School of Earth and Environmental Science and Engineering, Gwangju Institute of Science and Technology, 123 Cheomdangwagi-ro, Buk-gu, Gwangju, Republic of Korea.
School of Earth and Environmental Science and Engineering, Gwangju Institute of Science and Technology, 123 Cheomdangwagi-ro, Buk-gu, Gwangju, Republic of Korea.
Chemosphere. 2017 Mar;171:468-475. doi: 10.1016/j.chemosphere.2016.12.063. Epub 2016 Dec 19.
The single particle-inductively coupled plasma-mass spectrometry was applied to characterize the aggregates of AgNPs. was applied to characterize the aggregates of AgNPs. Two sizes of citrate-AgNPs and PVP-AgNPs were used at relatively high and predicted environmental concentrations under various ionic strengths. Citrate-AgNP aggregated with increases in the ionic strength, whereas PVP-AgNPs were sterically stable. The critical coagulation concentrations were 85 mM and 100 mM NaNO for 60 nm and 100 nm citrate-AgNPs at 2 mg L as total Ag obtained by dynamic light scattering (DLS). At 2 mg L as total Ag, the mass of an aggregate gradually increased with increasing ionic strength for both citrate-AgNP during spICP-MS analyses. The average number of single particles derived from the mass in an aggregate was calculated to be 8.68 and 5.95 for 60 nm and 100 nm citrate-AgNPs at 85 mM and 100 mM NaNO, respectively after 2 h. The mass fractal dimensions were determined to be 2.97 and 2.83, further implying that the aggregate structures were very rigid and compact. Only marginal increases in the average mass and number of single particles in the aggregate units were found during 24 h under environmentally relevant AgNP concentrations. The average number of single particles constituting an aggregate unit for 60 nm and 100 nm citrate-AgNPs was 1.24 and 1.37 after 24 h at a high ionic strength. These results indicate that under environmentally relevant conditions, the collision frequency is predominant in the aggregation and that NPs are likely to encounter natural colloids such as clay and organic matter to form hetero-aggregates.
采用单颗粒感应耦合等离子体质谱法(spICP-MS)对银纳米粒子(AgNPs)的聚集体进行了表征。采用柠檬酸-AgNPs 和 PVP-AgNPs 两种不同粒径的纳米粒子,在不同离子强度下,使用相对较高和预测的环境浓度。随着离子强度的增加,柠檬酸-AgNP 发生聚集,而 PVP-AgNPs 则具有空间稳定性。通过动态光散射(DLS)得到的 60nm 和 100nm 柠檬酸-AgNPs 在 2mg/L 总 Ag 浓度下,临界聚沉浓度(CCC)分别为 85mM 和 100mM NaNO3。在 2mg/L 总 Ag 浓度下,随着 spICP-MS 分析过程中离子强度的增加,两种粒径的柠檬酸-AgNP 聚集体的质量逐渐增加。根据聚集体中质量计算得到的单个粒子的平均数量分别为 8.68 和 5.95,对于 85mM 和 100mM NaNO3 下的 60nm 和 100nm 柠檬酸-AgNPs,分别在 2 小时后。质量分形维数分别为 2.97 和 2.83,进一步表明聚集体结构非常刚性和紧凑。在环境相关的 AgNP 浓度下,24 小时内聚集体单元中单个粒子的平均质量和数量仅略有增加。在高离子强度下,24 小时后,60nm 和 100nm 柠檬酸-AgNPs 的聚集体单元中单个粒子的平均数量分别为 1.24 和 1.37。这些结果表明,在环境相关条件下,碰撞频率在聚集过程中占主导地位,并且 NPs 很可能会遇到天然胶体(如粘土和有机物)形成异质聚集体。
