Improved Box Model for Simulating Pesticide Transport in the Vadose Zone with Dispersive Flux through the Boundary Layer

IF 1.6 4区环境科学与生态学 Q3 ENGINEERING, CIVIL Journal of Environmental Engineering Pub Date : 2012-05-01 DOI:10.1061/(ASCE)EE.1943-7870.0000509

X. Chu

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Abstract

AbstractA box-type transport model can be a useful tool for screening-level, long-term predictions of contamination and the relevant environmental assessment, especially when data are scarce and quick decisions are needed. In most box-type transport models, only advective flux is simulated to account for the interaction between boxes. In reality, however, significant mass transfer may also occur through the boundary between two boxes as a result of dispersion. For volatile contaminants (e.g., pesticides), the mass transfer through the boundary may involve both dissolved and vapor phases. In this study, an improved box-type analytical pesticide transport model with dispersive flux through the boundary layer (APTM-DF) was developed for simulating fate and transport of three-phase pesticides in the vadose zone, which was further divided into the surface zone, plant root zone, and deep vadose zone. The model also simulated pesticide leaching, degradation, volatilization, sorption, partition between dissolved ...

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用改进的箱形模型模拟具有分散通量通过边界层的气膜带中农药的运移

箱型输运模型可以作为筛选水平、污染长期预测和相关环境评价的有用工具，特别是在数据稀缺和需要快速决策的情况下。在大多数箱型输运模式中，只模拟对流通量来解释箱型之间的相互作用。然而，在现实中，由于色散，通过两个盒子之间的边界也可能发生重大的传质。对于挥发性污染物(如农药)，通过边界的传质可能包括溶解相和气相。本研究建立了一种改进的具有边界层弥散通量的箱式农药分析运输模型(APTM-DF)，用于模拟三相农药在渗透区的命运和运输，该渗透区进一步分为表面区、植物根区和深层渗透区。该模型还模拟了农药的淋滤、降解、挥发、吸附、溶解组分之间的分配等过程。

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来源期刊

Journal of Environmental Engineering 环境科学-工程：环境

CiteScore

4.40

自引率

0.00%

发文量

127

审稿时长

6.0 months

期刊介绍： The Journal of Environmental Engineering presents broad interdisciplinary information on the practice and status of research in environmental engineering science, systems engineering, and sanitation. Papers focus on design, development of engineering methods, management, governmental policies, and societal impacts of wastewater collection and treatment; the fate and transport of contaminants on watersheds, in surface waters, in groundwater, in soil, and in the atmosphere; environmental biology, microbiology, chemistry, fluid mechanics, and physical processes that control natural concentrations and dispersion of wastes in air, water, and soil; nonpoint-source pollution on watersheds, in streams, in groundwater, in lakes, and in estuaries and coastal areas; treatment, management, and control of hazardous wastes; control and monitoring of air pollution and acid deposition; airshed management; and design and management of solid waste facilities. A balanced contribution from consultants, practicing engineers, and researchers is sought on engineering solutions, and professional obligations and responsibilities.