Apparent variations in nitrogen runoff and its uptake in paddy rice under straw incorporation

Straw incorporation is a widespread practice to promote agricultural sustainability.However,the potential effects of straw incorporation with the prolonged time on nitrogen(N)runoff loss from paddy fields are not well studied.The current study addresses the knowledge gap by assessing the effects of straw incorporation on the processes influencing N runoff patterns and its impacts on crop yield,N uptake,total N(TN),and soil organic matter(SOM).We conducted field experiments with rice(Oryza sativa L.)–wheat(Triticum aestivum L.)rotation,rice–tobacco(Nicotiana tabacum L.)rotation,and double-rice cropping in subtropical China from 2008 to 2012.Each rotation had three N treatments:zero N fertilization(CK),chemical N fertilization(CF),and chemical N fertilization combined with straw incorporation(CFS).The treatment effects were assessed on TN runoff loss,crop yield,N uptake,soil TN stock,and SOM.Results showed that TN runoff was reduced by substituting part of the chemical N fertilizer with straw N in the double rice rotation,while crop N uptake was significantly(P<0.05)decreased due to the lower bioavailability of straw N.In contrast,in both rice–wheat and rice–tobacco rotations,TN runoff in CFS was increased by 0.9–20.2%in the short term when straw N was applied in addition to chemical N,compared to CF.However,TN runoff was reduced by 2.3–19.3%after three years of straw incorporation,suggesting the long-term benefits of straw incorporation on TN loss reduction.Meanwhile,crop N uptake was increased by 0.8–37.3%in the CFS of both rotations.This study demonstrates the challenges in reducing N runoff loss while improving soil fertility by straw incorporation over the short term but highlights the potential of long-term straw incorporation to reduce N loss and improve soil productivity.

Reducing nitrogen runoff from paddy fields with arbuscular mycorrhizal fungi under different fertilizer regimes

Nitrogen（N） runoff from paddy fields serves as one of the main sources of water pollution. Our aim was to reduce N runoff from paddy fields by fertilizer management and inoculation with arbuscular mycorrhizal fungi（AMF）. In northeast China, Shuangcheng city in Heilongjiang province, a field experiment was conducted, using rice provided with 0%, 20%, 40%, 60%, 80%,and 100% of the local norm of fertilization（including N, phosphorus and potassium）, with or without inoculation with Glomus mosseae. The volume, concentrations of total N（TN）,dissolved N（DN） and particulate N（PN） of runoff water were measured. We found that the local norm of fertilization led to 18.9 kg/ha of N runoff during rice growing season, with DN accounting for 60%–70%. We also found that reduction in fertilization by 20% cut down TN runoff by 8.2% while AMF inoculation decreased N runoff at each fertilizer level and this effect was inhibited by high fertilization. The combination of inoculation with AMF and 80% of the local norm of fertilization was observed to reduce N runoff by 27.2%. Conclusively, we suggested that the contribution of AMF inoculation combined with decreasing fertilization should get more attention to slow down water eutrophication by reducing N runoff from paddy fields.

Spatial and temporal variation of nitrogen exported by runoff from sandy agricultural soils

The eutrophication problem has drawn attention to nutrient leaching from agricultural soils, and an understanding of spatial and temporal variability is needed to develop decision-making tools. Thus, eleven sites were selected to monitor, over a two-year period, spatial and temporal variation of runoff discharge and various forms of N in surface runoff in sandy agricultural soils. Factors influencing the variation of runoff discharge and various forms of N in surface runoff were analyzed. Variation of annual rainfall was small among 11 sites, especially between 2001 and 2002. However, variation of annual discharge was significant among the sites. The results suggest that rainfall patterns and land use had significant effect on discharge. The concentrations of total N, total kjeldahl N （TKN）, organic matter-associated N （OM-N）, NO3- -N, and NHn＋-N in the runoff ranged widely from 0.25 to 54.1, 0.15 to 20.3, 0.00 to 14.6, 0.00 to 45.3, and 0.00 to 19.7 mg/L, respectively. Spatial and temporal variations in the N concentration and runoff discharge were noted among the different sites. Annual loads of N in the runoff varied widely among monitoring sites and depend mainly on runoff discharge. High loads of total N, OM-N, NO3--N, and NHn＋-N in the runoff either in citrus groves or on vegetable farms occurred from June to October for each year, which coincided with the rainy season in the region. This study found that N in surface runoff was related to rainfall intensity, soil N level, and fertilizer use.

Study of Dynamics of Floodwater Nitrogen and Regulation of Its Runoff Loss in Paddy Field-Based Two-Cropping Rice with Urea and Controlled Release Nitrogen Fertilizer Application

The article deals with the effects of urea and controlled release nitrogen fertilizer （CRNF） on dynamics of pH, electronic conductivity （EC）, total nitrogen （TN）, NH4^＋-N and NO3 -N in floodwater, and the regulation of runoff TN loss from paddy field-based two-cropping rice in Dongting Lake, China, and probes the best fertilization management for controlling N loss. Studies were conducted through modeling alluvial sandy loamy paddy soil （ASP） and purple calcareous clayey paddy soil （PCP） using lysimeter, following the sequence of the soil profiles identified by investigating soil profile. After application of urea in paddy field-based two-cropping rice, TN and NHa＋-N concentrations in floodwater reached peak on the 1st and the 3rd day, respectively, and then decreased rapidly over time; all the floodwater NO3--N concentrations were very low; the pH of floodwater gradually rose in case of early rice within 15 d （late rice within 3 d） after application of urea, and EC remained consistent with the dynamics of NH4^＋-N. The applied CRNF, especially 70% CRNF, led to significantly lower floodwater TN and NH4^＋ concentrations, pH, and EC values compared with urea within 15 d after application. The monitoring result for N loss due to natural rainfall runoff indicated that the amount of TN lost in runoff from paddy field- based two-cropping rice with urea application in Dongting Lake area was 7.47 kg ha^-1, which accounted for 2.49% of urea- N applied, and that with CRNF and 70% CRNF application decreased 24.5 and 27.2% compared with urea application, respectively. The two runoff events, which occurred within 20 d after application, contributed significantly to TN loss from paddy field. TN loss due to the two runoffs in urea, CRNF, and 70% CRNF treatments accounted for 72, 70, and 58% of the total TN loss due to runoff over the whole rice growth season, respectively. And the TN loss in these two CRNF treatments due to the first run-off event at the 10th day after application to early rice decreased 44.9 and 44.2% compared with urea, respectively. In conclusion, the 15-d period after application of urea was the critical time during which N loss occurred due to high floodwater N concentrations. But CRNF decreased N concentrations greatly in floodwater and runoff water during this period. As a result, it obviously reduced TN loss in runoff over the whole rice growth season.

Nitrogen export by runoff and sedimentunder different types of land use inWest Tiaoxi catchment

Five typical land covers in West Tiaoxi catchment of China, including mulberry garden, bamboo forest, pinery, vegetable plot and paddy field, were studied on nitrogen loss in artificial rainstorm runoff and sediment. Triple duplication experiments have been carried out under the artificial rain condition with an intensity of 2 mm.mm?1 and lasting 32 minutes in 3 m2 field. Export of various species of nitrogen in runoff and sediment were investigated. The results show that nitrogen loss amount and rate are quite different among five kinds of land covers. The loss of total nitrogen in runoff of mulberry is the largest and that of paddy field is the smallest. Particle nitrogen accounts for 70–90% of total nitrogen in runoff of various kinds of land covers. Loss of dissolved nitrogen in pinery is much higher than in other kinds of land covers, which are similar among them. More detailed species of dissolved nitrogen show their respective features among various land covers. Total amounts of nitrogen loss from the top 10 cm layer of 5 kinds of soils are estimated as high as 4.66–9.40 g.m?2, of which nitrogen loss through sediment of runoff accounts for more than 90%. The rate of total nitrogen losses are ranged in 2.68–14.48 mg.m?2.min?1 in runoff, which is much lower than that of 100.01–172.67 mg.m?2.min?1 in sediment of runoff.

不同配置乡村植被缓冲带阻控径流污染特征研究

植被缓冲带是河湖的重要生态空间屏障,对于减缓人类活动对河湖的直接干扰、阻隔农业面源污染等具有重要意义。为系统研究不同类型缓冲带对农田氮磷等污染物的拦截功效,本研究在定远张山设计8个缓冲带小区,结合自然降雨方式,持续两年观测不同缓冲带对地表径流及其主要污染物(TN、TP、COD)的削减效果。结果表明:林地和3°、8°横垄耕地缓冲带对径流的拦截效率较高,减流率分别达到了62.4%、52.0%和60.6%,径流量随雨强增大先升高后下降。与8°坡耕地缓冲带相比,降坡(3°)处理竖垄、横垄缓冲带泥沙流失量分别降低53.3%、50.9%。降雨产流的养分流失以氮素和有机质为主,林地缓冲带对径流NH4+-N的拦截率平均高达95.2%,此外降坡和横垄耕作措施也能有效减少径流冲刷的氮素流失。不同处理缓冲带对径流TP均有较好的拦蓄效果。3°、8°横垄耕地缓冲带CODMn流失量较低,拦截率达到53.0%、58.6%。林地缓冲带中高覆盖度的植被和发达的根系能够有效减缓降雨对地表的冲刷,减少径流和养分流失。在南方丘陵山地的乡村地区实施横坡垄作是拦蓄径流、降低面源污染风险的有效措施。

冬春季生态沟渠对农田径流污染物的净化效果分析

为有效提高冬春季沟渠的净化效率,在原有土质沟渠中增设耐寒植物黑麦草浮毯与填料透水坝构建生态沟渠,分析生态沟渠对农田径流中主要污染物的削减率,对比沿程不同处理段对污染物的净化效果,估算植物吸收对于污染通量降低总量的贡献。结果显示:在冬春季节,生态沟渠对总氮(TN)、硝氮(NO_(3)^(-)-N)、总磷(TP)、化学需氧量(COD)和悬浮物(SS)的总削减率均值分别为29.06%、54.93%、20.76%、54.08%和49.85%。透水坝段的TN和NO_(3)^(-)-N沿程削减率最高;植物浮毯+透水坝段的TP和COD沿程削减率最高;植物浮毯段的SS沿程削减率最高,其对NO_(3)^(-)-N、TP和COD也有较好的净化效果。在降水量达到10 mm以上的9 d内,TN和TP的污染通量降低总量分别为11.43和0.27 kg;黑麦草吸收的氮、磷量分别约占污染通量降低总量的20.6%和55.6%。大雪融化后气温降至0℃以下,可能引起土壤冻融作用,雪水径流中的氮、磷浓度显著升高,此时生态沟渠对径流中氮、磷的净化效果不明显,可利用周边河塘暂存雪水径流,后续结合生态措施对污染物实施强化处理。

梁子湖流域降雨径流过程及氮磷流失对不同景观格局的响应

景观格局决定小流域能源流动与水沙过程,是影响氮磷流失的重要因素。以湖北梁子湖流域的双溪(农林复合型)和石桥(林地型)2个典型小流域为研究对象,在自然降雨条件下,于2016年1-12月对流域出口断面水质水量进行了连续监测,并结合丰水期典型次降雨径流过程,探讨了不同景观格局下小流域降雨径流过程和氮磷输出特征,为梁子湖环境综合治理提供一定的科学依据。结果表明:(1)降雨径流过程在不同景观格局小流域内呈现出明显差异。相比于双溪小流域,石桥小流域产流能力较强,径流过程呈现出汇流时间较短、径流响应速度较快、径流模数较大的趋势;(2)双溪小流域总氮(TN)和总磷(TP)月均输出浓度范围分别为1.29~4.28 mg/L和0.04~0.22 mg/L,均高于石桥小流域(TN:0.62~1.90 mg/L;TP:0.02~0.11 mg/L),其中硝态氮(NO_(3)^(-)-N)是氮素流失的主要形态,占TN流失的51.8%~88.2%。相比于石桥小流域,双溪小流域的NO_(3)^(-)-N/TN较大。2个小流域的氨氮(NH_(4)^(+)-N)和亚硝态氮(NO_(2)^(-)-N)输出浓度均较低并且无明显变化趋势;(3)双溪小流域的TN和TP月均输出通量范围分别为1.83~20.03 g/s和0.04~1.45 g/s,均高于石桥小流域(TN:0.62~10.01 g/s;TP:0.01~0.54 g/s),且与同时段流量呈现显著正相关关系(P<0.01);(4)双溪小流域的TN和TP流失强度分别为3.68和0.20 t/(km^(2)·a),分别是石桥小流域的1.32倍和1.30倍。氮磷流失主要集中在降雨频繁的4-7月,占全年流失负荷的70%以上。综上,梁子湖流域景观格局显著影响养分流失,优化土地利用配置和科学合理施肥是改善该流域水环境的科学措施。

秸秆和生物炭对紫色土坡耕地产流产沙与氮素流失的影响

[目的]探究不同添加量的秸秆和生物炭对紫色土坡耕地的具体改良效果,从而为合理防治三峡库区水土流失提供理论参考。[方法]采用人工模拟降雨的方法,以裸坡为对照,研究了紫色土中添加水稻秸秆(施用量4,7,10 t/hm^(2))和生物炭(含量13,39,65 t/hm^(2))对紫色土坡耕地产流产沙与氮素流失的影响。[结果](1)高强度降雨条件下,紫色土混掺生物炭加快了坡面产流进程,而施加碎混秸秆能延长起始产流时间、削减产流速率;(2)紫色土添加生物炭后累积产沙量较对照增加了0.64%~66.29%,而施加碎混秸秆后减少了42.58%~70.27%,且施加碎混秸秆对坡面产沙的抑制效应远强于对坡面产流的控制作用;(3)地表径流中氮素流失过程以NO-3-N为主,且TN,NO-3-N和NH+4-N的流失量和养分流失模数整体表现为生物炭处理最大,碎混秸秆处理最小。[结论]紫色土坡耕地施加碎混秸秆能促渗阻流、有效控制水土及养分流失,而短期施加生物炭可能会产生负面影响。

基于SWAT模型的武强溪流域非点源污染关键源区界定与控制策略

随着点源污染的控制与处理技术日趋完善,非点源污染成为重要的水污染源。武强溪作为流入千岛湖的第二大支流,量化武强溪流域非点源污染负荷,解析非点源污染时空分布特征,提出适合削减武强溪流域污染物的最佳管理措施(best management practices,BMPs)对千岛湖水污染高效治理至关重要。该研究基于土壤水分评估工具(Soil and water assessment tool,SWAT)分析了武强溪流域径流量、总氮输出负荷量的时空分布特征,探究了不同管理措施及组合的削减效果,提出了武强溪流域非点源污染针对性的治理措施。结果表明:1)SWAT模型对于武强溪流域径流量和总氮输出负荷量的模拟具有较好的适用性,径流量校准期和验证期的决定系数(coefficient of determination,R^(2))分别为0.86、0.97,纳什系数(nash-sutcliffe coefficient,NSE)分别为0.83、0.96,百分比偏差(percent bias,PBIAS)分别为15.8%、-6.3%,总氮校准期和验证期的决定系数分别为0.87、0.74,纳什系数分别为0.63、0.66,百分比偏差分别为31.6%、21.2%;2)该流域径流量和总氮负荷主要集中在3—7月,分别占全年输出量的71.67%和75.76%。综合考虑氮的来源和流失途径,将耕地和林地面积占比大、坡度陡的子流域设置为总氮的关键污染源区。考虑调整化肥施用量/配方、改变耕作方式和设置植被缓冲带等削减非点源污染的手段,进行总氮输出负荷削减效率的情景模拟,表明10 m植被缓冲带是减少总氮输出负荷的最佳单一控制策略,总氮削减率可达到69.90%;实施综合管理措施对总氮的污染削减效果更佳,10 m植被缓冲带与施肥量减少20%可使总氮削减率达到74.79%。研究结果可为千岛湖水质管理与控制提供理论基础。

基于ReNuMa模型的武烈河氮磷负荷模拟及来源解析

武烈河是承德市工农业及居民生活用水的重要水源,开展流域污染物负荷模拟及来源解析对流域水污染控制和管理具有重要意义。采用ReNuMa模型对武烈河磷矿上游断面子流域2015—2020年的水文径流过程和全流域2018—2020年的总氮(TN)、总磷(TP)污染负荷量进行模拟,解析氮磷负荷的来源及贡献率。结果表明:(1)2018—2020年,年均TN负荷量为655.98 t,各污染来源贡献率由大到小依次为地下水(30.68%)>点源(25.63%)>腐生系统(25.16%)>沉积物源(12.85%)>地表径流(5.68%);2018—2020年,年均TP负荷量为8.12 t,各污染来源贡献率由大到小依次为沉积物源(49.58%)>点源(16.54%)>地下水(15.01%)>腐生系统(13.20%)>地表径流(5.67%)。(2)年内氮磷污染负荷入河量以非点源为主,分别占总负荷的74.37%和83.46%,点源与非点源的贡献占比受汛期和非汛期影响显著,非汛期以点源形式输入的负荷占比远超汛期(6—9月)的。本研究结果能够为流域水质改善和污染管控方案的制定提供借鉴。

南方校园降雨径流特性与植草沟净化效果研究

为研究植草沟对降雨径流污染的削减效果,于校园绿化带路段建立植草沟示范点,并在研究校园总体降雨水质和不同下垫面降雨径流特性基础上,开展植草沟对屋面雨水和地表径流中污染物的控制效果研究。结果表明,校园降雨径流中COD和NH_(3)-N浓度较高,需进行控制;且屋面雨水相较于道路径流水质污染更为严重,可能的原因是沥青油毡屋面材料中有机物的释出增加了径流水质的有机物污染程度;屋面雨水降雨初期污染较为严重,但屋面雨水与道路径流各污染物浓度随着降雨历时的延长均呈现逐渐下降并趋于稳定的变化规律;植草沟对屋面雨水COD的去除率为59%~98%,浊度的去除率为50%~83%,TP的去除率为59%~93%,NH_(3)-N的去除率为49%~88%。可见,渗透型生态植草沟作为一种植被生态排水沟渠,有助于减少不透水下垫面的覆盖程度,对控制城市面源污染效果十分显著。

控释氮肥减量对作物产量、氮素吸收与径流损失的影响

玉米蔬菜轮作是我国南方丘陵山地农区一种主要的旱地种植方式。为指导施肥,减少农业面源污染,于2020—2021年持续开展定位试验,探究控释氮肥及减氮处理对玉米小白菜轮作体系作物产量、氮素吸收残留、氮素径流损失的影响。试验共设置6个处理:CK,不施氮肥;U,常量施用普通尿素;CRU,施用等氮量的控释氮肥;90%CRU,施用控释氮肥,并较常量减氮10%;80%CRU,施用控释氮肥,并较常量减氮20%;70%CRU,施用控释氮肥,并较常量减氮30%。结果表明,与U处理相比,玉米在减氮20%条件下未显著减产,小白菜在减氮30%时均未显著减产。与U处理相比,合理施用控释氮肥可使总氮流失量显著(P<0.05)降低25.3%~43.5%,以70%CRU处理的总氮流失量最少。径流水中的氮素流失主要以颗粒氮为主,占比60.0%~67.0%。与U处理相比,除70%CRU处理外,其他施用控释氮肥处理的玉米地上部氮素积累量无显著差异;80%CRU处理的氮肥利用率显著提高9.4百分点。与U处理相比,施用控释氮肥0~80 cm各土层的总氮、铵态氮、硝态氮含量均未显著增加,不会提高土壤无机氮的流失风险。综上,在该试验条件下,与U处理相比,80%CRU处理可以在确保产量不降低的同时,减少氮素投入,降低氮素径流损失,提高肥料利用率,是试验条件下较为合理的施肥方式。

不同厚度降解地膜对坡耕地溶解态氮磷流失的影响

[目的]为探究降解地膜覆盖对径流及溶解态氮磷流失的影响。[方法]利用野外原位径流小区,以覆膜垄作花生种植为研究对象,设置0.003 mm厚聚乙烯普通地膜覆盖处理(PF)和厚度为0.006 mm(BF1),0.008 mm(BF2),0.010 mm(BF3),0.012 mm(BF4)的降解地膜覆盖处理及未覆膜处理(CK),测定不同处理在自然降雨条件下的径流量及径流中铵态氮(NH_(4)^(+)-N)、硝态氮(NO_(3)^(-)-N)、速效磷(PO_(4)^(3-)-P)浓度,分析不同厚度降解地膜覆盖条件下径流及养分流失特征。[结果](1)降解地膜降解所需时间随地膜厚度的增加而增加。(2)各处理的累积径流量由小到大为BF1<BF2<BF3<PF<CK<BF4,BF1与BF4之间差异显著(p<0.05)。(3)与CK相比,各覆膜处理均能不同程度减少氮磷累积流失量。其中,BF1处理对NH_(4)^(+)-N和NO_(3)^(-)-N流失量的削减效果较好,而BF2处理对PO_(4)^(3-)-P流失量的削减效果较好。(4)在5个覆膜处理中,BF4处理的NO_(3)^(-)-N和PO_(4)^(3-)-P流失量最高,而BF3处理的NH_(4)^(+)-N流失量最高。[结论]研究结果可为防治覆膜坡耕地水土及养分流失、解决农业面源污染等问题提供理论基础,对绿色农业发展和生态可持续发展具有重要意义。

红枫湖流域农业面源污染治理的生物地球化学垒体系构建初探

在点源污染得到有效控制后,流域内农业面源污染逐渐成为了湖库氮、磷等营养物质外源输入的主要贡献者。本研究选取红枫湖流域农田土壤为研究对象,对其添加改良剂并种植植物来构建生物地球化学垒,并对其氮、磷拦截效应进行了综合评估。研究结果表明,添加Al_(2)(SO_(4))_(3)、CaCl_(2)与钠基膨润土显著提高了土壤对NH_(4)^(+)-N、NO_(3)^(-)-N和磷的拦截率,降低其流失程度。其中,对土壤添加CaCl_(2)改性钠基膨润土并种植植被构建的生物地球化学垒,对NH_(4)^(+)-N、NO_(3)^(-)-N和磷的综合拦截效果最佳,截留率分别为87%、95%、93%。而添加了FeSO_(4)的土壤,NO_(3)^(-)-N的淋失程度增强,不宜选取。种植植物后,植物生长对土壤中氮和磷有一定的活化作用,导致模拟径流中NH_(4)^(+)-N和溶解性磷浓度较种植植物前升高,但是均低于对照组。而且种植植物后经改良的土壤单元有效磷(Olsen-P)较种植植物前显著降低,也反映出植物对土壤磷的活化利用。综上表明,通过对土壤添加Al_(2)(SO_(4))_(3)、CaCl_(2)与钠基膨润土并种植适生植物(黑麦草和白花三叶草)来构建生物地球化学垒,可以实现红枫湖小流域内的氮、磷等污染物拦截和植物生长两相促进,从而有效、持续拦截土壤氮、磷,降低其流失程度,对实现农业面源污染的可持续治理具有重要意义。

不同农作措施下紫色土坡耕地氮磷流失特征

为揭示不同农作措施下径流氮磷流失变化特征,基于2020年12场次的自然降雨产流事件,分析了顺坡无施肥(对照,CK)、顺坡混合施用有机肥和化肥(T1)、顺坡单施化肥(T2)、顺坡单施化肥增量(T3)、横坡单施化肥(T4)5种处理下径流量及径流中总氮(TN)、总磷(TP)质量浓度与流失量、氮磷比(TN/TP)的变化特征.结果表明:①各处理径流TN,TP最高质量浓度均发生在施肥后的前6次降雨,其中的4次降雨事件造成了超50%的总氮、总磷流失.②与单施化肥相比,有机肥化肥配施的径流TN,TP流失量没有显著差异,且径流TN,TP质量浓度与施肥后天数都呈极显著线性负相关(p<0.01).③和顺坡耕作相比,横坡垄作可以显著削减76.85%的径流量、75.12%的径流总氮流失量和87.97%的径流总磷流失量.④CK处理的TN/TP显著高于T2和T3(p<0.05),但与T1,T4差异无统计学意义(p>0.05),所有处理下全年超50%的TN/TP≥50,表现为磷限制.

降雨事件下洱海北部主要入湖河流污染物特征分析

通过研究2019年雨季(7—9月)洱海最主要的入湖河流污染物特征,对流域内6场次降雨下的污染物浓度与负荷进行监测,阐述6种污染物特征,计算入湖负荷,并评估对洱海的水质影响。结果表明:弥苴河是北三江流域径流与污染物入湖的主要贡献来源,径流量占北三江流域入湖总径流量的47%,氨氮、硝态氮、可溶性总氮(TDN)、正磷酸盐、可溶性总磷(TDP)和化学需氧量(COD)入湖负荷分别占总负荷的40.5%、65.0%、55.0%、55.0%、54.1%、57.1%;TDN、TDP、氨氮、COD污染负荷之间都存在着不同程度的相关性,降雨是影响氮磷等典型污染物负荷入湖的主要因素。雨季径流携带大量养分入湖使水体养分浓度升高,导致水体环境质量下降。因此在雨季控制径流携带污染物入湖,对防控洱海水质持续下降具有重要意义。

马尾松改造成香榧林对地表径流及氮磷流失的影响

掌握马尾松Pinus massoniana林转换为香榧Torreya grandis林对地表径流及氮磷流失的影响,可为人工林经营管理提供一定的基础。在浙江省东阳市林业总场设置马尾松林、香榧幼龄林和香榧中龄林3种处理径流小区,全面监测2023年地表径流量,分析径流水中不同形态氮、磷浓度,并计算养分流失量。结果表明:地表径流量大小为马尾松林(218.0 m^(3)·hm^(−2))>香榧幼龄林(206.0 m^(3)·hm^(−2))>香榧中龄林(157.0 m^(3)·hm^(−2));地表氮流失量大小为香榧幼龄林(806.56 g·hm^(−2))>香榧中龄林(582.80 g·hm^(−2))>马尾松林(159.89 g·hm^(−2)),磷流失量大小为香榧幼龄林(265.55 g·hm^(−2))>香榧中龄林(183.57 g·hm^(−2))>马尾松林(48.72 g·hm^(−2))。与马尾松林相比,香榧幼、中龄林地表径流量分别减少了5.5%和22.5%,而氮流失量增加了4.04倍和2.65倍,磷流失量增加了4.45倍和2.77倍。综上,马尾松林改造成香榧林后降低了地表径流,但增加氮、磷流失量,随着香榧林龄的增大,地表径流及氮、磷流失量随之降低。

我国中部水网区茭白潜流湿地进出水质和净化性能时变特征

本研究从小集水区角度研究了茭白潜流湿地进出水氮、磷、COD_(Cr)污染和净化性能的时变特征,结果表明,茭白潜流湿地进水氮、磷、COD_(Cr)季节波动大,其中春节期间湿地进水总氮(TN)和总磷(TP)最高,其次是农田施用化肥后产生地表径流的首月,中等降雨量下湿地进水COD_(Cr)浓度高于强暴雨下的浓度。受沉淀池的调节缓冲,湿地进水氨氮(NH_(3)-N)和硝态氮(NO_(x)^(-)-N)秋季最高,其次是春节后。湿地对小集水区氮、磷、COD_(Cr)冲击负荷均具有良好的缓冲能力和净化性能,TP、TN和COD_(Cr)平均去除率分别为(82.1±10.5)%、(72.9±8.1)%和(65.6±6.2)%;秋冬季过渡期间,因微生物降解和基质吸附的协同作用使得植物吸收氮磷的季节拐点不明显;冬季湿地具有耐受中部水网区低温的能力。不过冬季低温易于引起潜流湿地内有机氮分解转变为NH_(3)-N后被沸石等基质吸附而发生积聚,同时较长水力停留时间(HRT)下因有机质分解耗氧引起环境厌氧的加剧。此外,冬季出水溶解有机磷(DOP)比例增加。该潜流湿地可有效提升村镇面源污染排水水质,改善乡村水环境,但对上述受季节影响较大的时变因素应加强管控。

自然红壤坡地氮素在地表径流-土壤水系统迁移转化规律试验研究

目前对红壤坡地氮素流失的试验研究主要集中在人工土槽装置中监测径流和壤中流氮素,缺乏在野外自然坡情况下氮素在径流-壤中流及土壤中迁移转化过程的整体研究。为了探究天然红壤坡地氮素在地表径流-土壤水系统中的迁移转化规律,在江西水土保持生态科技园开展了3次坡地人工降雨氮素流失试验,对不同坡面及土壤初始条件下人工降雨过程中地表径流、壤中流及土壤水分状况与氮素(硝态氮和铵态氮)浓度进行了监测和分析。结果表明,初始坡面粗糙截流能力强,能减少地表径流产流量,但会导致硝态氮大量渗入土壤,造成硝态氮随土壤水的下移。自然坡地土壤中的大孔隙和土壤空间变异性是导致壤中流的主要原因,壤中流硝态氮浓度显著高于地表径流硝态氮浓度,导致壤中流硝态氮流失占比较高,第一次试验中硝态氮壤中流流失占比超过50%。相比较而言,壤中流与地表径流铵态氮浓度均较小,与铵态氮在土壤中较强的吸附能力有关。历次试验中,土壤硝态氮和铵态氮沿顺坡方向空间变异性较大,随时间变化无一致性规律,除受到坡面水力特征影响外,还受到土壤温度的影响。