key: cord-1052098-8mkizlj3 authors: Shen, Xinyi; Cai, Chenkai; Yang, Qing; Anagnostou, Emmanouil N.; Li, Hui title: The US COVID-19 Pandemic in the Flood Season date: 2020-10-01 journal: Sci Total Environ DOI: 10.1016/j.scitotenv.2020.142634 sha: 377f6f6e1be6ec1a66b3986505dbe09230140544 doc_id: 1052098 cord_uid: 8mkizlj3 Flooding displaces large populations each season, which potentially increases the exposure of the vulnerable societies. Having failed to curve down the number of people infected with COVID-19 in the first wave of the pandemic, many states in the United States (U.S.) are now at high risk of the concurrence of the two disasters. Assessing this compound risk before the country enters the flood season is of vital importance. Therefore, we provide a prompt tool to assess the compound risk of COVID-19 at the county level over the U.S.. We find that (1) the number of flood insurance house claims can proxy the displaced population accurately with more spatiotemporal detail, and (2) the high-risk areas of both flooding and COVID-19 are concentrated along the southern and eastern coasts and some parts of the Mississippi River. Our findings may trigger the interest of further exploring the topics related to the concurrence of COVID-19 and flooding. As of July 2020, the COVID-19 global pandemic had infected more than four million population in the United States (U.S.). In Wuhan, where the virus was first reported, the initial reproductive number (R 0 ) was 2.2 (Li et al., 2020) , it has been up to 6.5 globally . In the U.S., which is seeing the record-breaking numbers of infections following a reckless reopening of states (Knauer, 2020) , the best-case outcome in the absence of a vaccine or effective has proved to be managing a controlled transition from community spread. Nonpharmaceutical mitigation measures including social distancing and have been proved effective in curving the number of infectees (Anderson et al., 2020; Dehning et al., 2020; Lai et al., 2020; Prem et al., 2020; Shen et al., 2020) . This has left the U.S. successfully in bending the curve, just as the country is about to enter the flood season. During the past three years, flooding alone has displaced 10,729 people per year on average in the U.S. (Internal Displacement Monitoring Centre, IDMC, https://www.internaldisplacement.org/countries/united-states). This year, potentially increased exposure of the flooddisplaced population to COVID-19 may yield a greater risk of infection. Flood risk is traditionally evaluated by hydrological models (Fu et al., 2014; Liang et al., 1994; Shen and Anagnostou, 2017; Shen et al., 2016) , sometimes coupled with hydraulic models (Bates et al., 2010; Hardesty et al., 2018; Yamazaki et al., 2011) at global, national, and local scales in terms of the output discharge, inundation extent (Shen et al., 2019a; Shen et al., 2019b) , or depth (Cohen et al., 2017) . The traditional flood risk measures cannot, however, be linked directly to the displaced population. J o u r n a l P r e -p r o o f Moreover, while many published studies have analyzed the risk of either flooding or COVID-19, none has evaluated the compound risk posed by the concurrence of the two. In this study, we aim to provide a prompt tool to overview the compound risk before the flood season by utilizing three datasets, 10 years of flood insurance house claims (referred to as flood claims hereafter), the displaced population from the past three years, and the COVID-19 infectee records. We will process the final result to the county level over the U.S. Since May 22, many states have reopened regardless of the ongoing pandemic. We use the mean daily reproductive number from May 22 to July 1 to represent the current risk of COVID-19. The reproductive number, R 0, is defined as the average number of secondary infectees generated by a primary infector (Van den Driessche and Watmough, 2008). Therefore, we define a greater than unity R 0 as representing moderate to extremely high risk and a smaller than unity R 0 as indicating low risk. We employ a stochastic approach (Flaxman et al., 2020) to estimate the reproductive number, R 0 from the clinical confirmation of COVID-19 infectees assembled at Johns Hopkins University (Dong et al., 2020) . The approach models as discrete stochastic number of days the time delay from when a person becomes infected to his/her clinical confirmation as a discrete stochastic number of days, and the time from when a person gets infected and to when he/she infects another person. Then the R 0 of a given county on day t, R 0t , can be estimated from the daily (1) where is the probability of an infectee's receiving clinical confirmation t days since being infected (Lauer et al., 2020) . Note that in equation (1), C records with a 14-day extension need to be used to estimate the I t on a given day. Therefore, we use the COVID-19 records until July 15 to study the period up to July 1. The conversion from to 0 is given by equation (2), where is the probability of an infector's infecting other people on the day t since being infected. Non-local community spread can occur in two situations in a given response unit: before the community spread starts, or when a large number of infectors are imported in the middle of a community spread. Both situations could result in an erroneous R 0 value. For the first situation, we simply set 30 accumulated cases as the minimum threshold for a community spread to start. R 0 outside of the community spreading period will be set as No Data. The second situation is featured by a sharp peak of daily confirmed infectees and/or many days of zero newly confirmed cases. In this situation on a given day, if either the number of newly confirmed infectees on the given day is at least 10 times of any other day within the 14-day window the given day is centered in, or the number of newly confirmed infectees are zero on no less than 4 days in the 14-day window ending on the given day, we set R 0 of the 14-day window ending on the given day as No Data. The Finally, we use the total NFIP flood claims at the county level from 2010 to 2019 to represent the flood risk. We find the Normal and Weibull distributions could well characterize the county-level R 0 and positive claims (see Figure 2 ), as written by equations (3) and (4), and they have low correlation (r = 0.09). Therefore, we standardize each marginal risk to low, moderate, high, and very high, then composite the two-dimensional risks as the compound one. Note that when the R 0 is smaller than unity, the virus is likely to die out. Therefore, we define the low COVID-19 risk category as R 0 < 1. The standardized thresholds for other categories are listed in Table 1 . Note that although we attempt to remove erroneous R 0 values by implementing a trimming algorithm, the lack of tests at early stages or the insufficient test capabilities in some counties can still bias the transmissivity estimation (Manski and Molinari, 2020) . Therefore, the standardization might characterize the risk of COVID-19 more accurately than directly using the reproductive number. (1) Table 1. Classification standard of 0 and positive flood claim. N represents the number of positive flood claims, represents the CDF of the standard normal distribution, and −1 is its inverse. Standardized magnitude High 0.5 ≤ −1 ( 0 ) < 1.5 1 ≤ −1 ( ) < 2 Very high −1 ( 0 ) ≥ 1.5 −1 ( ) ≥ 2 Compositing the flood and COVID-19 risks at the county level over the U.S. reveals the hotspots of the compound risk and each marginal risk. Although the correlation between the historical flood risk and recent COVID-19 risk is low, areas at high risk for both exist. As shown in Figure 3 , the US COVID-19 capitals include the west coastal, south coastal, and southeastern coastal counties, and the south great plains. Figure 4 shows the flood risk is relative higher along the southern and eastern coasts, and in areas along the Mississippi River and its main branches. Consequently, the compound risk is equal or above the high level (for both) along the southern and eastern coastal counties and some part of the Mississippi River, as shown in Figure 5 . We present a prompt tool to estimate the compound risk posed by flooding and COVID-19. The areas of high risk for both types of hazards are concentrated along southern and eastern coastal states, and along the Mississippi River and its main branches. We also note that although the northeastern coast used to be the capital of COVID-19 and is also at high risk for flooding, the compound risk is no thigh because the COVID-19 risk is currently low. The latter can be attributed to the effective and stringent mitigation policies adopted by these states (e.g., New York state, especially New York City). Note that the insufficient COVID-19 clinical records available for many midwestern counties for the period of consideration could make the J o u r n a l P r e -p r o o f evaluation of COVID-19 risk less accurate there. Furthermore, it worth noting that in areas frequently that experience flooding, residents might be more prepared than areas with less frequent flooding, resulting a different relationship of flood severity and impact than we expect before the flood season. Our study may trigger the interest of studying the following topics: (1) predicting the flood risk or COVID-19 risk for the next season; and (2) physically estimating the feedback from flood damage to COVID-19 risk (e.g., the transmissivity) in 2020 or parameterizing the flood damage in modeling the COVID-19 risk. How will country-based mitigation measures influence the course of the COVID-19 epidemic? 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The Lancet Public Health A Framework to Improve Hyper-Resolution Hydrologic Simulation in Snow-Affected Regions Near Real-Time Nonobstructed Flood Inundation Mapping by Synthetic Aperture Radar Socioeconomic restrictions slowdown COVID-19 far more effectively than favorable weather-evidence from the satellite Refining a Distributed Linear Reservoir Routing Method to Improve Performance of the CREST Model Inundation Extent Mapping by Synthetic Aperture Radar: A Review Further notes on the basic reproduction number A physically based description of floodplain inundation dynamics in a global river routing model We want to give many thanks to Dr. Lisa Ferraro Parmelee (LFP Editorial Enterprises LLC) for the professional proofreading of this manuscript during her vacation time, and the editorial board of Science of the Total Environment for the prompt processing, which ensures the timely submission and processing of this COVID-19 related manuscript.