Abstract
Flood exposure has been linked to shifts in population sizes and composition. Traditionally, these changes have been observed at a local level providing insight to local dynamics but not general trends, or at a coarse resolution that does not capture localized shifts. Using historic flood data between 2000-2023 across the Contiguous United States (CONUS), we identify the relationships between flood exposure and population change. We demonstrate that observed declines in population are statistically associated with higher levels of historic flood exposure, which may be subsequently coupled with future population projections. Several locations have already begun to see population responses to observed flood exposure and are forecasted to have decreased future growth rates as a result. Finally, we find that exposure to high frequency flooding (5 and 20-year return periods) results in 2-7% lower growth rates than baseline projections. This is exacerbated in areas with relatively high exposure to frequent flooding where growth is expected to decline over the next 30 years.
Similar content being viewed by others
Introduction
Much of the world’s population is exposed to some kind of extreme weather event exacerbated by climate change1. These events have been directly connected to impacts on human systems including economic, social, and political crises2. Adding to the problem’s complexity, humans have concurrently settled in areas with climate risk that were previously thought to have low, or no, exposure3. Since 1980, there have been over 300 disaster events responsible for $2.3 trillion in damages across the US4. Nearly half of these damages can be attributed to flooding and tropical cyclones4. As such, understanding the ways that flood risk impacts human systems is of great importance.
Increasing flood exposure and losses are expected to drive population and demographic shifts in the US. Some projections estimate that globally, up to 216 million people may migrate due to climate change by 20505. It is now generally accepted that sea level rise (SLR) could lead to large migrations as impacted communities move away from rising flood risk6,7,8,9. Previous research has documented an observed association between such flood exposure and the shifting demographics of an area as drivers of an emerging phenomenon termed climate gentrification10. It is worth noting that at a global scale, these types of population shifts are much more common and are most often linked to involuntary migration due to climate exposure11 or, more colloquially, climate migration12.
Past research on climate migration related to flood risk often focuses on relatively long-distance relocations, such as across county borders6,8,13,14,15. This existing research has found that areas with high climate risk (or exposure) are currently seeing an influx of population and growing16,17,18,19,20,21. However, increasing evidence suggests that a more voluntary form of climate migration is associated with flood risk at a more local scale, taking into account property and neighborhood level variations in exposure10,22,23. Much of this research is focused on the stressors of lower impact but persistent flood events rather than the less likely shock from extreme flood events24.
Climate migration is likely to increase over time, with projections suggesting between 4.2 and 13.1 million people in the U.S. may be at risk of inundation from sea level rise by 2100, and suggests that in the absence of adaptation there are likely to be large migrations on a similar scale to the Great Migration in the twentieth century25, during which 4 million people may have moved26. With 21.8 million properties currently having some exposure to flooding within the Contiguous United States (CONUS), and 23.5 million expected to have flood exposure by the middle of the century27, it is important to understand how migration and settlement patterns may change over time6,28,29,30.
When climate impacts are evaluated over longer time periods, it is likely that a combination of direct (e.g. property inundation) and indirect (e.g. neighbors moving away) factors will contribute to migration6,31. In addition, these migrations are likely to occur along existing pathways15,28,32, thus likely constituting an enhanced normal out-migration6. Such expectations are driven by migration theory, which draws heavily on the economics of location through an evaluation of factors referred to as push and pull factors33. In the case of climate migration, the emphasis is generally put on the push factors as they relate to exposure and movement away from an area e.g11. However, the lack of such exposure may also serve as a pull factor34.
To understand climate risk, it is important to clarify the definitions of risk components: hazard, exposure, and vulnerability. In this context, hazard refers to the probability and severity of physical environmental events. Exposure is concerned with the physical proximity to those hazards, capturing the degree to which assets, people, and systems are exposed. Finally, vulnerability refers to the susceptibility of an exposed system to the impacts of a hazard, often encompassing various social, economic, or political factors that influence the ability to cope with a hazard event35,36. Below, the focus of this research highlights that a flood exposure metric is the primary differentiating factor used in the modeling framework.
Within that context, much existing research is limited by the availability of high-quality flooding information to help define at risk populations. Within the U.S., national scale flood information is often limited to historical records or flood maps provided by government agencies, while high-resolution flood risk information is often only locally available. In addition, the effect of adaptation on flood risk is considerable37, and built adaptation should be accounted for as they generally exist in areas at the intersection of high levels of exposure and population concentration. Furthermore, high-resolution flood risk information for multiple return periods (RPs) and sources (pluvial, fluvial, and coastal) allow for a more complex investigation of how populations react to different flood severities, frequencies, and sources. For example, past research has shown that communities tend to rebound after a devastating but low-likelihood event, but the degree of recovery varies by demographic and socioeconomic characteristics13,14. Other research has shown that frequent and less severe flooding is correlated with more persistent issues of decreased property valuations and population redistribution in favor of higher ground10,38.
Many studies looking to estimate displaced populations due to flooding rely on an underlying assumption that exposure corresponds directly with migration. Estimates for SLR displacement are highly variable due to differing types of exposure relating to who is at risk of migration. Common at risk definitions include populations (1) in low-elevation coastal areas, (2) in 100-year floodplains, and (3) predicted to be inundated in the future under SLR (Hauer et al.7 provides a general discussion of these approaches–which typically prioritize future understandings of coastal flooding, with less, or no, emphasis on inland flooding). However, in addition to inundation, there are multiple other important aspects to consider. Those considerations revolve around the fact that, depending on the context, residents will react differently to the same level of flood exposure. In addition, there may be external differences related to the manifestation of impacts (i.e. indirect vs. direct), the existence of amenities, and the simple fact that heightened risk exists in some of the most amenity heavy areas of the US. For example, many low-lying areas within 100-year floodplains possess ample water resources, thus potentially attracting people to live there for reasons that correlate with the same factors (flooding) that may be used to inform out-migration39. Research that equates inundated populations to the migration population may be overly simplistic if they do not adequately include other covariates in their modeling.
While there is some understanding that populations respond differently to severe and rare flooding, compared with more frequent flooding, this research has focused on single events and investigations of singular types (sources, severities, or probabilities) of flooding. For example, while Hauer6 contributed towards understanding inland population impacts due to flood-related migration, the source of flood information used was still solely from SLR inundation. Advancements in agent based modeling (ABM) are moving towards modeling household level migration under climate change40,41,42, but it has been limited to flooding increases from SLR and requires strong assumptions and extensive existing research to define inputs (for example, amenity values must be previously defined, and thus in these applications are limited), and are computationally intensive due to the use of individual flood simulations. In addition, much of this previous research forecasting future growth in flood exposure uses independent projections of populations and flooding, and does not investigate the historical relationship between the two to modify future population projections19,20,21.
In this work, we estimate localized shifts in population counts (2000–2020) across small area administrative units (specifically, Census Blocks) across the CONUS, accounting for exposure from multiple flood sources, depths, and probabilities. This research is explicitly focused on the migration component of population change and has taken care to include covariates known to be related to differential levels of fertility and mortality in the research design, captured by social, economic, and spatial factors. In addition, the research design explicitly removes any changes in fertility and mortality by focusing only on 2 decades of data. Given the possible endogeneity of the treatment (flood exposure), we use propensity score matching to balance unobserved covariates that affect both the treatment and the outcome and synthetically create a control-treatment design. This is then followed by a statistical modeling process that isolates the historical flood-population relationship. Building upon that retrospective analysis, a secondary component of this research projects population levels out 30 years in the future, relying on existing population population projections along Shared Socioeconomic Pathways (SSPs)43, climate-adjusted flood hazard projections44,45, and historically derived relationships between flood exposure and population redistribution.
Results
Future national level population projections adjusted for historic climate impact
The future population projections indicate that when introducing the climate consequences derived from the modeling process, there are overall negative impacts on population growth in areas with high flood exposure. The climate consequence across the country is evaluated in Table 1, where the population projections for blocks which are defined as relatively highly exposed to flooding (in respect to three different indicators, defined in the following sentence) are shown to decrease, or have decreased growth, when compared to their respective baseline projections. Blocks were categorized into dichotomous groups for comparison based on the following definitions: if a block has higher than average proportion of inundated properties in the (1) 5, 20, or 100-year RPs, (2) 20-year RP, and (3) 5-year RP.
Table 1 highlights that areas with exposure to more frequent flooding report a more pronounced negative climate consequence associated with the integration of observed population responses from historic flood risk. Specifically, blocks with relatively high exposure in the 5-year RP report a negative 7 point difference in the rate of growth in the baseline projections (5.7% cumulative growth) versus those corrected by the integration of the climate consequences (1.5% cumulative loss). Similarly, results show that communities with high inundation in the 20-year RP will also grow at slower rates than the current SSP population projections estimate with a 1.4 point loss on the cumulative rate of growth in the baseline projections (10%) versus the cumulative rate of growth in the climate adjusted projections (8.6%). Finally, the national number consolidating the impact of all RPs is collectively negative with about a 2 point difference in the cumulative rate of growth in the baseline population projections (~14%) versus the cumulative growth in those same areas following the integration of the climate consequence (~12%).
Current and future variations in absolute population exposed
Figure 1 shows the spatial distribution of the percentage of future population changes that is due to the integration of the modeled climate consequence. The differentiation is interesting to note because, while there is a climate consequence associated with the tipping points identified in this research, there are also larger macro level drivers of population change that are built into the baseline SSP2 trajectory used as the baseline for this forecast. Again, given the highly localized nature of flood risk, the acute impact needed to be explored at a higher resolution.
In order to look at these results at a higher resolution, the block level population forecasts were examined for select areas known to have high, and uneven, levels of flood exposure in both the coastal and inland context. One such area due to coastal flooding is Miami-Dade County, FL, presented in Figs. 2 and 3. A second example of inland flooding, Cincinnati, OH, is presented and discussed for comparison in the Supplementary Information. These examples illustrate the integration of the modeled climate consequence into future population projections at a localized level. At a summary level, Miami-Dade shows that the inclusion of flood exposure coefficients in future projections are related to a negative effect on population growth. However, it should be noted that the relationship is not specifically linear in either case. Instead, there appears to be a tipping point across the different RPs as the proportion of properties that are exposed in the census block reaches a point in which population change begins to decline based on the empirically derived relationships. In contrast, an opposite overall effect exists in Cincinnati, OH where areas of higher inundation are actually more likely to grow versus areas less exposed. A discussion of potential reasons behind this inland pattern is further discussed in the Supplementary Information around Supplementary Fig. 6.
Figure 2 highlights the pattern of this relationship for all blocks in the city of Miami-Dade in the 20 and 100-year RPs. In this case, population change actually increases up to about 7–10% of the properties in the area which have exposure to flooding in that RP. However, after 7–10% tipping point, there is a negative relationship associated with population decline. The pattern is most pronounced in the 100-year exposure for all the reasons related to frequency and severity above.
To understand the relationships identified in Fig. 2, it is important to locate the blocks spatially. Figure 3 highlights the relationship between forecast population change and changing flood exposure (by selected RP scenarios) out to mid-century. While the county predictions indicate that Miami-Dade is likely to grow into the middle of the century, that growth will be uneven and it is highly correlated with the exposure identified in the 100-year flood zone. This highlights that when seeking to understand the future impact of flood exposure change, using high precision data in regard to both flood exposure and population change, are required to see an adequate picture of the impacts. In particular, this example shows the areas along the Atlantic Ocean, Miami Beach, and the areas closest to the low-lying Everglades as the areas most susceptible to increased risks of flooding and to the resulting population decreases that are forecasted to occur as a result.
Discussion
This research presents a method for investigating observed relationships between historic flood exposure and population redistribution patterns in an attempt to understand the impact of climate change on population change forecasts. When isolating that effect from other migration push-pull factors, we are left with an independent, mostly negative, relationship over the past 20 years. Using that empirically derived relationship, this research further showed that summary level analyses at the state and county levels hide the spatial variability associated with the localization of climate exposure. However, when looking at this data at a high resolution, we see clear patterns associated with changing flood exposure and its impacts on estimated future population levels. This holds true for both coastal and inland areas, although the effects are more dramatic in coastal areas.
This analysis shows that while at an aggregate level, areas with high climate risk may be growing in population, this growth is more complicated, at least in regard to flood risk. Specifically, while larger geographic areas with high flood exposure may be growing rapidly, when looking within those areas at a higher resolution, the results found here indicate that growth is on average slower or negative for areas that are relatively more exposed than other areas in the same state. By accounting for population and spatial characteristics, migration likelihoods may be captured in population growth (and decline) rates as associated with various sources, depths, and probabilities of flood exposure at a high resolution. This not only captures varying responses to flood exposure, but also captures the population effect for areas that have relatively less flood exposure than surrounding areas (where this lack of flooding serves as a “pull” factor).
The intention of this manuscript is to investigate the influence of relatively high levels of exposure on population growth rates, the model variables which distinguish between relatively high and low exposure implicitly also captures the population effect for areas that have relatively less flood exposure than surrounding areas, where this lack of flooding serves as a pull factor. While current adaptation is accounted for in the FSF-FM used in this analysis, one limitation of the analysis is that it does not forecast future adaptation which may serve to dampen push factors or exacerbate pull factors. This serves as a potential source of uncertainty in future projections, and provides opportunities for future research. In addition, there may be uncertainty at multiple other steps throughout this process. The first forms of uncertainty come from the underlying flood, population, and other input data. Historical data may have uncertainties due to accuracy and measurement issues, while future data (flood and population) may have additional uncertainties as it builds off of historical data and uses various modeling approaches, capturing climate uncertainties, modeling uncertainties, and uncertainties due to underlying assumptions.
In spite of these known issues, this manuscript illustrates the potential for high-resolution data in providing a better understanding of climate migration within the U.S. While some areas with a high level of exposure have continued to see growth and are predicted to continue growing into the future, when data are used which provides information at a localized level, a more complex story comes to light. While larger areas (i.e. counties) with high exposure have grown and may continue to grow, small (i.e. tracts) areas with relatively low exposure may be driving this growth. A more clear understanding of how and where these impacts may occur will allow for better decision making as communities prepare for the impacts of climate change and continue to provide insight into how individuals are dealing with the changing climate and increasing levels of flood risk.
Methods
We integrate data on flood exposure and population with a series of indicators related to local political, social, and economic conditions (Supplementary Table 1). Historic flood exposure is accounted for through the data detailed in Lai et al.46, and from the NOAA Storm Events Database47. In addition to the historical flood exposure data, the First Street Foundation Flood Model (FSF-FM) estimates of properties with exposure from the underlying 3-meter hazard model were also included for the 5-, 20-, 100-, and 500-year RPs. These exposure estimates account for fluvial, pluvial, and coastal sources and are used to produce the primary treatment variable in this analysis, the proportion of properties in a block that are exposed to flooding. Both historic exposure and current estimates of the risk of exposure were included to account for two separate dimensions of risk associated with the experience of flooding and the likelihood that one could flood, thus accounting for prior sorting based on experiences of actual flooding. Future flood information is also provided by the FSF-FM, projecting flood exposure out 30 years into the future under RCP 4.5 using a combination of 21 global climate models, holding all else constant except for climatic changes44,45.
As this manuscript uses the proportion of inundated properties, we refer to the flood information as exposure for the remainder of the manuscript. More broadly, other variables which are accounted for in this research include demographic, economic, and political factors, which capture additional aspects of vulnerability, thus constituting the necessary components of risk35. These additional vulnerability-related metrics are not operationalized in such a way to provide a uniform comparison of risk across areas (such as by constructing a risk index), so the use of the term risk is kept only in broad contexts.
Future baseline population projections, which are demographically driven and do not explicitly account for climate change impacts at a local level, are provided by Hauer43 and are proportionally downscaled using current block population counts. This study utilizes SSP2 for consistency with the flood data future projections along RCP4.5 (equivalent to SSP2). SSP2 is defined as the Middle of the Road scenario, where future development trends are similar to historical patterns, and there is slow progress in achieving sustainable goals48. Additional data sources are introduced in Supplementary Table 1 and the following section highlights additional data sources and the larger 3-step research design.
Step 1. Propensity matching for control-treatment pairs by flood exposure
To account for potential endogeneity due to factors which may influence self-selection into block areas with flood risk, propensity scoring was executed to synthetically create conditions akin to a control-treatment design. Several options for treatment variables were considered, where a binary variable was used to define considerable flooding versus not-considerable flooding in an area. In this analysis, considerable flooding is a within-state metric that was derived from sensitivity analyses to identify a census block for the treatment group if that census block has a proportion of inundated properties that is ~3 times the mean proportion of inundated properties within census blocks in the same state. The metric captures relative flood exposure, and a block in a highly exposed state would need to have higher flood exposure to be considered at risk. This threshold was selected to retain a large sample size while also prioritizing the inclusion of highly exposed blocks. Conditional on observable characteristics of the block areas, propensity score matching allows for the synthetic construction of comparable treatment and control groups within a sample, allowing for a more direct comparison of the impacts from flooding on population trends and reducing selection bias. The variables used for the propensity score matching are presented in Supplementary Table 1. These variables are also more broadly related to some key drivers in differences between population growth rates, including job density, job growth rates, population in the starting year (2000), population density, median income, median home value, the Multi-Deprivation Index (MDI; provided by the Census Bureau, capturing six dimensions of standard of living, health, education, economic security, housing quality, and neighborhood quality49), and employment rate. A matching algorithm is used where matches are selected using the nearest neighbor as determined by a generalized linear model50. Furthermore, because migration tends to be within local areas, and generally within labor/housing markets, the subsequent analyses are run independently for each state across CONUS51.
Step 2. Evaluating the historic impact of flood exposure on population trends
The propensity score matching process resulted in a within-state matched sample, which is then fitted independently for each state through an OLS estimator, to account for political factors which may vary considerably across states, while not requiring models to rely on small and overly homogenous samples.
The dependent variable of our models is the block change rate, where:
The historic block change is calculated for 2000 to 2020. The subscripts on the above equation include i for blocks, and t for time. The modeling process then combined the explanation of variation in the calculated block change metric with the local amenities and/or disamenities. The modeling approach was further optimized to only select conditions that were empirically identified to be related to the explanation of block change variation within the state-level models. In all cases, the full model could include indicators of flood exposure, social characteristics, economic characteristics, local area pull amenities, spatial location, and baseline future change (from the unmodified baseline projections, as a latent variable of unobservable amenities). As such, when considering the explanatory modeling of the variation in the block change, the full relationship that the model may choose from may be expressed as the following equation:
And the minimum relationship that the model must include is:
Where Flood within the minimum model refers to a set of variables capturing the proportion of inundated properties within a block level. These variables exist for various all 4 RPs to capture differential population responses to variable flood scenarios, where the responses in redistribution patterns after low-severity and high-frequency flood events may differ from reactions to high-severity and low-frequency flood events. While data from the FSF-FM does include 2-year RP flooding (to measure tidal flooding), it is difficult to isolate it from other coastal amenities without meaningfully reducing the sample size. As such, this modeling approach does not explicitly account for nuisance tidal flooding events, but instead operationalizes frequent events at the 5-year RP.
In the full model, additional Flood variables include the square of the proportion of inundated properties for all RPs to allow for non-linear relationships. Social captures a set of variables, including initial population counts and density. Economic includes variables such as job opportunities, incomes, home valuation, employment rates, and a multidimensional deprivation index score. Amenities includes distances to natural amenities associated with flood exposure, such as proximities to coasts or rivers. Spatial is a set of variables that capture some of the spatially explicit interactions and movements of population settlements, such as longitudes, latitudes, and county controls. Future change is a single variable which is provided by the baseline growth projections, aimed at capturing any other characteristics of an area that facilitate certain growth rates. Both the spatial and future change variables also account for differences in differing valuation views by populations, such as perceptions of flood risk which may influence decision-making53, suitability of neighborhoods for raising a family, and social connectivity. For many of these variables, linear, interaction terms, and exponential variations (accounting for any non-linear relationships) were included in the full model selection for the final model to consider. The model selection process was optimized to select the most efficient model based on AIC. Here, the minimum and full model specifications were provided, where the model iterates through all possible variations between the two to select the one with the lowest AIC, capturing both goodness-of-fit and model simplicity. This process allows for the inclusion of location and population-specific valuation views, which are difficult and costly to independently quantify.
To evaluate the efficacy of the forecasting methodology, the data are split into training and testing sets through a stratification process. For each state, 80% of the total sample is used to construct the training sample, and the remaining 20% serves as the testing sample set. To evaluate the accuracy of the trained model in making predictions for the testing dataset, three accuracy metrics are considered25. Given the evaluation of these accuracy metrics, as well as the conclusions that they are all absolutely low and don’t seem to have any systematic patterns, the methodology to estimate coefficient estimates was deemed reliably useful in this application. This validation process and the results are discussed in further depth in the Supplementary Information (Supplementary Tables 2–3, Supplementary Figs. 1–2).
Step 3. Integrating the climate consequence to Future SSP Population Projections
For the purposes of this study, we modify population projections only with the condition of changes in flood exposure. To do this, we apply the coefficients for flood variables to the future (2053) flood layer projections assuming operationally linear increases between current and future flooding projections and that this gradual increase in exposure will be realized through growth rates. The coefficients for the relationship between flood variables and block growth rates may be applied through the integration of these relationships. Where initially the future population projections are derived as age-sex-race adjusted demographic estimates along the SSP2 trajectory.
Where, expressed differently using future (baseline) population counts, may be considered as:
Similarly, the future projections correcting for flood exposure (i.e. integrating the climate consequence) may be thought of as the contribution of and relationship between flood exposure metrics and demographic indicators,
Where expressed differently using future (projected, with flooding indicators described in step 2) population counts, may be considered as:
Where, when combined the future population projections can be expressed as:
The retrospective analysis and prospective correction of population projections along the SSP2 trajectory give us the ability to take observable associations between flood risk and exposure and integrate a high resolution climate signal into current SSP projections. Most importantly, we are interested in how areas that have been classified as highly exposed to flooding are projected to change in population relative to areas that have been classified as not being highly exposed.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
The input datasets used for this analysis are either already publicly available or cannot be made available due to restrictive data sharing agreements. All data sources are listed with links to access points in Supplementary Table 1.
Code availability
The code used for this analysis is available in a Github repository at: https://github.com/FirstStreet/flood-risk-migration-projection.
References
Callaghan, M. et al. Machine-learning-based evidence and attribution mapping of 100,000 climate impact studies. Nat. Clim. Change 11, 966–972 (2021).
Ide, T., Fröhlich, C. & Donges, J. F. The economic, political, and social implications of environmental crises. Bull. Am. Meteorological Soc. 101, E364–E367 (2020).
Tedesco, M., McAlpine, S. & Porter, J. R. Exposure of real estate properties to the 2018 Hurricane Florence flooding. Nat. Hazards Earth Syst. Sci. 20, 907–920 (2020).
NOAA National Centers for Environmental Information (NCEI) U.S. Billion-Dollar Weather and Climate Disasters https://www.ncei.noaa.gov/access/billions/, https://doi.org/10.25921/stkw-7w73 (2022).
Clement, V. et al. Groundswell part 2: Acting on internal climate migration (World Bank, 2021).
Hauer, M. E. Migration induced by sea-level rise could reshape the US population landscape. Nat. Clim. Change 7, 321–325 (2017).
Hauer, M. E. et al. Sea-level rise and human migration. Nat. Rev. Earth Environ. 1, 28–39 (2020).
Robinson, C., Dilkina, B. & Moreno-Cruz, J. Modeling migration patterns in the USA under sea level rise. PLoS ONE 15, e0227436 (2020).
Strauss, B. H., Kulp, S. & Levermann, A. Carbon choices determine US cities committed to futures below sea level. Proc. Natl Acad. Sci. USA 112, 13508–13513 (2015).
Keenan, J. M., Hill, T. & Gumber, A. Climate gentrification: from theory to empiricism in Miami-Dade County, Florida. Environ. Res. Lett. 13, 054001 (2018).
Chaturvedi, S., Cheong, T. S., Luo, Y., Singh, C., & Shaw, R. IPCC Sixth Assessment Report (AR6): Climate Change 2022-Impacts, Adaptation and Vulnerability: Regional Factsheet Asia (2022).
Piguet, E., Pécoud, A. & De Guchteneire, P. Migration and climate change: an overview. Refugee Surv. Q. 30, 1–23 (2011).
Curtis, K. J., Fussell, E. & DeWaard, J. Recovery migration after Hurricanes Katrina and Rita: Spatial concentration and intensification in the migration system. Demography 52, 1269–1293 (2015).
Fussell, E., Sastry, N. & VanLandingham, M. Race, socioeconomic status, and return migration to New Orleans after Hurricane Katrina. Popul. Environ. 31, 20–42 (2010).
Gutmann, M. P. & Field, V. Katrina in historical context: environment and migration in the US. Popul. Environ. 31, 3–19 (2010).
Indaco, A. & Ortega, F. Adapting to Climate Risk? Local Population Dynamics in the United States (2023).
Radeloff, V. C. et al. Rapid growth of the US wildland-urban interface raises wildfire risk. Proc. Natl Acad. Sci. USA 115, 3314–3319 (2018).
Partridge, M. D., Feng, B. & Rembert, M. Improving climate-change modeling of US migration. Am. Econ. Rev. 107, 451–455 (2017).
Jongman, B., Ward, P. J. & Aerts, J. C. J. H. Global exposure to river and coastal flooding: Long term trends and changes. Glob. Environ. Change 22, 823–835 (2012).
Merkens, J. L., Lincke, D., Hinkel, J., Brown, S. & Vafeidis, A. T. Regionalisation of population growth projections in coastal exposure analysis. Climatic Change 151, 413–426 (2018).
Neumann, B., Vafeidis, A. T., Zimmermann, J. & Nicholls, R. J. Future coastal population growth and exposure to sea-level rise and coastal flooding—A global assessment. PLoS ONE https://doi.org/10.1371/journal.pone.0118571 (2015).
McAlpine, S. A. & Porter, J. R. Estimating recent local impacts of sea-level rise on current real-estate losses: a housing market case study in Miami-Dade, Florida. Popul. Res. Policy Rev. 37, 871–895 (2018).
Bernstein, A., Gustafson, M. T. & Lewis, R. Disaster on the horizon: the price effect of sea level rise. J. Financial Econ. 134, 253–272 (2019).
Thiede, B. C. & Brown, D. L. Hurricane Katrina: Who stayed and why? Popul. Res. Policy Rev. 32, 803–824 (2013).
Hauer, M. E., Evans, J. M. & Mishra, D. R. Millions projected to be at risk from sea-level rise in the continental United States. Nat. Clim. Change 6, 691–695 (2016).
Derenoncourt, E. Can you move to opportunity? Evidence from the Great Migration. Am. Econ. Rev. 112, 369–408 (2022).
Armal, S. et al. Assessing property level economic impacts of climate in the US, new insights and evidence from a comprehensive flood risk assessment tool. Climate 8, 116 (2020).
Black, R., Bennett, S. R., Thomas, S. M. & Beddington, J. R. Migration as adaptation. Nature 478, 447–449 (2011).
Mueller, V., Gray, C. & Kosec, K. Heat stress increases long-term human migration in rural Pakistan. Nat. Clim. Change 4, 182–185 (2014).
Hugo, G. Future demographic change and its interactions with migration and climate change. Glob. Environ. Change 21, S21–S33 (2011).
Gibbons, S. J. A. & Nicholls, R. J. Island abandonment and sea-level rise: an historical analog from the Chesapeake Bay, USA. Glob. Environ. Change 16, 40–47 (2006).
Hunter, L. M., Murray, S. & Riosmena, F. Rainfall patterns and US migration from rural Mexico. Int. Migr. Rev. 47, 874–909 (2013).
Lee, E. S. A theory of migration. Demography 3, 47–57 (1966).
Banzhaf, H. & McCormick, E. Moving beyond cleanup. The Political Economy of Environmental Justice, 23–51 (2012).
Cardona, O. D. et al. Determinants of risk: exposure and vulnerability. In Managing the risks of extreme events and disasters to advance climate change adaptation: special report of the intergovernmental panel on climate change (pp. 65–108). (Cambridge University Press, 2012).
Ward, P. J. et al. Assessing flood risk at the global scale: model setup, results, and sensitivity. Environ. Res. Lett. 8, 044019 (2013).
de Ruig, L. T. et al. How the USA can benefit from risk-based premiums combined with flood protection. Nat. Clim. Change 12, 995–998 (2022).
Shu, E. G., Porter, J. R., Wilson, B., Bauer, M. & Pope, M. L. The economic impact of flood zone designations on residential property valuation in Miami-Dade County. J. Risk Financial Manag. 15, 434 (2022).
Seto, K. C. Exploring the dynamics of migration to mega-delta cities in Asia and Africa: contemporary drivers and future scenarios. Glob. Environ. Change 21, S94–S107 (2011).
Bell, A. R. et al. Migration towards Bangladesh coastlines projected to increase with sea-level rise through 2100. Environ. Res. Lett. 16, 024045 (2021).
Tierolf, L. et al. A coupled agent-based model for France for simulating adaptation and migration decisions under future coastal flood risk. Sci. Rep. 13, 4176 (2023).
Entwisle, B. et al. Climate shocks and migration: an agent-based modeling approach. Popul. Environ. 38, 47–71 (2016).
Hauer, M. E. Population projections for US counties by age, sex, and race controlled to shared socioeconomic pathway. Sci. Data 6, 1–15 (2019).
First Street Foundation. First Street Foundation Technical Documentation. https://assets.firststreet.org/uploads/2020/06/FSF_Flood_Model_Technical_Documentation.pdf (accessed on 28 June 2023) (2020).
Bates, P. D. et al. Combined modeling of US fluvial, pluvial, and coastal flood hazard under current and future climates. Water Resour. Res. 57, e2020WR028673 (2021).
Lai, K. et al. A natural language processing approach to understanding context in the extraction and geocoding of historical floods, storms, and adaptation measures. Inf. Process. Manag. 59, 102735 (2022).
NOAA National Weather Service (NWS). NOAA Storm Events Database (accessed in January https://www.ncdc.noaa.gov/stormevents/ftp.jsp (2023).
O’Neill, B. C. et al. The roads ahead: Narratives for shared socioeconomic pathways describing world futures in the 21st century. Glob. Environ. Change 42, 169–180 (2017).
Glassman, B. The multidimensional deprivation index using different neighborhood quality definitions. United States Census Bureau Social, Economic, and Housing Statistics Division (2020).
Ho, D., Imai, K., King, G. & Stuart, E. A. MatchIt: nonparametric preprocessing for parametric causal inference. J. Stat. Softw. 42, 1–28 (2011).
Frey, W. H. Americans’ local migration reached a historic low in 2022, but long-distance moves picked up. Brookings Institute Report (accessed 04/10/23). https://www.brookings.edu/research/americans-local-migration-reached-a-historic-low-in-2022-but-long-distance-moves-picked-up/ (2023).
Acknowledgements
The views expressed in this paper are solely the responsibility of the authors and should not be interpreted as reflecting the opinions of any organizations from which public data was used.
Author information
Authors and Affiliations
Contributions
E.G.S. and J.R.P. conceptualized and designed the research project, assembled input data, analyzed output data, and wrote the manuscript. E.G.S. designed and ran the statistical models. J.R.P. supervised the project. M.E.H. and S.S.O. provided advice on model design, analyzed output data, and edited the manuscript. J.G., B.W., M.P., D.M.V. and E.K. provided advice on the analysis of output data and edited the manuscript. J.G., B.W., M.P., D.M.V. and E.K. all contributed equally to this work.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Peer review
Peer review information
Nature Communications thanks Felipe Quintero and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. A peer review file is available.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Shu, E.G., Porter, J.R., Hauer, M.E. et al. Integrating climate change induced flood risk into future population projections. Nat Commun 14, 7870 (2023). https://doi.org/10.1038/s41467-023-43493-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-023-43493-8
- Springer Nature Limited
This article is cited by
-
Long-term effects of redlining on climate risk exposure
Nature Cities (2024)