Poorly crystalline iron and aluminium oxides contribute to the carbon saturation and sorption of dissolved organic carbon in the soil

Soil carbon (C) saturation implies an upper limit to a soil's capacity to store C depending on the contents of silt + clay and poorly crystalline Fe and Al oxides. We hypothesized that the poorly crystalline Fe and Al oxides in silt + clay fraction increased the C saturation and thus reduced the capacity of the soil to sorb additional C input. To test the hypothesis, we studied the sorption of dissolved organic carbon (DOC) on silt + clay fractions (<53 µm) of highly weathered oxic soils, collected from three different land uses (i.e., improved pasture, cropping and forest). Soils with high carbon saturation desorbed 38% more C than soils with low C saturation upon addition of DOC, whereas adsorption of DOC was only observed at higher concentration (>15 g kg^?1). While high Al oxide concentration significantly increased both the saturation and desorption of DOC, the high Fe oxide concentration significantly increased the desorption of DOC, supporting the proposition that both oxides have influence on the DOC sorption in soil. Our findings provide a new insight into the chemical control of stabilization and destabilization of DOC in soil.     

生物炭对Bt Cry1Ac蛋白抗紫外能力影响

为了研究生物炭对紫外线的防护作用，以豆壳烧制的生物炭作为载体，研究生物炭对Bt Cry1Ac蛋白的吸附行为以及生物炭对Cry1Ac蛋白的紫外保护作用。使用扫描电子显微镜、透射电子显微镜、X-射线粉末衍射以及傅立叶红外光谱等手段对生物炭的形貌和结构进行表征。结果表明，生物炭是典型的多孔结构材料，表面具有丰富的官能团。Cry1Ac蛋白与生物炭吸附平衡时间为50 min，最合适的吸附浓度比（生物炭：蛋白）为1：100，二者吸附符合准二级动力学模型和Langmuir模型。在UVB紫外照射4 h后，生物炭与Cry1Ac蛋白复合物对棉铃虫的生物活性是单纯蛋白的4.93倍，显示生物炭具有较好的紫外抵抗效果。研究结果初步表明，制备得到的生物炭能够显著提高Cry1Ac蛋白的抗紫外能力，为后续研发耐受紫外线的农药剂型提供新材料。     

氮吸附法分析生物质焦孔隙结构

采用氮吸附法对4种生物质焦(稻壳、树叶、玉米秆、棉花秆)的孔隙结构进行测量,结果表明,不同种类焦样的比表面积和孔径分布有明显差别,树叶的比表面积最大,为242.21 m2·g-1,玉米秆的比表面积最小,为0.81 m2·g-1.850℃时,稻壳、树叶、玉米秆焦样的孔径分布曲线在微孔和中孔范围各有一个分布峰,而棉花秆焦样的孔径分布曲线只在中孔范围内出现一个分布峰.热解温度是影响孔隙结构的一个重要因素,在高温条件下,同步热解得到的焦样的比表面积较大,微孔较多.在本研究中,600℃、850℃的稻壳焦样和850℃的树叶焦样具有较大的比表面积,比较适合做吸附剂.     

Influence of the physical and chemical properties of soil on the retention process of isoxaflutole and its two main derivatives

Isoxaflutole is a new pre‐emergence herbicide for use in maize and sugarcane. Its two main derivatives are a diketonitrile derivative, the 2‐cyano‐3‐cyclopropyl‐1‐(2‐methanesulfonyl‐4‐trifluoromethylphenyl)propan‐1,3‐dione, named DKN, and a benzoic acid derivative, the 2‐methanesulfonyl‐4‐trifluoromethylbenzoic acid, named BA. The adsorption/desorption processes have never been studied for isoxaflutole (IFT) at high concentrations nor for BA, and the present work aimed at completing the knowledge of the behaviour of these three molecules in conditions close to those encountered in the context of agricultural use. The adsorption/desorption study was conducted on seven soils of different physical and chemical properties, using the batch equilibrium technique. During the experiments, IFT was chemically converted into DKN in a continuous manner. This reaction appeared to be dependent on the pH of the soil and was taken into account in the calculations of the adsorbed and desorbed amounts. The adsorption isotherms obtained were predominantly C‐shaped for IFT and DKN and S‐shaped for BA, but some differences appeared on a few soils. They fitted well the Freundlich equation, and the values of the Freundlich coefficient K_fa showed that, whatever the soil, IFT was more adsorbed than its two derivatives. The main parameter influencing the adsorption of IFT appeared to be the organic matter content, whereas this effect was not evident for DKN and BA. No correlation was found between the extent of adsorption and either clay content or pH of the soil, for the three molecules.     

Biochar Mitigates Salinity Stress in Potato

A pot experiment was conducted in a climate‐controlled greenhouse to investigate the growth, physiology and yield of potato in response to salinity stress under biochar amendment. It was hypothesized that addition of biochar may improve plant growth and yield by mitigating the negative effect of salinity through its high sorption ability. From tuber bulking to harvesting, the plants were exposed to three saline irrigations, that is 0, 25 and 50 mm NaCl solutions, respectively, and two levels of biochar (0 % and 5 % W/W) treatments. An adsorption study was also conducted to study the Na⁺ adsorption capability of biochar. Results indicated that biochar was capable to ameliorate salinity stress by adsorbing Na⁺. Increasing salinity level resulted in significant reductions of shoot biomass, root length and volume, tuber yield, photosynthetic rate (A_n), stomatal conductance (g_s), midday leaf water potential, but increased abscisic acid (ABA) concentration in both leaf and xylem sap. At each salinity level, incorporation of biochar increased shoot biomass, root length and volume, tuber yield, A_n, g_s, midday leaf water potential, and decreased ABA concentration in the leaf and xylem sap as compared with the respective non‐biochar control. Decreased Na⁺, Na⁺/K⁺ ratio and increased K⁺ content in xylem with biochar amendment also indicated its ameliorative effects on potato plants in response to salinity stress. The results suggested that incorporation of biochar might be a promising approach for enhancing crop productivity in salt‐affected soils.     

茉莉花茶加工技术与吸香机理研究现状

为了进一步综合地认识茉莉花茶窨制的工艺本质、完善茉莉花茶窨制技术,本文综述和分析了茉莉花茶加工技术及吸香机理的研究现状,并对后续研究进行了展望。     

竹炭陶的制备及其气体吸附和调湿性能

基于开发和利用生物质竹炭材料,以竹炭粉、凹凸棒、硅藻土等为原料,制备竹炭陶瓷复合材料,从而避免传统炭吸附材料易碎和粉尘污染的缺点。首先,将原料通过陶瓷造粒工艺制备成直径为2~5 mm的小球;然后,在N 2气氛中1250℃下烧结为竹炭陶小球,并对其结构和吸附性能进行了研究。XRD测试结果表明,竹炭陶瓷复合材料在烧结前后并未改变竹炭陶晶体结构。原料的SEM测试结果表明,竹炭粉在微观结构上存在1μm左右的大孔,其中硅藻土的微观形貌为多孔圆盘状结构,圆盘的直径分布在20~50μm,孔道直径在0.1~1.2μm;竹炭陶的SEM测试结果表明,断面结构疏松多孔,经过复合和烧结后,仍然保持了原有的孔道结构,保障了竹炭陶的吸附性能。BET法测试结果表明,竹炭陶的比表面积达到118.54 m^2/g。吸附性能测试表明,竹炭陶对水分吸附率达到22.0%,对甲醛、氨气及硫化氢等有害气体的吸附率分别达到87.7%,94.6%和96.3%。实验结果表明,竹炭陶具有良好的吸湿和气体吸附性能,是一种良好的空气净化材料,在室内环境和水处理等方面具有广阔的应用前景。     

纳米Fe3O4负载酸改性炭对水体中Pb2+、Cd2+的吸附

为探讨纳米Fe₃O₄负载联合硝酸改性椰壳炭对Pb²⁺、Cd²⁺单一及复合溶液的吸附特性，通过静态吸附实验，针对吸附剂的表面特性、投加量、溶液初始pH、吸附时间、重金属初始浓度等影响因素进行了探讨，应用等温吸附模型及吸附动力学模型对吸附特性进行了研究。结果表明，纳米Fe₃O₄负载酸改性炭比表面积较未改性椰壳炭增加了221.03 m²·g^-1，表面含氧官能团如O-H、C=O、C-O-C增加，芳香性增强，等电点提高至5.68。从经济效率角度考虑5 g·L^-1为合理吸附剂用量，pH为5.0时，吸附效果最好，吸附在4 h达到平衡。准二级动力学模型对吸附的拟合度更高，吸附主要是化学吸附，吸附由快速外扩散和颗粒内扩散共同作用，Pb²⁺、Cd²⁺的吸附分别更符合Langmuir和Freundlich等温吸附模型。纳米Fe₃O₄负载酸改性椰壳炭对Pb²⁺、Cd²⁺的最大吸附量（Q_m）分别达42.54 mg·g^-1和25.79 mg·g^-1，为未改性椰壳炭的1.87倍和2.23倍，复合溶液中Pb²⁺、Cd²⁺的Q_m分别为单一溶液的65.16%和54.21%，这揭示了离子共存条件下的吸附竞争现象。研究表明，纳米Fe₃O₄负载联合硝酸改性提高了椰壳炭对Pb²⁺、Cd²⁺的吸附能力，且Pb²⁺的吸附性能及吸附竞争性优于Cd²⁺。     

白果壳遗态HAP/C复合材料对水中氨氮的吸附

为综合利用农林废弃物，以白果壳为植物模板、羟基磷灰石（HAP）为改性材料，制备了白果壳遗态HAP/C复合材料（PBGC-HAP/C-G），并通过X射线衍射仪（XRD）、傅里叶红外光谱仪（FT-IR）和扫描电镜（SEM）等对其进行了表征，同时研究了溶液pH、初始浓度、吸附剂投加量等对其去除水中氨氮的影响。结果表明，PBGC-HAP/C-G是一种大孔材料，孔径主要介于35~200 μm之间。在溶液pH=5时，吸附效果最佳；吸附剂投加量的增加有利于氨氮的去除；粒径大小不是影响吸附效果的主要因素。准二级动力学模型和Freundlich等温吸附模型能很好地描述该吸附过程，吸附过程以化学吸附为主。在氨氮初始浓度为20、50、100 mg·L^-1时，拟合计算得到的理论平衡吸附量分别为0.45、1.10、2.15 mg·g^-1，与实验测定值0.46、1.15、2.18 mg·g^-1相近，可见PBGC-HAP/C-G可用作去除氨氮的吸附剂。     

La和Fe改性木芙蓉和龙牙花树枝粉对畜禽废水中磷的吸附

畜禽养殖废水中过量的磷排放易导致水体富营养化。为有效去除畜禽废水中的磷和对园林废弃物进行资源化利用,本研究探讨La和Fe分别改性木芙蓉树枝粉(HM)和龙牙花树枝粉(EC)得到的4种材料(La-HM、La-EC、Fe-HM和Fe-EC)在不同投加量、溶液pH、吸附时间和初始磷浓度等条件下对模拟废水中磷吸附的影响。结果表明,4种改性材料对模拟废水中磷的单位吸附量随投加量的增加呈指数或幂函数下降(P0.05);随溶液pH的升高,La改性的两种材料对磷的吸附量呈先上升后下降趋势,Fe改性的两种材料则相应呈幂函数下降(P0.05)。它们的吸附动力学过程符合准二级动力学模型,吸附等温线更适合用Freundlich模型拟合。4种改性材料对模拟废水中磷的理论最大吸附量分别为15.00、12.02、7.18 mg·g~(-1)和8.43 mg·g~(-1),对实际养猪废水中磷的吸附量为11.63～21.71 mg·g~(-1),是未改性前的1.58～3.23倍。因此,La和Fe改性木芙蓉和龙牙花树枝粉是吸附畜禽废水中磷的潜在材料。