Identification of Groundwater Nitrate Contamination from Explosives Used in Road Construction: Isotopic, Chemical, and Hydrologic Evidence

Explosives used in construction have been implicated as sources of NO3– contamination in groundwater, but direct forensic evidence is limited. Identification of blasting-related NO3– can be complicated by other NO3– sources, including agriculture and wastewater disposal, and by hydrogeologic factors affecting NO3– transport and stability. Here we describe a study that used hydrogeology, chemistry, stable isotopes, and mass balance calculations to evaluate groundwater NO3– sources and transport in areas surrounding a highway construction site with documented blasting in New Hampshire. Results indicate various groundwater responses to contamination: (1) rapid breakthrough and flushing of synthetic NO3– (low δ15N, high δ18O) from dissolution of unexploded NH4NO3 blasting agents in oxic groundwater; (2) delayed and reduced breakthrough of synthetic NO3– subjected to partial denitrification (high δ15N, high δ18O); (3) relatively persistent concentrations of blasting-related biogenic NO3– derived from nitrification of NH4+ (low δ15N, low δ18O); and (4) stable but spatially variable biogenic NO3– concentrations, consistent with recharge from septic systems (high δ15N, low δ18O), variably affected by denitrification. Source characteristics of denitrified samples were reconstructed from dissolved-gas data (Ar, N2) and isotopic fractionation trends associated with denitrification (Δδ15N/Δδ18O ≈ 1.31). Methods and data from this study are expected to be applicable in studies of other aquifers affected by explosives used in construction.

在建筑工程中使用的炸药已被确认为地下水NO3-污染的来源，但直接的法医学证据却极为有限。识别与爆破相关的NO3-可能因农业和废水处理等其他NO3-来源的干扰而变得复杂，以及受影响NO3-的传输和稳定性之水文地质因素。本研究采用水文地质学、化学、稳定同位素和物质平衡计算，评估了新罕布什尔州一公路建设工地周边有记录爆破活动的地区的地下水NO3-来源和传输。研究结果揭示了地下水对污染的多种响应：（1）在好氧地下水中溶解未爆炸NH4NO3爆破剂产生的合成NO3-（低δ15N，高δ18O）的快速突破和冲洗；（2）部分反硝化作用后的合成NO3-的延迟和减少突破（高δ15N，高δ18O）；（3）由NH4+硝化产生的与爆破相关的生物源NO3-的相对持久浓度（低δ15N，低δ18O）；（4）与化粪池补给一致，但空间上变化的生物源NO3-浓度，受反硝化作用影响各异。通过溶解气体数据（Ar，N2）和与反硝化作用相关的同位素分馏趋势（Δδ15N/Δδ18O ≈ 1.31）重建了反硝化样品的源特征。本研究的方法和数据预期可应用于受建筑工程中使用的炸药影响的其他含水层的研究。