岩溶地下水补给的地表河流溶解无机碳昼夜变化与钙沉降

溶解无机碳昼夜动态变化对河流水体碳通量的估算有重要影响。本文选择由地下水补给且富含水生植物的典型河流,开展高分辨率水文地球化学监测和高频率水样取样工作,分析了水化学的昼夜动态变化特征,钙与无机碳昼夜循环产生的生物地球化学控制机理,估算了钙与无机碳昼夜通量。结果表明,白天pH、SIC上升,产生钙沉降和水体无机碳(主要为HCO-3)含量的下降,夜间得到地下水的补给,Ca2+和HCO-3浓度回升。监测期间,官村地下河出口地表河流钙与溶解有机碳的流失或沉降量分别为69.04kg/d和168.68kg/d,即51.14g/(m·d)和124.95g/(m·d),分别占输入量的6.2%和4.7%。受水生植物光合作用和钙化作用控制,沿流程发生无机碳向有机碳转化,是真正意义上的自然碳汇。

桂林漓江水体溶解无机碳迁移与水生光合碳固定研究

河流溶解无机碳含量昼夜变化主要受碳酸盐反向沉积、水生光合利用和脱气作用控制,被水生光合利用的溶解无机碳是岩溶碳汇的组成部分,脱气作用比例的大小是影响碳汇稳定性的决定因素。本文以漓江中游省里—冠岩之间15 km长河段为研究对象,开展昼夜高分辨率水化学自动化监测与高频取样,分析水生植物光合作用利用HCO^(-)_(3)及相关钙沉降过程。结果表明,监测河段水生光合利用的无机碳转化通量为859 kgC·d^(-1),单位流程光合作用溶解无机碳转化量和钙沉降量分别为2.06 t·(d·km)^(-1)和0.78 t·(d·km)^(-1)。光合作用与钙沉降消耗DIC约占总转化量的70%,以光合有机碳和CaCO3形式储存于河床,成为岩溶碳汇组成部分。无机碳转化量约占输入DIC总量的6.0%(其中1.7%以CO_(2)形式返回大气),说明夏季低水位期间强烈的水生植物光合利用溶解无机碳,可有效遏制白天水气界面CO_(2)脱气过程发生,低脱气比例证实漓江水体的溶解无机碳还是比较稳定的。

酸性高氟废水处理方法的研究

介绍了用改性聚铁结合传统的钙盐沉降法联合PAM处理酸性高氟废水的试验情况,分别介绍了改性聚铁加入量、pH、CaCl2加入量、沉降时间、PAM加入量对除氟效率的影响,在试验确定的最佳条件下可使废水中氟质量浓度降至10mg/L以下,达到国家规定的工业废水的排放标准。按试验确定的工艺处理该类废水,操作简便,易于管理,费用低廉。

含高氟废水处理方法的研究

叙述了作为人体生命活动所必需的微量元素氟对人体的危害、详细介绍了目前国内外对含氟废水的处理方法 。

Polymorph and morphology of CaCO_3 in relation to precipitation conditions in a bubbling system

Simulating the typical carbonation step in a mineral CO_2 sequestration, precipitated calcium carbonate(PCC) was prepared by bubbling CO_2 gas into a rich Ca solution. These carbonation reactions were conducted at three p H ranges, namely 10.0–9.0, 9.0–8.0, and 8.0–7.0, in which temperature and CO_2 flow rate are additional experimental variables. The PCC obtained in experiments was examined by Fourier transform infrared spectroscopy(FTIR)and X-ray diffraction(XRD). It was found that supersaturation determined by p H value and flow rate of CO_2 has significant influence on polymorph of PCC. Vaterite was preferably formed at high supersaturation, while dissolution of metastable vaterite and crystallization of calcite occurred at low supersaturation. High temperature is a critical factor for the formation of aragonite. At 70 °C, vaterite, calcite and aragonite were observed to coexist in PCC because transformation from vaterite to aragonite via calcite occurred at this temperature. Scanning electron microscopy(SEM) technology was performed on prepared PCC, and various morphologies consistent with polymorphs were observed.