基于多种方法的宝坻新井水位异常分析

针对天津宝坻新井(117.4°E, 39.7°N)水位阶变异常, 选取该井及周边水体进行水化学分析, 结果表明宝坻新井水主要为大气降水成因, 存在一定的水岩作用, 周边水体与宝坻新井水之间没有明显水力联系; 采用有限单元法模拟了水坝泄水对宝坻新井的加卸载影响, 结果显示水坝泄水的应变量不足以引起宝坻新井水位的大幅阶变; 通过调和分析及含水层参数计算可知2017年以来宝坻新井潮汐参数及含水层水文介质参数未发生明显变化。 据此推测, 宝坻新井水位异常可能与局部应力小幅调整过程中宝坻断裂及其次级断裂蠕动有关。 本文采用的多种方法结合的异常分析思路可为今后判别地下水位异常干扰提供参考。     

天津王3井逸出氦气浓度变化特征分析

对天津王3井逸出氦气浓度日变化和年变化特征进行了分析,结果表明：①王3井逸出氦气浓度日变幅背景值在0.0012%—0.0036%之间,日变幅在冬季偏高;②在大多数观测日的10—18时左右,王3井逸出氦气浓度日变化曲线有“波谷”,但没有明显的“波峰”,但在部分观测日逸出氦气浓度日变化曲线的“波谷”却不明显,王3井逸出氦气浓度日变化形态不属于“固体潮”型;③王3井逸出氦气浓度年变化曲线呈上升的“双峰双谷”似“潮汐”形态,一般在6月、12月左右出现“波峰”,3月、9月左右出现“波谷”,相比较而言,“波峰”更显著。通过对井孔所在地的地质构造、大气温度、降水、同井孔水位、周边地热资源开采等因素的分析,笔者认为王3井逸出氦气浓度的变化基本不受大气温度、降水和同井孔水位变化的影响,主要与井孔所在地的断层活动性和周边地热资源的开采有关。     

四川北川川41井动水位动态特征及干扰分析

本文收集和梳理了四川北川川41井（以下简称川41井）2017—2022年动水位资料,分析了该井所处构造地质背景、环境干扰因素、固体潮效应以及动水位年变动态特征。结果表明：川41井动水位、中层水温受降水影响显著,年变形态受气压、固体潮效应及环境因素影响较小,不同观测仪器记录显示中层水温存在相似的年变动态特征,相同仪器记录显示动水位、中层水温多年年变形态略有不同,其原因可能与降雨量有关。通过分析,可以为数据跟踪分析和地震异常识别提供支撑。     

天津王3井水位突升异常的调查与研究

从观测系统、自然环境、场地环境、人为干扰和地球物理事件等5个方面,对自2015年9月13日起天津王3井水位持续上升异常进行了调查与研究,结果表明:1该异常是受东北方向距其约2.6 km的京津新城供热有限公司钻井注水的影响,非震兆异常;2王3井水位对深井注水的响应较灵敏,无明显时间滞后,水位变化形态呈上升的趋势;3持续注水条件下,王3井水位持续上升,无"饱和"状态,短时停止注水后,王3井水位没有明显的下降恢复变化;4新钻井孔抽水时,王3井水位呈下降的变化形态,下降幅度与出水量成正比,进一步印证了该井水位突升异常系受钻井注水的影响。     

辽宁新民井静水位转折上升变化成因分析

新民静水位自2016年7月22日开始出现转折上升变化,至2016年9月水位最大上升幅度达1.2m,但同井水温变化平稳,未出现同步变化。通过对水位井观测系统、区域地质特征和周边环境等进行调查发现,水位井北东约50m处的大型挖土坑大量积水可能是造成水位转折上升变化的主要原因。结合该区地质特征、井水地球化学特征以及区域降水特征分析结果,显示水位转折上升变化与附近土坑开始大量积水在水源、空间、时间和强度上都存在明显的相关性。故认为新民井静水位大幅度转折上升变化为附近土坑降雨积水干扰所致,排除为地震前兆异常的可能。     

滇南地区近期水位趋势上升异常机理初探

2014年以来,滇南地区高大、开远和易门3口井的井水位出现趋势上升现象。通过开展井孔周边地下水开采情况的调查、降水影响的定量排除、井孔含水层系统应力状态的定量计算、周边区域构造活动的分析以及井孔水体化学组分的分析等工作,认为易门井的水位年动态主要受控于降水,2003年以来的趋势下降和2014年的趋势转折上升与大椿树工业园区的深井开挖抽水密切相关;高大井和开远井的井水位自2014年以来的趋势转折上升现象不完全受控于降水,但与周边地下水的开采亦无直接联系,可能与近几年该区域南北向强挤压为主的构造活动有关。      

广西北流Ms5.2地震地下流体异常分析

整理分析了北流M5.2地震震中周边300 km范围广西境内的地下流体观测资料,发现北海咸田、桂平、南宁石埠3个流体井的水位观测数据震前出现了前兆异常,3个异常井均分布在震中周边200 km范围内。采用观测曲线对比和小波相干分析等方法并结合异常井所处区域的地质构造,系统分析了异常的开始时间、持续时间、变化形态以及异常在时间-频率域内的相关特性。经分析认为,北海咸田、桂平、南宁石埠3个井的水位观测在震前出现的年尺度变化为较可靠的中期前兆异常。     

德令哈台尕海井水位异常分析

针对2018年青海德令哈台尕海井水位破年变异常,系统梳理和分析该井相关资料,发现该井两套水位仪运行稳定、数据一致性非常好,而这段时期异常与降雨和气压不相关,以及井孔附近地区的视应力值较高,表明该地区地壳应力水平进一步增强。利用水位变幅、去趋势和一阶差分分析,结果显示,该项异常信度较高,反映该区域构造活动信息,是周边两次中等强度地震的共同前兆,属于中短期异常。     

黑龙江省德都地震发生前后依安102井水位异常及其分析

概述了依安102井水位、声响的映震异常特点,指出了异常水位、异常声响,并非人为因素造成,不受大气降水过程的干扰影响,提出了孕发地震的区域应力—应变异常场同映震水位、映震声响之间,存在着内在的密切联系,结论认为,依安102井的水位异常、声响异常,同孕发德都地震的应力—应变区域异常相呼应,依安102井所在地处于德都地震孕震应力场直接影响范围。     

河北黄骅井水位阶变异常研究

收集整理河北省地下流体观测井网黄骅井2005年以来的水位资料,结合周边的河间井和衡水井的水位资料,以河北昌黎4.2级地震为例,对黄骅井水位阶变异常进行分析。结果表明:2015年以来黄骅井水位阶变异常与其周边的河间井和衡水井的水位异常变化有一定的对应关系,水位阶变是构造活动引起的,与昌黎4.2级地震有一定的相关性,是一次短期前兆异常。     

基于水化学的永清井水温异常分析

在地下流体研究中,判定地下水异常的首要任务是区别地下水是受浅层物质补给的影响还是受深层介质活动的影响。本文通过对永清井及周边多次样品采集与测试,获得水化学组分和氢氧稳定同位素观测数据;通过对地下水样品数据对比分析、水化学组分及氢氧稳定同位素与大气降水线、水温数据分析,认为永清井水温的多次异常变化不是受干扰影响;通过对水温的异常变化与地震的对应关系的分析,认为永清井水温异常可能与3次地震有关。      

芜湖皖28井水位异常综合分析

针对2011年芜湖皖28井水位破年变异常,系统梳理该井相关资料,利用水位变幅、相关性分析及相对变差率进行分析.结果表明,该项异常信度较高,反映区域构造活动信息,是周边几次中等强度地震的共同前兆.通过剩余曲线、从属函数等数学方法,对该井历年水位观测数据进行异常识别.研究表明,该井水位异常主要表现为短期异常特征,与该井孔西北、西南侧中等地震有较好的对应关系.     

Canopy interception of apple orchards should not be ignored when assessing evapotranspiration partitioning on the Loess Plateau in China

Canopy interception is one of the most important processes in an ecosystem, but it is still neglected when assessing evapotranspiration (ET) partitioning in apple orchards on the Loess Plateau in China. To explore the importance of canopy interception, we monitored two neighbouring apple orchards on the Loess Plateau in China, one 8‐year‐old and the other 18‐years old at the start of the study, from May to September for four consecutive years (2013–2016). We measured parameters of canopy interception (I) including precipitation, throughfall, stemflow, leaf area index, transpiration (T), and soil evaporation (S) to quantify ET. The importance of canopy interception was then assessed by comparing the relationship between water supply (precipitation) and water demand (ET), calculated with and without considering canopy interception (T + S and T + S + I, respectively). Tree age clearly influenced canopy interception, as estimates of annual canopy interception during the study years in the younger and older orchards amounted to 22.2–29.4 mm and 26.8–39.9 mm, respectively. Daily incident rainfall and rainfall intensity in both orchards were significantly positively correlated with daily canopy interception in each year. The relationship between annual precipitation and annual ET (calculated with and without consideration of canopy interception) in the younger orchard differed during 2015 and 2016. Ignoring canopy interception would result in underestimation of annual ET in both apple orchards and hence incorrect evaluation of the relationship between water supply and water demand, particularly for the younger orchard during 2015 and 2016. Thus, for a complete understanding of water consumption in apple orchards in this and similar regions, canopy interception should not be ignored when assessing ET partitioning.     

张掖MS 5.0地震前山丹地震台地电阻率异常分析

通过分析山丹地震台地电阻率资料发现,在2019年9月16日张掖M_S 5.0地震前地电阻率出现了明显的异常变化,即2016年11月开始EW测道观测数据出现年变畸变异常,年变幅度几近消失,该异常持续至2018年年底。采用傅里叶滑动去年变分析发现,同段年变消失,去年变后数值出现超阈值异常;采用矩平处理方法分析发现,2016年11月至2018年10月观测值小于矩平拟合值,出现低值异常。研究表明,该异常可能与2019年9月16日张掖M_S 5.0地震有关。     

Identifying the source of atmospheric moisture over arid deserts using stable isotopes (2H and 18O) in precipitation

Precipitation is a major component of the hydrologic cycle in arid desert areas. To date, however, few studies have been conducted on investigating the isotope characteristics and moisture sources of precipitation in arid desert environments. The Alxa Desert Plateau is a critical arid desert area in North China. This study is the first to analyse the stable isotopic composition of precipitation to identify the sources of atmospheric moisture over this plateau. Our results show that the δD and δ¹⁸O values of precipitation across the plateau change greatly at both daily and monthly timescales, and exhibit seasonal variations. Among the main meteorological parameters, atmospheric temperature is the most predominant factor controlling the isotopic composition and the δD–δ¹⁸O relationship of local precipitation. Analyses of the precipitation isotopes with the Hybrid Single Particle Lagrangian Integrated Trajectory (HYSPLIT) model reveal that (a) the westerly and polar moisture sources are the dominant controls on summer and winter precipitation and (b) the evaporation of local lake water significantly affects winter precipitation even though it only represents a small amount. Based on the isotope data of 2013–2016 precipitation, a local meteoric water line (LMWL) is derived: δD = (8.20 ± 0.22)·δ¹⁸O + (8.15 ± 2.16)‰ for the study site. Compared to the global meteoric water line, the LMWL has a greater slope and lower d‐excess. This can be explained by admixing of atmospheric moisture resulting from the evaporation of local lake water. Based on this LMWL, we are able to trace that groundwater of the Badain Jaran Desert originates from the surrounding mountains with altitudes of <4,000 m. The newly derived LMWL shows that the recharge altitudes of desert groundwater are overestimated on the basis of the previous LMWLs. This study not only provides insights into the hydrological cycle but also offers guidance for water resource management in arid desert areas of China. Additionally, this study provides techniques that can be applied to the analyses of precipitation isotopes in similar arid regions of the world.     

Isotopic composition of precipitation in a topographically steep,seasonally snow‐dominated watershed and implications of variations from the global meteoric water line

The local meteoric water line (LMWL), the functional relationship between locally measured values of δ¹⁸O and δ²H in precipitation, represents the isotopic composition of water entering hydrologic systems. The degree to which the LMWL departs from the global meteoric water line (GMWL), moreover, can reveal important information about meteoric sources of water (e.g. oceanic or terrestrial) and atmospheric conditions during transport. Here we characterize the isotopic composition of precipitation within an experimental watershed in the Western US that is subject to large topographic and seasonal gradients in precipitation. Interpreting the hydrometeorologic and spatial controls on precipitation, we constructed a seasonally weighted LMWL for southwestern Idaho that is expressed by the equation δ²H = 7.40 × δ¹⁸O ? 2.17. A seasonally weighted LMWL that is based on weighting isotopic concentrations by climatic precipitation volumes is novel, and we argue better represents the significant seasonality of precipitation in the region. The developed LMWL is considerably influenced by the semiarid climate experienced in southwest Idaho, yielding a slope and y‐intercept lower than the GMWL (δ²H = 8 × δ¹⁸O + 10). Moderate to strong correlations exist between the isotopic composition of precipitation from individual events and surface meteorologic variables, specifically surface air temperature, relative humidity, and precipitation amount. A strong negative correlation exists between the annual average isotopic composition of precipitation and elevation at individual collection sites, with a lapse rate of ?0.22‰/100 m. Copyright © 2016 John Wiley & Sons, Ltd.     

The hydrological response of surface water to recent climate variability: A remote sensing case study from the central tropical Pacific

For small tropical islands with limited freshwater resources, understanding how island hydrology is influenced by regional climate is important, considering projected hydroclimate and sea level changes as well as growing populations dependent on limited groundwater resources. However, the relationship between climate variability and hydrologic variability for many tropical islands remains uncertain due to local hydroclimatic data scarcity. Here, we present a case study from Kiritimati, Republic of Kiribati (2°N, 157°W), utilizing the normalized difference vegetation index to investigate variability in island surface water area, an important link between climate variability and groundwater storage. Kiritimati surface water area varies seasonally, following wet and dry seasons, and interannually, due to hydroclimate variability associated with the El Niño/Southern Oscillation. The NIÑO3.4 sea surface temperature index, satellite‐derived precipitation, precipitation minus evaporation, and local sea level all had significant positive correlations with surface water area. Lagged correlations show sea level changes and precipitation influence surface water area up to 6 months later. Differences in the timing of surface water area changes and variable climate‐surface water area correlations in island subregions indicate that surface hydrology on Kiritimati is not uniform in response to climate variations. Rather, the magnitude of the ocean–atmosphere anomalies and island–ocean connectivity determine the extent to which sea level and precipitation control surface water area. The very strong 2015–2016 El Niño event led to the largest surface water area measured in the 18‐year data set. Surface water area decreased to pre‐event values in a similarly rapid manner (<6 months) after both the very strong 2015–2016 event and the 2009–2010 moderate El Niño event. Future changes in the frequency and amplitude of interannual hydroclimate variability as well as seasonal duration will thus alter surface water coverage on Kiritimati, with implications for freshwater resources, flooding, and drought.     

Complex sources of air-soil-water pollution processes in the Miyun reservoir region

The comprehensive impact of atmospheric dry deposition and wet deposition and the pollution sources of farmlands, mining areas, and towns along the Baihe River on the water quality of Miyun reservoir is investigated from the angle of the complex sources of air-soil-water pollution processes, in the context of the 1990-2001 precipitation chemical data at Shangdianzi station--a WMO regional background air pollution monitoring station 15 km far from the Miyun reservoir, in conjunction with the atmospheric dry deposition and wet deposition data of the 2002-2003 Beijing City Air Pollution Observation Field Experiment (BECAPEX). Analysis results suggest that the major ions in precipitation in the Miyun reservoir region in this period were SO, NO, NH and Ca2+; wet acid deposition quantity of Miyun reservoir in the summer half year (April to September) was greater than the quantity in the winter half year (October to March), and the annual wet acid deposition in the reservoir exhibited a rising trend with the mean 1038.45 t, the maximum 1766.31 t occurred in 1996, and the minimum 604.02 t in 1994; the long-term averaged pH of atmospheric precipitation in the Miyun reservoir region was 5.20, i.e. weakly acidic, and the interannual variation of pH values displayed a falling trend. pH values of water body at various depths in the Miyun reservoir were all greater than 7.0, but they exhibited vertical and horizontal nonhomogeneity, and at the same region pH decreased vertically with depth; the 2002 and 2003 annual dustfalls in the Miyun reservoir were 13513.08 t and 3577.64 t, respectively, and the spring dustfall was the number one in a year, accounting for the 61.91% and 44.56% of the annual totals of 2002 and 2003, respectively. Because the atmospheric dry deposition and wet depositions contain multiple types heavy metal elements and harmful elements, they to some extent exacerbated the eutrophication, acidification and potential heavy metal pollution of the reservoir water. The above comprehensive analysis results reveal the complex source characters of the air-soil-water pollution process and the multi-sphere interaction effect. Besides, summer (rainy season) is a season when local soil pollutants enter the water system of reservoir after being washed out by torrential rain or heavy precipitation, which starts the air-soil- water chaining pollution processes, and results in the water pollution of rivers and reservoirs. It is found from the statistical analysis in this paper that the water pollution of Miyun reservoir was correlated with the rain wash-out and confluent flow in the peripheral and upstream local region of the reservoir, and the pollutant concentration of the reservoir water was significantly correlated with the upstream local region precipitation. Those correlation characters reveal the effect of the air-soil-water multi-spheric interaction of reservoir water pollution process. This paper presents the point of view of the complex source analysis of reservoir water pollution and a technical approach for tracing the spatial distribution of the upstream pollution source of the water systems of reservoir.     

Streamflow trends and climate linkages in the source region of the Yellow River,China

Much of the discussion on hydrological trends and variability in the source region of the Yellow River centres on the mean values of the mainstream flows. Changes in hydrological extremes in the mainstream as well as in the tributary flows are largely unexplored. Although decreasing water availability has been noted, the nature of those changes is less explored. This article investigates trends and variability in the hydrological regimes (both mean values and extreme events) and their links with the local climate in the source region of the Yellow River over the last 50 years (1959–2008). This large catchment is relatively undisturbed by anthropogenic influences such as abstraction and impoundments, enabling the characterization of widely natural, climate‐driven trends. A total of 27 hydrological variables were used as indicators for the analysis. Streamflow records from six major headwater catchments and climatic data from seven stations were studied. The trend results vary considerably from one river basin to another, and become more accentuated with longer time period. Overall, the source region of the Yellow River is characterized by an overall tendency towards decreasing water availability. Noteworthy are strong decreasing trends in the winter (dry season) monthly flows of January to March and September as well as in annual mean flow, annual 1‐, 3‐, 7‐, 30‐ and 90‐day maxima and minima flows for Maqu and Tangnag catchments over the period 1959–2008. The hydrological variables studied are closely related to precipitation in the wet season (June, July, August and September), indicating that the widespread decrease in wet season precipitation is expected to be associated with significant decrease in streamflow. To conclude, decreasing precipitation, particularly in the wet season, along with increasing temperature can be associated with pronounced decrease in water resources, posing a significant challenge to downstream water uses. Copyright © 2011 John Wiley & Sons, Ltd.