Remote Sensing Technique Captures Details of Hurricane Ian鈥檚 Aftermath
An ariel view of the structural damage on Southwest Florida鈥檚 Estero Island in the aftermath of Hurricane Ian. (Photo credit: Ryan Sloan, 91制片厂)
Category 4 Hurricane Ian made landfall in Florida鈥檚 Lee County on Sept. 28, 2022, battering the region with wind speeds of 155 miles per hour and storm surge up to 13 feet 鈥 the highest storm surge documented in Southwest Florida in the past 150 years.
In the aftermath of a disaster, rapidly assessing damage is critical for rescue, recovery and emergency planning. Damage assessments are typically conducted through field reconnaissance deployments, which can be labor-intensive, costly and risky. Moreover, field-based emergency response assessments can be hindered by delays and other setbacks due to the severity of the damage and the inability to access the hardest hit areas.
Using remote sensing technology, 91制片厂 researchers have developed a novel technique that provides rapid, high-resolution assessments of detailed damage after a hurricane. Using aerial imagery data and LiDAR, they identified the hardest-hit areas of Southwest Florida鈥檚 Estero Island and estimated the extent of structural damage. Researchers also compared pre- and post-storm structural or morphological changes to the beach. The study is the first to apply an advanced multi-faceted approach that links damage assessment to post-storm change in the structure of barrier islands.
Results of the study, published in the , identified a total of 2,427 structures on Estero Island that were impacted by Hurricane Ian, with 170 structures suffering extensive damage. A single store was the only structure in the study area classified as 鈥渘ot affected.鈥
Using data from the Lee County tax appraiser, researchers estimated the total assessed value of the heavily damaged structures at more than $200 million.
Overall, 734 buildings had 30 to 50 percent structural damage, the majority of which were single-family and multi-unit residences. Researchers identified 158 buildings that were severely damaged with partial or complete roof failure.
The highest percentage of damaged structures occurred on the central and northern portions of the island, where most of the structures were single-family and multi-family residences. Most of the structures that experienced 0 to 30 percent damage were classified as low-rise condominiums (three stories or less), commercial shopping centers and stores. Among the 鈥渟everely damaged鈥 and 鈥渄estroyed鈥 structures were seven mobile home subdivisions.
鈥淓mploying this advanced technology of aerial imagery and airborne LiDAR enabled us to collect extensive data from Hurricane Ian鈥檚 aftermath and analyze large-scale datasets rather quickly,鈥 said , Ph.D., senior author, chair and an associate professor in the within 91制片厂鈥檚 Charles E. Schmidt College of Science.
The 2,427 structures were built between 1963 to 2019. The buildings in the areas where less damage was observed were built between 1963 and 1981. Similarly, in the areas of heavy damage, the majority of the buildings were built between 1963 and 1981. The spatial distribution of ground elevation and year built indicated no apparent trends associated with these two variables.
鈥淲e found no correlation between the ground elevation or year built for the extent of damages in this analysis, which emphasizes the role of the extreme inundation and importance of other factors contributing to vulnerability,鈥 said Roberts Briggs. 鈥淩esults from our study can help improve disaster planning by developing new policies and guidelines for coastal development in some of the most vulnerable and storm-exposed areas.鈥
Areas associated with little to no damage were spatially clustered in the southern and central portion of the island, with most structures concentrated on the landward side of the barrier island.
鈥淭he southern portion of Estero Island contains multiple saltwater marshes,鈥 said Leanne Hauptman, first author and a Ph.D. student in 91制片厂鈥檚 Department of Geosciences. 鈥淏ecause of these saltwater marshes, storm-wave energy may been substantially dissipated by friction by the time the waves reached the barrier interior, potentially lessening the impact on the structures in that area.鈥
Findings also showed substantial post-storm debris and sand deposition across the entire island, and a notable deposition of sediment across the roadways and on the backside of the barrier, which is not readily returned seaward to the beach under post-storm conditions. Ponding water also was found hundreds of meters inland near buildings and other structures, providing evidence of the extent of inundation resulting from the storm.
鈥淎lthough our study focused on Estero Island, this new remote sensing approach is generalizable,鈥 said Diana Mitsova, Ph.D., corresponding author, chair and professor, 91制片厂 Department of Urban and Regional Planning within the Charles E. Schmidt College of Science and an affiliate professor, 91制片厂 Department of Geosciences. 鈥淎s this technology continues to advance and becomes more readily available, it will offer a broad range of high-resolution coverage that can help prioritize emergency response efforts immediately following catastrophic natural disasters and other events.鈥
For the study, analysis of beach morphology was conducted by creating profile graphs to visualize elevation changes over a continuous distance. To measure structural damage, researchers use LiDAR tools to extract building footprints and building heights pre- and post-storm. Building footprints were overlaid on the post-imagery to estimate the total number of damaged buildings as well as the level of damage to each structure.
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