Division of Atmospheric Sciences, Desert Research Institute, 2215 Raggio Parkway, Reno, NV 89512, USA.
Department of Civil and Environmental Engineering, Michigan Technological University, Houghton, MI 49931, USA.
Chemosphere. 2015 Sep;134:98-105. doi: 10.1016/j.chemosphere.2015.03.087. Epub 2015 Apr 27.
We characterized distributions of 23 polycyclic aromatic hydrocarbons (Σ23PAH) and nine oxygenated PAHs (Σ9OPAH) in four remote forests. We observed highest Σ23PAH and Σ9OPAH concentrations in a coniferous forest in Florida, particularly in organic layers which we attributed to frequent prescribed burning. Across sites, Σ23PAH and Σ9OPAH concentrations strongly increased from surface to humidified organic layers (+1626%) where concentrations reached up to 584 ng g(-1). Concentrations in mineral soils were lower (average 37 ± 8 ng g(-1)); but when standardized per unit organic carbon (OC), PAH/OC and OPAH/OC ratios were at or above levels observed in organic layers. Accumulation in litter and soils (i.e., enrichment factors with depth) negatively correlated with octanol-water partition coefficients (Kow) and therefore was linked to water solubility of compounds. Concentrations of Σ9OPAHs ranged from 6 ± 6 ng g(-1) to 39 ± 25 ng g(-1) in organic layers, and from 3 ± 1 ng g(-1) to 11 ± 3 ng g(-1) in mineral soils, and were significantly and positively correlated to Σ23PAHs concentrations (r(2) of 0.90) across sites and horizons. While OPAH concentrations generally decreased from organic layers to mineral soil horizons, OPAH/OC ratios increased more strongly with depth compared to PAHs, in particular for anthrone, anthraquinone, fluorenone, and acenaphthenequinone. The strong vertical accumulation of OPAH relative to OC was exponentially and negatively correlated to C/N ratios (r(2)=0.67), a measure that often is used for tissue age. In fact, C/N ratios alone explained two-thirds of the variability in OPAH/OC ratios suggesting particularly high retention, sorption, and persistency of OPAHs in old, decomposed carbon fractions.
我们描述了四个偏远森林中 23 种多环芳烃(Σ23PAH)和 9 种含氧多环芳烃(Σ9OPAH)的分布情况。我们观察到佛罗里达州一个针叶林中Σ23PAH 和 Σ9OPAH 的浓度最高,特别是在有机层中,我们认为这是由于频繁的规定性燃烧所致。在各个地点,Σ23PAH 和 Σ9OPAH 的浓度从表面到增湿的有机层(增加 1626%)强烈增加,在那里浓度达到 584ng/g。矿物土壤中的浓度较低(平均 37±8ng/g);但是当按单位有机碳(OC)标准化时,PAH/OC 和 OPAH/OC 比值达到或超过有机层中观察到的水平。在凋落物和土壤中的积累(即与深度相关的富集因子)与辛醇-水分配系数(Kow)呈负相关,因此与化合物的水溶性有关。Σ9OPAH 浓度在有机层中为 6±6ng/g 至 39±25ng/g,在矿物土壤中为 3±1ng/g 至 11±3ng/g,在各地点和各层中与 Σ23PAH 浓度呈显著正相关(r2 为 0.90)。虽然 OPAH 浓度通常从有机层到矿物土壤层逐渐降低,但与 PAHs 相比,OPAH/OC 比值随深度增加的幅度更大,特别是对于蒽酮、蒽醌、芴酮和苊醌。与 OC 相比,OPAH 垂直积累与 C/N 比值(r2=0.67)呈指数负相关,C/N 比值通常用于测量组织年龄。实际上,C/N 比值单独解释了 OPAH/OC 比值变化的三分之二,这表明 OPAH 在旧的、分解的碳组分中具有特别高的保留、吸附和持久性。
