Zhang Changyong, Yoon Hongkyu, Werth Charles J, Valocchi Albert J, Basu Nandita B, Jawitz James W
Department of Civil and Environmental Engineering, University of Illinois at Urbana Champaign, 205 N. Mathew Ave., MC-250, Urbana, IL 61801, USA.
J Contam Hydrol. 2008 Nov 14;102(1-2):49-60. doi: 10.1016/j.jconhyd.2008.05.007. Epub 2008 May 27.
Nonaqueous phase liquid (NAPL) dissolution was studied in three-dimensional (3D) heterogeneous experimental aquifers (25.5 cm x 9 cm x 8.5 cm) with two different longitudinal correlation lengths (2.1 cm and 1.1 cm) and initial spill volumes (22.5 ml and 10.5 ml). Spatial and temporal distributions of NAPL during dissolution were measured using magnetic resonance imaging (MRI). At high NAPL spill volume, average effluent concentrations initially increased during dissolution, as NAPL pools transitioned to NAPL ganglia, and then decreased as the total NAPL-water interfacial area decreased over time. Experimental results were used to test six dissolution models: (i and ii) a one-dimensional (1D) model using either specific NAPL-water interfacial area values estimated from MR images at each time step (i.e., 1D quasi-steady state model), or an empirical mass transfer (Sh') correlation (i.e., 1D transient model), (iii and iv) a multiple analytical source superposition technique (MASST) using either the NAPL distribution determined from MR images at each time step (i.e., MASST steady state model), or the NAPL distribution determined from mass balance calculations (i.e., MASST transient model), (v) an equilibrium streamtube model, and (vi) a 3D grid-scale pool dissolution model (PDM) with a dispersive mass flux term. The 1D quasi-steady state model and 3D PDM captured effluent concentration values most closely, including some concentration fluctuations due to changes in the extent of flow reduction. The 1D transient, MASST steady state and transient, and streamtube models all showed a monotonic decrease in effluent concentration values over time, and the streamtube model was the most computationally efficient. Changes during dissolution of the effective NAPL-water interfacial area estimated from imaging data are similar to changes in effluent concentration values. The 1D steady state model incorporates estimates of the effective NAPL-water interfacial area directly at each time point; the 3D PDM does so indirectly through mass balance and a relative permeability function, which causes reduced water flow through high saturation NAPL regions. Hence, when model accuracy is required, the results indicate that a surrogate of this effective interfacial area is required. Approaches to include this surrogate in the MASST and streamtube models are recommended.
在具有两种不同纵向相关长度(2.1厘米和1.1厘米)以及初始溢出体积(22.5毫升和10.5毫升)的三维(3D)非均质实验含水层(25.5厘米×9厘米×8.5厘米)中研究了非水相液体(NAPL)的溶解情况。使用磁共振成像(MRI)测量了溶解过程中NAPL的空间和时间分布。在高NAPL溢出体积下,溶解过程中平均流出物浓度最初会增加,这是因为NAPL池转变为NAPL条带,然后随着总NAPL - 水界面面积随时间减小而降低。实验结果用于测试六种溶解模型:(i和ii)一维(1D)模型,一种使用在每个时间步从MR图像估计的特定NAPL - 水界面面积值(即1D准稳态模型),另一种使用经验传质(Sh')相关性(即1D瞬态模型);(iii和iv)多重解析源叠加技术(MASST),一种使用在每个时间步从MR图像确定的NAPL分布(即MASST稳态模型),另一种使用从质量平衡计算确定的NAPL分布(即MASST瞬态模型);(v)平衡流管模型;以及(vi)具有弥散质量通量项的3D网格尺度池溶解模型(PDM)。1D准稳态模型和3D PDM最能紧密捕捉流出物浓度值,包括由于流量减少程度变化引起的一些浓度波动。1D瞬态、MASST稳态和瞬态以及流管模型都显示流出物浓度值随时间单调下降,并且流管模型计算效率最高。根据成像数据估计的有效NAPL - 水界面面积在溶解过程中的变化与流出物浓度值的变化相似。1D稳态模型在每个时间点直接纳入有效NAPL - 水界面面积的估计值;3D PDM则通过质量平衡和相对渗透率函数间接纳入,这导致通过高饱和度NAPL区域的水流减少。因此,当需要模型准确性时,结果表明需要这种有效界面面积的替代物。建议采用将这种替代物纳入MASST和流管模型的方法。
