Hydrochemical and microbial community characteristics and the sources of inorganic nitrogen in groundwater from different aquifers in Zhanjiang, Guangdong Province, China.

Groundwater from different aquifers in the Zhanjiang area suffers from different degrees of nitrogen pollution, which poses a serious threat to the health of urban and rural residents as well as the surrounding aquatic ecological environment. However, neither the water chemistry and microbial community characteristics in different aquifer media nor the sources of inorganic nitrogen pollution have been extensively studied. This study integrated water quality parameters, dual isotopes (δ15N–NO 3 − and δ18O–NO 3 −), and 16S rRNA data to clarify the hydrochemical and microbial characteristics of loose rock pore water (LRPW), layered bedrock fissure water (LBFW), and volcanic rock pore fissure water (VRPFW) in the Zhanjiang area and to determine inorganic nitrogen pollution and sources. The results show that the hydrochemistry of groundwater in different aquifers is complex and diverse, which is mainly affected by rock weathering and atmospheric precipitation, and the cation exchange is strong. High NO 3 − concentration reduces the richness of the microbial community (VRPFW). There are a large number of bacteria related to nitrogen (N) cycle in groundwater and nitrification dominated the N transformation. A quarter of the samples exceeded the relevant inorganic nitrogen index limits specified in the drinking water standard for China. The NO 3 − content is highest in VRPFW and the NH 4 + content is highest in shallow loose rock pore water (SLRPW). In general, NO 3 −/Cl−, dual isotope (δ15N–NO 3 − and δ18O–NO 3 −) data and MixSIAR quantitative results indicate manure and sewage (M&S) and soil organic nitrogen (SON) are the main sources of NO 3 −. In LRPW, as the depth increases, the contribution rate of M&S gradually decreases, and the contribution rate of SON gradually increases. The results of uncertainty analysis show that the UI 90 values of SON and M&S are higher. This study provides a scientific basis for local relevant departments to address inorganic nitrogen pollution in groundwater. [Display omitted] • Groundwater chemistry mainly reflects an oxidizing environment. • There are a large number of bacteria related to N cycle in groundwater. • Mean 58.0%, 37.0% and 11.5% of the nitrate were contributed from M&S, SON and NF. • In LRPW, the contribution rate of M&S and SON is related to the depth change. • Uncertainties of source contributions decreased in the order: SON > M&S > NF > AP. [ABSTRACT FROM AUTHOR]