Find in Library

Abstract The mechanisms controlling transport and retention of microplastics (MPs) in riverine systems are not understood well. We investigated the impact of large roughness elements (LREs) on in-stream transport and retention of the ubiquitous polystyrene-microplastics (PS-MPs). Scaled experiments were conducted with and without LREs under various shear Reynolds numbers (Re*) in an ecohydraulics flume. Our results, for the first time, demonstrated a clear dependence of the MPs’ velocity on Re* in LREs-dominated channel. Two distinct regimes and thresholds were identified: lower Re* (≤ 15,000) regime corresponding to higher velocities of MPs ( $${U}_{MPs}^{*}$$ U MPs ∗ > 0.45), and higher Re* (> 15,000) to lower $${U}_{MPs}^{*} ($$ U MPs ∗ ( < 0.45). The presence and higher density of LREs increased Re*, decreased $${U}_{MPs}^{*}$$ U MPs ∗ , and enhanced the PS-MPs capture. The LREs-generated turbulence kinetic energy (TKE) was found to be a good predictor of PS-MPs transport and retention rates, indicating the effectiveness of LREs in retaining PS-MPs in streams and rivers.