Evaluating the potential of capillary rise for the migration of Pt nanoparticles in Luvisols and Phaeozems (Western Siberia)

IF 1.4 Q4 SOIL SCIENCE Soil Science Annual Pub Date : 2021-12-31 DOI:10.37501/soilsa/141621
S. Loiko, A. Konstantinov, G. Istigechev, E. Konstantinova, D. Kuzmina, V. Ivanov, S. Kulizhskiy
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引用次数: 1

Abstract

Numerous experiments with nanoparticles have recently led to a better understanding of the migration of colloids and larger particles in soils. However, it remains unclear how colloidal particles migrate in soil horizons without macropores, and whether they can move with the fl ow of capillary water. In this article, we tested the hypothesis that colloidal particles can be transported by water fl ow in capillary-sized soil pores. To test our hypothesis, column experiments with platinum nanoparticles were carried out. The columns contained undisturbed monoliths from the Luvisols and Phaeozems soil horizons in the southeast of Western Siberia. The lower part of the soil columns was immersed in a colloidal solution with platinum nanoparticles. Thus, we checked whether the nanoparticles would rise to the top of the columns. Platinum nanoparticles are a usable tracer of colloidal particle migration pathways. Due to the minimal background concentrations, platinum can be detected by inductively coupled plasma mass spectrometry (ICP-MS) in experimental samples. Due to their low zeta potential, nanoparticles are well transported over long distances through the pores. Our experiments made it possible to establish that the process of the transfer of nanoparticles with a fl ow of capillary water is possible in almost all the studied horizons. However, the transfer distances are limited to the fi rst tens of centimeters. The number of migrating nanoparticles and the distance of their transfer increase with an increase in the minimum moisture-holding capacity and decrease with an increase in the bulk density of soil horizons and an increase in the number of direct macropores. The migration of nanoparticles in capillary pores is limited in carbonate soil horizons. The transfer of colloidal particles through soil capillaries can occur in all directions, relative to the gravity gradient. Capillary transport plays an important role in the formation of the ice composition of permafrost soils, as well as in plant nutrition. Keywords
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Pt纳米颗粒在Luvisols和Phaeozems(西西伯利亚)中毛细管上升迁移潜力的评价
最近,大量的纳米颗粒实验使人们对胶体和较大颗粒在土壤中的迁移有了更好的理解。然而,胶体颗粒如何在没有大孔隙的土层中迁移,以及它们是否能随着毛细水的流动而移动,目前还不清楚。在本文中,我们验证了胶体颗粒可以在毛细管大小的土壤孔隙中通过水流运输的假设。为了验证我们的假设,我们进行了铂纳米颗粒柱实验。这些石柱包含了来自西伯利亚西部东南部Luvisols和Phaeozems土壤层的未受干扰的巨石。土柱下部浸泡在含铂纳米粒子的胶体溶液中。因此,我们检查了纳米颗粒是否会上升到柱的顶部。铂纳米颗粒是胶体颗粒迁移途径的可用示踪剂。由于铂的背景浓度极低,因此可以通过电感耦合等离子体质谱法(ICP-MS)在实验样品中检测到铂。由于它们的zeta电位低,纳米颗粒可以很好地通过孔隙长距离运输。我们的实验表明,在几乎所有研究的层位中,纳米颗粒随毛细管水流动的转移过程都是可能的。然而,传输距离被限制在最初的几十厘米。迁移纳米粒子的数量和迁移距离随最小持湿量的增加而增加,随土层容重的增加和直接大孔数量的增加而减少。在碳酸盐土层中,纳米颗粒在毛细管孔隙中的运移受到限制。相对于重力梯度,胶体颗粒通过土壤毛细血管的转移可以在各个方向发生。毛管运输在永久冻土区冰成分的形成和植物营养中起着重要作用。关键字
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来源期刊
Soil Science Annual
Soil Science Annual SOIL SCIENCE-
CiteScore
2.50
自引率
6.70%
发文量
0
审稿时长
29 weeks
期刊介绍: Soil Science Annual journal is a continuation of the “Roczniki Gleboznawcze” – the journal of the Polish Society of Soil Science first published in 1950. Soil Science Annual is a quarterly devoted to a broad spectrum of issues relating to the soil environment. From 2012, the journal is published in the open access system by the Sciendo (De Gruyter).
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