Abstract Membrane technology, as an effective method for heterotrophic microalgae harvesting, is still restricted by the inevitable fouling and unclear fouling mechanisms. Accordingly, in this study, IMDLA model was developed to simulate the cake layer topography and predicate the local fouling tendency. A series of experiments and characterizations were designed to certify the feasibility of this model. The findings indicate that the cake layer formation and growth at the microscopic level was a sequential evolution process: “rivet” seed—cluster—mobile seeds interact with cluster—cluster horizontal growth—monolayer cake—multilayer cake formation—cake layer condensation. The formation of one uniform cake layer was delayed with fewer rivet seeds. Coverage can reflect the change in cake layer topography versus time in both the horizontal and vertical directions. Furthermore, by imputing the typical parameters of a one-setting filtration process, the cake layer topography in any filtration time was rapidly obtained. With the assistance of model-based visualized images, the fouling tendency was quickly confirmed, thereby improving the efficiency of providing precise control strategies. This model provides new insight into understanding local fouling behavior and works well as a useful tool to predict the algae-related membrane fouling.

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