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1.
对江西省九江地震台2号观测井井水、大气降水、马尾水泉水及天花井水库水的常量化学组分、氢氧同位素及氚活度数据进行分析,讨论九江台地下水的水化学类型、成因及补给循环过程,揭示九江地震台2号井对构造活动响应灵敏的地球化学特征。研究发现九江台2号井水水化学类型为HCO3-Ca·Mg型;氢氧同位素指示九江台2号井水属于大气降水成因型,补给高程为647 m;氚活度分析给出的地下水年龄显示九江台2号井既有老水补给又有近10年的新水补给。分析结果表明,九江台2号井既有浅表水特征又有深循环水的特征,暗示两个不同补给源的含水层通过不同循环路径上升至浅表,而深部含水层可能携带部分深部构造活动的氡,并在瑞昌—阳新MS4.6地震前出现较显著的异常信息。 相似文献
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以昆明地震台井水、渔塘水为研究对象,通过水质、同位素分析方法并结合水文地质、构造地质等资料,探究井水地球化学特征及意义,以及井水与渔塘水之间的水力关系。研究结果显示:昆明地震台井水、渔塘水水化学类型为HCO3—Ca型,水质受含水层和隔水层岩性控制,与2018年相比2020年井水水化学特征发生了显著变化,K+、HCO3-浓度降低,这反映了昆明地震台井—含水层渗透性有所增加;SO42-、Cl-浓度的增加则表明昆明地震台井水会受到人为干扰。研究区构造活动平稳,井水为未成熟水,演化程度较低,因含水层渗透性增强和人为干扰,自2018年7月至2020年11月昆明地震台井水—岩作用有所增强,表现为δD、δ18O富集,Mg2+浓度升高。井水补给来源为大气降水,补给区位于观测井正北的石关一带。渔塘水与昆明地震台井水间存在水力关系,在分析地表水对昆明地震台井的影响时应予以考虑,但渔塘水不是影响井水的主要因素。 相似文献
3.
应力、应变或地震活动会打破地壳中流体原有的水-岩平衡状态,引起地下流体化学组分和同位素的变化。根据河北何家庄流体观测井氢氧同位素和离子化学组分测试结果,分析了该井的地球化学特征及与构造活动的关系。由氢氧同位素结果及高程效应,判定井水来源主要为大气降水,大气降水沿断裂裂隙渗入,深循环后温度增加,经溶滤作用等形成热水;按照舒卡列夫分类法,何家庄井水为Cl-Na.Ca型。受2015年9月14日昌黎M4.2地震的影响,区域应力变化使井孔断裂岩石裂隙增大,深部热水上涌,引起何家庄井水离子组分和氢氧同位素组成等发生变化。研究结果表明,对何家庄井流体地球化学特征进行分析,可以为井孔附近断裂构造活动和地震前兆异常分析提供地球化学依据。 相似文献
4.
在地震地下流体观测研究中,基于氢氧同位素示踪技术研究地下水补给源及循环过程是常用的技术方法之一。本文给出了九江地震台2号观测井水、大气降水、周边水库水及高山泉水等样品的氢氧同位素测定结果,表明地下水δ~(18)O测值介于-7.59‰~-6.09‰,平均值-6.99‰,δD测值介于-45.22‰~-39.69‰,平均值-42.32‰,变异异数分别为0.09、0.16;大气降水δ~(18)O测值介于-13.00‰~-1.27‰,平均值-4.74‰,δD测值介于-96.13‰~-4.74‰,平均值-46.87‰,变异异数分别为0.40、0.56,与降水相比,地下水氢氧同位素变化更为稳定。大气降水氢氧同位素2017年5~10月表现为明显的降水效应,2018年11~4月表现为明显的温度效应,而地下水氢氧同位素并未表现出明显的降水效应和温度效应。氢氧同位素及过量氘揭示地下水在下渗补给前经历了明显的蒸发分馏作用,并与围岩进行~(18)O交换,δ~(18)O与δD计算得出的补给高程分别约为647、440m。九江台观测井的观测层地下水为大气降水成因的构造裂隙水,属于大气成因型且循环过程为较稳定的裂隙水补给并形成承压自流井。 相似文献
5.
《地震研究》2020,(4)
对昭通地区12口流体观测井及其周边5个地表水体进行取样测试,分析其水化学组分和氢氧同位素,确定该地区流体观测井的地球化学背景特征,为该区流体测项的跟踪分析提供基础支撑。水岩平衡结果显示:相较于其它观测井,昭阳一中井地下水水岩平衡状态更接近于部分成熟水,表现为地下水补给过程缓慢,水岩作用程度较高;其余观测井均处在未成熟水阶段,表现出补给路径较短,水岩相互作用较弱等特点。氢氧同位素组成显示:研究区内大多数流体观测井补给源均为大气降水,但补给方式略有差异。水化学组分演化过程显示:自2014年以来,大多数井含水层水体未发生新的水岩作用过程,并且与其附近的河流水力联系密切。 相似文献
6.
在位于依兰—伊通断裂北段的4个地震流体观测站及其附近地区采集了19个水样,对水样的水化学组分及氢氧同位素组成进行分析,对该地区地下水类型及成因等地球化学特征进行了研究。结果表明:(1)取样点水温变化为8.5℃~23.4℃,水样的矿化度为32~568 mg/L,全部为低矿化度水;(2)水样分为10种化学类型,水-岩反应均未达到完全平衡;通河台井水属于部分平衡水,具有深部来源特征;(3)δD和δ18O值的分别为-100.24‰~-65.46‰和-13.47‰~-8.53‰,表明所测水样的补给源主要为大气降水。 相似文献
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8.
通过对内蒙古东部—辽宁西部地区主要活动断裂带及其周边25个泉、井、河流、水库取样点的氢氧同位素组成及主要离子含量进行测试,讨论了该地区地下水的物质来源及其与地震活动的关系。结果表明:(1)研究区地下水主要来源于大气降水。水样TDS范围为40.14~1 720.87 mg/L,低矿化度(TDS<200 mg/L)水样的离子主要来源于岩石溶解和大气输入,而其它水样的离子主要来源于岩石溶解和深部流体,大气输入相对很小,但各测区深部流体的贡献有明显差别;(2)低温热水、中温热水及高温热水均为花岗岩裂隙水,其水化学类型为硫酸型和重碳酸型,富含碱性长石的火成岩溶解导致地下水富Na+,周围构造活动相对活跃。其中,RST水样更接近深部储水层的热水特征,表明其受深部流体影响为主;(3)NS和AES水样位于阴山北部高原区,为CO2过饱和水,属重碳酸钠型;AES受干旱区季节性降水淋滤表层可溶盐、水体的蒸发以及深部富CO2流体混入造成其矿化度最高;(4)KZHQ和BYNE水样分别处于碳酸盐岩含水层和含砾砂岩含水层,由于Ca2+<... 相似文献
9.
根据辽东南地区10处泉水、井水的水化学组分和氢、氧同位素组成,讨论了地下水的化学类型、成因及其动态变化特征.测得水样的TDS范围为105.38~809.05 mg·L-1,主要阳离子为Na+、Ca2+,主要阴离子为SO42-、HCO3-;δ18O和δD值分别为-9.25‰~-7.53‰和-66.43‰~-54.33‰.根据Piper分类法,所采水样可划分为9种水化学类型.样品的氢氧同位素组成表明,研究区泉/井水主要来源于大气降水,并有深部流体的混入.在花岗岩分布区,大气降水经水-岩相互作用演化成F-含量较高的SO4·HCO3-Na型、HCO3-Na型或SO4-Na型水,为花岗岩裂隙水的典型特征;金州的水样因受碳酸盐岩层影响和海水入侵形成Cl-Ca·Mg型水;砂砾岩中的长石类矿物水解和粘土矿物的离子交换作用使得Na+和Ca2+相对富集形成HCO3-Na·Ca型水.地震发生前后部分泉/井出现了K+、F-和Cl-离子浓度的异常变化,这可能是深部流体混入浅层地下水造成的.K+、Mg2+、Ca2+、Cl-离子浓度变化对辽宁地震活动的响应较好.研究结果可用于辽宁地区流体地球化学地震监测、预测和水环境研究. 相似文献
10.
针对2008年汶川MS 8.0地震后江苏地区的地震观测井水位上升现象,选取了苏18井和井周边地表水进行了水化学和物理分析,研究了井水位异常与地表水和大气降水的补给关系,讨论了井水补给来源及其与高邮-宝应MS 4.9地震的关系。离子含量和氢氧同位素结果表明,苏18井水主要为大气降水成因,存在一定的水岩作用。应用氯离子分析降水对地下水的补给,其结果显示大气降水在井水补给源中占了重要份额,井水位的突然上升与同期降水量增加有一定关系。水库水与苏18井水之间存在水力联系,大气降水增多致使水库水位升高,对该井水位变化有一定的影响。综合分析认为,大气降水的增多致使水库蓄水增加,水库水通过侧向渗透补给造成了2011年苏18井的水位显著升高。苏18井异常不是由构造活动引起的,作为高邮-宝应MS 4.9地震的前兆依据不充分。水化学和物理结合的方法为今后判别地下水位异常干扰提供了依据。 相似文献
11.
以南昌地震台2008年以来的地电场观测资料为研究对象,在对比分析观测数据质量的基础上,阐明影响地电场观测的主要干扰因素,并分析了造成观测资料质量不高的原因,主要是由于观测场地不平,6个电极所处的埋设环境存在较大差异引起的。 相似文献
12.
武汉及周边地区数字化形变观测资料质量分析 总被引:1,自引:1,他引:0
对武汉及周边地区2007—2016年数字化形变观测资料进行长期背景跟踪分析,认为形变观测资料的日均变化幅度、M_2波潮汐因子均方差、长周期拟合相对噪声水平等指标变化稳定,资料可信度高,DSQ型水管倾斜仪观测精度与资料稳定性均优于SS-Y型铟瓦棒洞体应变仪。对武汉狮子山及黄石地震台形变观测数据典型变化进行系统总结与跟踪分析,发现主要受到人为干扰(调零、标定)、自然环境(降雨、气压)和观测系统故障等因素影响。 相似文献
13.
大同地震监测中心站配备2套GM4-XL磁通门磁力仪进行地磁观测,探头置于同一地下地磁房。自2017年以来,2套仪器每年夏秋季均存在不同程度的数据漂移现象。从数据连续率、完整率及台站背景噪声、数据预处理等角度,对2017年以来观测数据进行质量评价。通过与山西省其他台站地磁数据进行差值检测,结合地磁房附近地质条件、地下地磁室及观测墩建设、降雨等因素,分析认为,大同地震监测中心站地磁观测数据漂移的原因在于,夏秋季降雨致土层渗水,玻璃钢罩密封性较差,探头室地面积水,造成观测墩基不稳,使得置于观测墩上的仪器探头水平状态改变,进而引起观测数据发生漂移。 相似文献
14.
通过对夏县地震台水氡观测数据分析,找出可能存在的干扰因素与水氡观测数据之间的变化规律。分析结果表明,地下水开采是影响夏县地震台水氡观测的主要因素,气温、气压对热水井溶解水氡测值几乎没有影响。 相似文献
15.
High-elevation mountains often constitute for basins important groundwater recharge sources through mountain-front recharge processes. These processes include streamflow losses and subsurface inflow from the mountain block. However, another key recharge process is from irrigation practices, where mountain streamflow is distributed across the irrigated piedmont. In this study, coupled groundwater fluctuation measurements and environmental tracers (18O, 2H, and major ions) were used to identify and compare the natural mountain-front recharge to the anthropogenically induced irrigation recharge. Within the High Atlas mountain front of the Ourika Basin, Central Morocco, the groundwater fluctuation mapping from the dry to wet season showed that recharge beneath the irrigated area was higher than the recharge along the streambed. Irrigation practices in the region divert more than 65% of the stream water, thereby reducing the potential for in-stream groundwater recharge. In addition, the irrigation areas close to the mountain front had greater water table increases (up to 3.5 m) compared with the downstream irrigation areas (<1 m increase). Upstream crops have priority to irrigation with stream water over downstream areas. The latter are only irrigated via stream water during large flood events and are otherwise supplemented by groundwater resources. These changes in water resources used for irrigation practices between upstream and downstream areas are reflected in the spatiotemporal evolution of the stable isotopes of groundwater. In the upstream irrigation area, the groundwater stable isotope values (δ18O: −8.4‰ to −7.4‰) reflect recharge by the diverted stream water. In the downstream irrigation area, the groundwater isotope values are lower (δ18O: −8.1‰ to −8.4‰) due to recharge via the flood water. In the nonirrigation area, the groundwater has the highest stable isotope values (δ18O: −6.8‰ to −4.8‰). This might be due to recharge via subsurface inflow from the mountain block to the mountain front and/or recharge via local low altitude rainfall. These findings highlight that irrigation practices can result in the dominant mountain-front recharge process for groundwater. 相似文献
16.
Across equatorial Africa, increasing demand for groundwater has raised concerns about resource sustainability and has highlighted the need for reliable estimates of groundwater recharge. Recharge investigations in this environment are typically inhibited by a shortage of good quality meteorological and hydrogeological records. Moreover, when recharge studies are attempted they tend to rely on a single technique and frequently lack corroborating evidence to substantiate recharge predictions. In recent studies undertaken in the Aroca catchment of the Victoria Nile basin in central Uganda, the timing and magnitude of recharge determined by a soil moisture balance approach are supported by stable isotope data and groundwater flow modelling. The soil moisture balance study reveals that recharge averages in the order of 200 mm year−1 and is more dependent on the number of heavy (more than 10 turn day−1) rainfall events than the total annual volume of rainfall. Stable isotope data suggest independently that recharge occurs during the heaviest rains of the monsoons, and further establish that recharge stems entirely from the direct infiltration of rainfall, an assumption implicit in the soil moisture balance approach. Deforestation over the last 30 years is shown to have more than doubled the recharge estimate. Aquifer flow modelling supports the recharge estimates but demonstrates that the vast majority (over 99%) of recharging waters must be transmitted by the aquifer in the regolith rather the underlying bedrock fractures which have traditionally been developed for rural water supplies. 相似文献
17.
Ricardo Sánchez-Murillo Germain Esquivel-Hernández José L. Corrales-Salazar Laura Castro-Chacón Ana M. Durán-Quesada Manuel Guerrero-Hernández Valeria Delgado Javier Barberena Katia Montenegro-Rayo Heyddy Calderón Carlos Chevez Tania Peña-Paz Saúl García-Santos Pedro Ortiz-Roque Yaneth Alvarado-Callejas Laura Benegas Antonio Hernández-Antonio Marcela Matamoros-Ortega Lucia Ortega Stefan Terzer-Wassmuth 《水文研究》2020,34(11):2660-2675
Numerous socio-economic activities depend on the seasonal rainfall and groundwater recharge cycle across the Central American Isthmus. Population growth and unregulated land use changes resulted in extensive surface water pollution and a large dependency on groundwater resources. This work combines stable isotope variations in rainfall, surface water, and groundwater of Costa Rica, Nicaragua, El Salvador, and Honduras to develop a regionalized rainfall isoscape, isotopic lapse rates, spatial–temporal isotopic variations, and air mass back trajectories determining potential mean recharge elevations, moisture circulation patterns, and surface water–groundwater interactions. Intra-seasonal rainfall modes resulted in two isotopically depleted incursions (W-shaped isotopic pattern) during the wet season and two enriched pulses during the mid-summer drought and the months of the strongest trade winds. Notable isotopic sub-cloud fractionation and near-surface secondary evaporation were identified as common denominators within the Central American Dry Corridor. Groundwater and surface water isotope ratios depicted the strong orographic separation into the Caribbean and Pacific domains, mainly induced by the governing moisture transport from the Caribbean Sea, complex rainfall producing systems across the N-S mountain range, and the subsequent mixing with local evapotranspiration, and, to a lesser degree, the eastern Pacific Ocean fluxes. Groundwater recharge was characterized by (a) depleted recharge in highland areas (72.3%), (b) rapid recharge via preferential flow paths (13.1%), and enriched recharge due to near-surface secondary fractionation (14.6%). Median recharge elevation ranged from 1,104 to 1,979 m a.s.l. These results are intended to enhance forest conservation practices, inform water protection regulations, and facilitate water security and sustainability planning in the Central American Isthmus. 相似文献