·g^-1,对磷的吸附符合Freundlich模型和伪二级动力学模型,其吸附属于物理化学吸附,具体的机制为孔隙填充、表面化学沉淀、氢键结合.研究表明,以香蒲为原料制备的改性生物炭是一种效果优越的除磷吸附剂,可应用于植草沟、雨水花园等以填料为主要吸附层的径流处理设施中.     

污泥基生物炭结构的共焦显微拉曼技术应用

采用共焦显微拉曼光谱仪探索不同热解温度(500~900)℃条件下所制备的污泥基生物炭结构变化的表征方法.结果表明,拉曼信号的荧光干扰与生物炭的理化特性有较强的相关性.随着热解温度升高,拉曼漂移系数减小,这与污泥基生物炭挥发分含量、H/C和O/C比变化趋势一致.其中,漂移系数与挥发分含量和H/C的相关性指数分别是0.97和0.94,其变化规律可用来准确评估生物炭挥发分含量和H/C的变化.同时,生物炭在拉曼光谱中的特征峰强度比D/G随着热解温度升高而增强,代表了污泥基生物炭无序化程度增加的过程.谷区域(V)与D峰强度比IV/ID随热解温度升高而减小,表明具有缺陷的稠合芳环结构的比例增加;另外,经分峰拟合后得到的ID1/IG1变化较小,而ID2/IG2呈增加趋势,证实了小分子侧链基团断裂形成的化合物部分沉积在炭表面,形成缺陷和非晶结构;IG1/IG2随着热解温度升高而减小,表明了炭基材料键角有序与无序比随着热解温度的升高而降低.因此,拉曼光谱可用于表征污泥基生物炭的微观结构变化,反映其结构演变规律.