污水可生化性及其影响因素研究

以自行设计的生化呼吸线测定装置研究了印染污水的可生化性,该装置通过反应体系的溶解氧浓度跟踪生物降解过程.采用本文设计的模拟污水处理装置探讨了污泥驯化时间、污水投加量等对污水可生化性的影响.测定了污水经可生化性调控后的处理效果.结果表明,生化呼吸线法判断污水处理体系的可生化性是1种可靠易行的方法,提高体系的可生化性是增加污水处理效果的关键因素.     

鼠尾藻(Sargassum thunbergii)对邻苯二甲酸二甲酯(DMP)胁迫的响应

邻苯二甲酸二甲酯(dimethyl phthalate,DMP)是近海环境有机污染物之一,不仅对海洋生物造成毒害,且能在生物体内富集和放大,对海洋生态系统形成严重威胁。本文以鼠尾藻(Sargassum thunbergii)为研究对象,通过测定比生长速率、叶绿素a含量、光合和呼吸速率、光合基因rbcL转录水平上的相对表达量等指标,研究了鼠尾藻对不同浓度DMP的响应。结果表明,低浓度的DMP(0.lmg/L)短时间内(≤15d)能促进鼠尾藻的生长和叶绿素a的合成,并使藻体的光合作用增强,诱导光合基因rbcL的表达,而在高浓度DMP(≥0.3mg/L)的作用下,鼠尾藻的生长速率、光合和呼吸速率、rbcL基因的表达量均随着暴露时间的延长呈明显下降趋势,且DMP浓度越高,降幅越大。以上研究结果对了解DMP对鼠尾藻胁迫的影响机制奠定了基础,为保护海洋经济藻类的养殖环境提供了理论依据。     

黄东海浮游生物群落呼吸率对碳平衡的重要性

黄东海接受长江冲淡水和黑潮带来的大量营养盐和有机物质,其碳循环对陆架海碳源汇格局至关重要.浮游生物群落呼吸是影响碳循环的重要过程.为揭示黄东海浮游生物群落呼吸率(PCR)对碳平衡的贡献,于2011年四季使用黑白瓶培养法测定黄海南部及东海北部浮游群落呼吸率和初级生产力,并同步测定温度、盐度、营养盐、叶绿素和细菌丰度等环境...     

Light‐dependence of photosynthesis and growth in cyanobacteria: Implications for their dominance in eutrophic lakes

In eutrophic lakes cyanobacteria are favoured relative to other phytoplankton, both under stratified and mixed conditions. During stratification, gas vacuole formation allows the accumulation of dense surface scums which attain the highest possible area‐specific photosynthetic rates in aquatic environments owing to high irradiances, near‐complete harvesting of impinging light, and minimal light inhibition and photo‐oxidation. During moderate mixing, high yields of biomass can be achieved by effective light harvesting for photosynthesis (aided by phycobilin pigments) and low maintenance energy requirements at low mean irradiances. Howevrr, nitrogen fixation competes for energy and reductant with photosynthesis, and leads to a decline of light‐saturated maximum growth rates. Wind‐driven vertical mixing and lateral advection are the main causes for the instability of cyanobacterial blooms in hyper‐eutrophic lake ecosystems.     

Water quality in a polluted lowland stream with chronically depressed dissolved oxygen: Causes and effects

Abstract

The Whangamaire Stream (North Island, New Zealand) has high concentrations of nitrate nitrogen (NO^? ₃‐N), biochemical oxygen demand (BOD₅), and Kjeldahl nitrogen (TKN) as a result of catchment land use practices. The lower reaches of the stream drain intensively farmed land and have dissolved oxygen (DO) levels of 10–50% saturation. The dominant riparian vegetation, Apium nodiflorum, provides a large organic loading by intercepting nutrients in run‐off and then decaying in the stream channel. Water quality and reaeration aspects of the stream were studied in order to explain the observed low DO levels. Measurements of the reaeration coefficient at 20°C, K₂ ²⁰, using methyl chloride (CH₃Cl) as a gas tracer, yielded values of 1.1–3.0 d^?1 for the upper part of the study reach and 15.5–16.2 d^?1 for the lower reach (overall average 12.5 ± 2.5 d^?1). These were in agreement with values inferred from single‐station diurnal curve analysis, which also showed that respiration was dominant in the lower reach where photo‐synthetic activity was inhibited by shade. The relatively large reaeration coefficients ensure that parts of the stream do not become anoxic at night time. Better riparian management and reduced nutrient inputs are likely to improve stream water quality.     

塔里木河流域干旱区棉田土壤呼吸的温度敏感性研究

利用阿克苏绿洲农田试验站连续测定的棉田土壤呼吸值及同步测定的土壤温度与湿度数据, 构建通用的土壤呼吸温度敏感性模型. 结合构建的模型, 对5个常用的土壤呼吸温度模型所模拟的研究区的土壤呼吸变化的温度敏感性进行评析. 结果表明: Arrhenius模型能较好的预测研究区的土壤呼吸温度敏感性的变化; 研究区土壤呼吸温度敏感性随温度的升高呈下降的趋势. 两类试验样地土壤呼吸温度敏感性存在明显的差异性, 这可能与两类试验样地土壤呼吸组分的差异有关, 这是以后需要重点关注的地方.     

土壤中氮碳间相互作用对全球碳循环的影响(英文)

氮循环中的能量产生过程构成与全球碳循环间的重要关联。例如,氮投入土壤,一开始导致CO2排放降低。这一众所周知的效应被理解为土壤呼吸作用受到阻碍或延缓。然而,当把冗余考虑在内便知,氮投入并不使最初得到的CO2最低排放量保持不变,而是逐渐导致排放增加。土壤中硝化作用对CO2消耗过程的特异性抑制,加上铵冗余投入或乙炔作用,往往导致额外的CO2排放量。这种总自养性呼吸(GHR)与CO2净排放(NHR)之间的差就是土壤内CO2汇。土壤呼吸作用单纯由NHR产生的CO2排放量(通常情况)来决定会导致对土壤系统的曲解,特别是在氮沉降量高的地区。因此,必须重新考虑温暖区域土壤呼吸作用的"适应环境"问题。可能也需要质疑氮投入带来的"呼吸抑制"概念。无视这些过程,包括上述氮驱动下的土壤内CO2汇过程,也许会有碍于采取足够的措施来对抗气候变化。     

亚热带马尼拉草坪生态系统呼吸昼夜变化研究初报

采用Li-8100对亚热带马尼拉草坪生态系统呼吸及其分室昼夜动态进行研究,结果表明,草坪生态系统呼吸、土壤呼吸和植物地上部分呼吸速率的昼夜变化均表现为单峰曲线,呼吸速率日最高值出现在中午13：00～14：00;草坪生态系统的呼吸速率最低值只出现在6月的7：00左右,其他月份的最低值出现在23：00～2：00;土壤呼吸速率的最低值出现在4月和6月的7：00左右,8月则在2：00达最低值,11月土壤呼吸速率波动不大,极值不太明显．生态系统呼吸速率始终表现为白天高于夜间．4月、6月、8月和11月生态系统呼吸的日排放C量分别为27．30、43．94、44．79和25．18g m^2d^-1．6月、8月和11月土壤日呼吸量占整个生态系统日呼吸总量的比例大约为50％,远小于4月的74％．除11月外,生态系统、土壤总呼吸速率的昼夜变化均与5cm土温呈显著的指数相关．草坪生态系统呼吸的Q10值大小顺序为4月〉11月〉6月〉8月,土壤总呼吸的Q10值大小顺序为6月〉4月〉8月〉11月;除11月外,土壤呼吸的Q10值大于生态系统呼吸．     

通过改变光热条件分析胡杨群落光合作用对土壤呼吸速率的影响

结合干旱环境下塔里木河下游地区胡杨群落长势、土壤呼吸、土壤水分、温度的实时监测资料,通过改变光热条件对胡杨群落进行人工遮阴控制,分析植物群落长势对土壤呼吸速率的影响,同时对不同光环境下胡杨群落土壤呼吸速率变化特征及其影响因素进行了探讨。结果表明,胡杨群落土壤呼吸速率日变化呈现多峰值曲线,但最大值集中出现在12:00—16:00之间,最低值出现在早上08:00和晚上20:00;植物群落长势很大程度上决定着土壤呼吸速率的大小;胡杨群落土壤呼吸的日变化与水热因子之间联系存在很大的不确定性,但在很大程度上受植物新近合成同化产物控制。     

A comparison of annual and seasonal carbon dioxide effluxes between sub-Arctic Sweden and High-Arctic Svalbard

Recent climate change predictions suggest altered patterns of winter precipitation across the Arctic. It has been suggested that the presence, timing and quantity of snow all affect microbial activity, thus influencing CO₂ production in soil. In this study annual and seasonal emissions of CO₂ were estimated in High-Arctic Adventdalen, Svalbard, and sub-Arctic Latnjajaure, Sweden, using a new trace gas-based method to track real-time diffusion rates through the snow. Summer measurements from snow-free soils were made using a chamber-based method. Measurements were obtained from different snow regimes in order to evaluate the effect of snow depth on winter CO₂ effluxes. Total annual emissions of CO₂ from the sub-Arctic site (0.662–1.487 kg CO₂ m^–2 yr^–1) were found to be more than double the emissions from the High-Arctic site (0.369–0.591 kg CO₂ m^–2 yr^–1). There were no significant differences in winter effluxes between snow regimes or vegetation types, indicating that spatial variability in winter soil CO₂ effluxes are not directly linked to snow cover thickness or soil temperatures. Total winter emissions (0.004–0.248 kg CO₂ m^–2) were found to be in the lower range of those previously described in the literature. Winter emissions varied in their contribution to total annual production between 1 and 18%. Artificial snow drifts shortened the snow-free period by 2 weeks and decreased the annual CO₂ emission by up to 20%. This study suggests that future shifts in vegetation zones may increase soil respiration from Arctic tundra regions.