Application of a cellular automaton method to model the structure formation in soils under saturated conditions: A mechanistic approach

Rupp A, Guhra T, Meier A, Prechtel A, Ritschel T, Ray N, Totsche KU (2019)


Publication Language: English

Publication Type: Journal article, Original article

Publication year: 2019

Journal

Book Volume: 7

URI: https://www.frontiersin.org/articles/10.3389/fenvs.2019.00170/abstract

DOI: 10.3389/fenvs.2019.00170

Abstract

Soil functions are closely related to the structure of soil microaggregates. Yet, the mechanisms controlling the establishment of soil structure are diverse and partly unknown. Hence, the understanding of soil processes and functions requires the connection of the concepts on the formation and consolidation of soil structural elements across scales that are hard to observe experimentally. At the bottom level, the dynamics of microaggregate development and restructuring build the basis for transport phenomena at the continuum scale. By modeling the interactions of specific minerals and/or organic matter, we aim to identify the mechanisms that control the evolution of structure and establishment of stationary aggregate properties. We present a mechanistic framework based on a cellular automaton model to simulate the interplay between the prototypic building units of soil microaggregates quartz, goethite, and illite subject to attractive and repulsive electrostatic interaction forces. The resulting structures are quantified by morphological measures. We investigated shielding effects due to charge neutralisation and the aggregate growth rate in response to the net system charge. We found that the fraction as well as the size of the interacting oppositely charged constituents control the size, shape, and amount of occurring aggregates. Furthermore, the concentration in terms of the liquid solid ratio has been shown to increase the aggregation rate. We further adopt the model for an assessment of the temporal evolution of aggregate formation due to successive formation of particle dimers at early stages in comparison to higher order aggregates at later stages. With that we show the effect of composition, charge, size ratio, time and concentration on microaggregate formation by the application of a mechanistic model which also provides predictions for soil aggregation behaviour in case an observation is inhibited by experimental limitations.

Authors with CRIS profile

Involved external institutions

How to cite

APA:

Rupp, A., Guhra, T., Meier, A., Prechtel, A., Ritschel, T., Ray, N., & Totsche, K.U. (2019). Application of a cellular automaton method to model the structure formation in soils under saturated conditions: A mechanistic approach. Frontiers in Environmental Science, 7. https://dx.doi.org/10.3389/fenvs.2019.00170

MLA:

Rupp, Andreas, et al. "Application of a cellular automaton method to model the structure formation in soils under saturated conditions: A mechanistic approach." Frontiers in Environmental Science 7 (2019).

BibTeX: Download