Sinking Land Increases Risk for Thousands of Coastal Residents

“This study demonstrates that we can now measure vertical land motion at a sufficient scale to create a useful climate service that supports planning and management decisions on flooding,” said Nicholls, a professor of climate adaptation. “This approach has the potential to be applied in any city around the world, really supporting adaptation.”

Using highly accurate data points measured by space-based radar satellites, Shirzaei and his research team have built some of the world’s first high-resolution depictions of the sinking land along the coast of the entire United States. Their work has previously revealed regions of the Atlantic coast to be sinking by as much as 5 millimeters per year.

This study revealed that 24 of the 32 coastal cities are currently sinking more than 2 millimeters per year and half of those cities have areas sinking more than global seas are rising. These numbers might seem small, but when combined with sea-level rise over time, it adds up to quite a significant shift, according to Ohenhen.

“The analogy I have found that is really helpful in helping people understand this change is to think about a sinking boat,” he said. “Imagine you are in that boat with a steady leak, slowly causing the boat to sink. That leak symbolizes sea-level rise or broadly flooding. What would happen if it also starts raining? Even a minor rainfall or drizzle would cause the boat to sink more quickly than you thought it would. That’s what land subsidence does — even imperceptible millimeter land subsidence exacerbates existing coastal hazards.”

Along with the new flood projections, the study also revealed the 32 cities have a combined 131 flood control structures, such as levees, berms, or dikes, but that 50 percent of those are located on the California coast. Only three of the 11 Atlantic coast cities studied maintain levees or floodwalls.

“When we looked at it across the board, we found that there is a general unappreciation for flood protection, particularly on the Atlantic coast,” Ohenhen said. “And even the levees there often protect less than 10 percent of the city, compared to other cities on the Pacific or Gulf coasts where up to 70 percent is protected.”

Another first in the study is the consideration of racial and socioeconomic demographics related to the potentially affected areas.

In some cities examined, particularly those along the Gulf Coast, the potential increased exposure fell disproportionately on racial minorities. In other cities, the properties facing increased exposure were found to generally be of lesser value than the median property value of the area. And in a few cities, New Orleans and Port Arthur, Texas, particularly, these two demographics intersect, showing the areas with greatest potential risk to be disproportionately occupied by people of color who are also at an economic disadvantage when compared to the city as a whole.

“That was the most surprising part of the study,” Ohenhen said. “We found that there is racial and economic inequality in those areas in that there was an overrepresentation of historically marginalized groups potentially impacted as well as properties with significantly lower value than the rest of the cities. It really multiplies the potential impact to those areas and their abilities to recover from significant flooding.”

Shirzaei said he believes the study as a whole not only provides the clearest picture of potential flooding to date, but also should serve as a call to action for policymakers of those areas.

“Very often, we hear, ‘Oh, we didn’t know about land subsidence’ or, ‘We didn’t know about that other factor,’ but this study will take away those excuses from everybody,” Shirzaei said.

Travis Williams is writer/editor, Office of Research and Innovation at Virginia Tech. The article was originally posted to the website of Virginia Tech.