This dataset contains two subsets of animations corresponding to particle tracking simulations of the Upper Missouri River near Wolf Point, MT comparing larval transport through the upper and lower sub-reaches of the larger model reach. Animations do not contain audio and depict particles moving from the top of the reach (left side) to the bottom of the reach (right side). A total of 96 animations are included corresponding to a combination of 1 of both reaches (upper or lower), 1 of 16 discharges (185-635 cms, at increments of 30 cms), and 1 of 3 vertical movement methods (active60pct, active75pct, or passive).

This dataset contains two subsets of animations corresponding to particle tracking simulations of the Upper Missouri River near Wolf Point, MT. Animations do not contain audio and depict particles moving from the top of the reach (left side) to the bottom of the reach (right side). The first subset are animations from simulations of a July 1, 2019, larval drift experiment. A total of 9 animations are included with each corresponding to the combination of 1 of 3 vertical movement methods (active60pct, active75pct, or passive) and 1 of 3 lateral eddy viscosity scenarios (LEVx0p5, LEVx1, or LEVx2). The second subset contains animations corresponding to particle simulations for the upper and lower sub-reaches of the larger model reach. A total of 96 animations are included corresponding to a combination of 1 of both reaches (upper or lower), 1 of 16 discharges (185-635 cms, at increments of 30 cms), and 1 of 3 vertical movement methods (active60pct, active75pct, or passive).

This dataset contains hydrodynamic metrics from particle tracking simulations for two sub-reaches of the Upper Missouri River near Wolf Point, MT. The upstream reach is referred to as the “upper” reach while the downstream reach is referred to as the “lower” reach. Simulations were performed for 16 flows in the range of 185-635 cms at increments of 30 cms.

This dataset contains hydrodynamic metrics from particle tracking simulations for two sub-reaches of the Upper Missouri River near Wolf Point, MT. The upstream reach is referred to as the “upper” reach while the downstream reach is referred to as the “lower” reach. Simulations were performed for 16 flows in the range of 185-635 cms at increments of 30 cms.

This dataset contains supporting files for particle tracking simulations of the Upper Missouri River near Wolf Point, MT.

This dataset contains supporting files for particle tracking simulations of the Upper Missouri River near Wolf Point, MT.

This dataset contains animations of particle tracking of the July 1, 2019, larval drift experiment on the Upper Missouri River near Wolf Point, MT. Animations do not contain audio and depict particles moving from the top of the reach (left side) to the bottom of the reach (right side). A total of 9 animations are included with each corresponding to the combination of 1 of 3 vertical movement methods (active60pct, active75pct, or passive) and 1 of 3 lateral eddy viscosity scenarios (LEVx0p5, LEVx1, or LEVx2).

This dataset contains animations of particle tracking of the July 1, 2019, larval drift experiment on the Upper Missouri River near Wolf Point, MT. Animations do not contain audio and depict particles moving from the top of the reach (left side) to the bottom of the reach (right side). A total of 9 animations are included with each corresponding to the combination of 1 of 3 vertical movement methods (active60pct, active75pct, or passive) and 1 of 3 lateral eddy viscosity scenarios (LEVx0p5, LEVx1, or LEVx2).

These two datasets contain metrics from hydrodynamic and particle tracking simulations for two sub-reaches of the Upper Missouri River near Wolf Point, MT. The upstream reach is referred to as the “upper” reach while the downstream reach is referred to as the “lower” reach. Simulations were performed for 16 flows in the range of 185-635 cms at increments of 30 cms.

This dataset contains two- and quasi-three-dimensional hydrodynamic model outputs from the Flow and Sediment Transport with Morphologic Evolution of CHannels (FaSTMECH) hydrodynamic model in the open-source binary Visualization Toolkit (VTK) format (https://vtk.org/). The simulations were run at flows in the range of 185-635 cms at increments of 30 cms. This set of flow conditions pertains to the base lateral eddy viscosity scenario referred to as LEVx1 in Call et al., 2023. Files can be opened using the open-source software program Paraview: (https://www.paraview.org/).