Rapid lake Michigan shoreline changes revealed by UAV LiDAR surveys

The recent record-breaking Laurentian Great Lakes water levels have led to severe erosion along many shorelines, but quantification of this erosion has not yet been widely reported. In this paper, novel shoreline measurements of Lake Michigan erosion, using a LiDAR-equipped unmanned aerial vehicle (UAV). The vehicle surveyed two beaches, Dune Acres and Beverly Shores, along the Indiana shoreline of southern Lake Michigan over the period 2018-2019, which are compared to existing aircraft-based LiDAR surveys. The UAV surveys reveal extensive shoreline erosion and recession at both beaches since the low water conditions of 2012-2013, with both beaches losing 70.7 and 64.8 m(3)/m of dry beach volume. Shoreline recession over this period was nearly 35 m for both beaches. In the period 2018-2019, the UAV measurements reveal continued beach erosion and the transition of beach topography to a steep, actively eroding foredune. Storm erosion resolved by short interval surveys highlight the episodic nature of shoreline erosion, with 8 m3/m of material lost over a stormy two-week period at Dune Acres. While large, the erosion and recession observed at both beaches is in keeping with limited historical observations of shoreline change during high water episodes. However, the observed overall shoreline recession slopes of 1:29 (water level rise : recession) are much less than historical slopes, suggesting that the beaches are not yet in equilibrium with the high water levels and that erosion will continue in the foreseeable future while lake levels remain high.

Automated summary

The study used a UAV equipped with LiDAR to measure erosion on the shorelines of Lake Michigan, revealing extensive erosion and recession at Dune Acres and Beverly Shores beaches since the low water conditions of 2012-2013. The measurements from 2018-2019 show continued beach erosion and the transition of beach topography to actively eroding foredunes, indicating that erosion will persist in the foreseeable future while lake levels remain high.