Heat Waves and Their Impacts on Human Health in Urban Areas of Central Oklahoma ---------------------------------------------------------Emma Fagan, Kyle Thiem, and Jessica Voveris University of Oklahoma, School of Meteorology Heather Basara Assistant Professor, University of Oklahoma Department of Geography Jeffrey Basara Associate Professor, University of Oklahoma School of Meteorology Abstract Heat waves occur throughout the world every year and have substantial impacts on human populations. Mortality and morbidity rates have been known to increase during these extreme heat events. Due to the increasing trend in urbanization and the probability of extreme heat waves increasing in intensity and frequency, adaptation and mitigation techniques are needed now more than ever. The authors chose to look at the 2008 summer heat wave in Oklahoma City, Oklahoma to determine which populations, based on a census tract level, were considered most at risk during such events. The purpose of this project was to demonstrate vulnerability mapping using a geographic information system (GIS) on a community level scale that could aid emergency managers in preparing and responding to disasters, such as extreme heat events. Individual census tracts were given a vulnerability level according to four different attributes (cluster data, population density, daily maximum temperature, and daily minimum temperature), which will allow for easy determination of where emergency aid should be sent in future events. Within the cluster data, demographic information such as education, income, and age were analyzed. A final analysis included combining these factors to determine which census tracts within Oklahoma City were considered most at risk. 1) Introduction Heat waves occur throughout the world and have substantial impacts on human populations, especially within urban environments. Higher rates of mortality and morbidity are often associated with heat waves due to the high temperatures and increased air pollution. Events such as the Chicago Heat Wave of 1995 (Krunkel et al. 1996), the European Heat Wave of 2003 (Garcia-Herrera et al. 2010), and the Russian Heat Wave of 2010 (Grumm 2011) resulted in numerous fatalities and call attention to the existing relationship between heat waves, urban environments, and human health. This particular field of research regarding heat waves still requires further understanding of the Urban Heat Island (UHI) Effect coupled with heat waves (Basara et al. 2010) in addition to temperature and other air pollutant impacts on the human body (Filleul et al. 2006; Zvyagintsev et al. 2011). The importance in understanding these features increases greatly when considering shifts in natural climate variability and the trend toward increasing urbanization since heat waves are likely to increase in intensity, longevity, and frequency in the future due to global climate change (Luber and McGeehin 2008; Meehl and Tebaldi 2004). The purpose of this study was to further expand the knowledge about heat waves and their impacts on both temperature and human health within urban environments and to introduce new vulnerability mapping techniques for urban cities. Due to the increasing trend in urban population and the probability of extreme heat waves increasing in intensity and frequency throughout the world, adaptation 2 and mitigation techniques are necessary in order to decrease the rate of heat-related mortality. The authors wish that in the future, the vulnerability mapping techniques introduced through this project can one day serve emergency managers in predicting where and when they need to focus their emergency aid after, or even before, a major heat wave event strikes an area. 2) Background Since heat waves are a common occurrence across the world and have the ability to impact a large amount of people, a further understanding of these events is essential. Heat waves have the potential to be extremely deadly within urban environments due to how they interact with the urban settings. A phenomenon known as the Urban Heat Island (UHI) Effect has been observed and studied in several urban cities across the world (Bornstein 1968; Kim 1992; Hung et al. 2006; Basara et al. 2008; Gaffin et al. 2008). Due to the UHI Effect, urban cities tend to be warmer than their rural counterparts, especially during the nighttime hours. Basara et al. (2008) performed a study to explore the urban heat island of Oklahoma City, Oklahoma. Utilizing the Oklahoma Mesonet stations and Oklahoma City Micronet stations, they compared the urban environment with the surrounding rural and suburban areas. The UHI Effect is more pronounced at night than during the day for both the 2-meter and 9-meter temperature recordings (Figure 1). The urban environment was also noted to be warmer overall at 9 meters but slightly cooler during the day at 2 meters during the time period from June 28 to July 31, 2003. Basara et al. (2008) noted the slightly cooler temperatures at 2 meters could have been attributed to the placement of measurement sites into areas where the density distribution of buildings was at its greatest, among other factors, which could have impacted the amount of solar radiation measured. Figure 1: Mean diurnal temperature differences at 9 meters and 2 meters in Oklahoma City, Oklahoma from the Oklahoma City Micronet stations during the time period from June 28 to July 31, 2003 (Basara et al. 2008). Previous research (Kunkel et al. 1996; Basara et al. 2010) shows that heat wave effects tend to be enhanced in urban heat islands. The UHI effect has a tendency to raise air temperatures in an urban area 3 approximately 0.5° C during the day to as much as 2° C during the nighttime period compared to rural areas, which can be devastating during periods of intense heat waves (Basara et al. 2008; Basara et al. 2010). Rural areas experience rapid cooling at night compared to the urban areas due to the lack of thermal storage and anthropogenic heating sources (e.g. exhaust from vehicles). These two factors result in the overall warming experienced in the urban environment seen at the 9-meter level in Figure 1. As city populations continue to grow and city sizes expand, this temperature difference between urban and rural environments created as a result of the UHI effect during major heat waves can essentially increase to an even larger gradient (Hung et al. 2006). The combined effects of heat waves and UHI can potentially increase the air temperature in urban zones to the point where the risks for heat-related illnesses amplify for a particular population compared to rural populations (Basara et al. 2010). For extremely hot temperatures, these health impacts include upper respiratory diseases, heat strokes, and heat exhaustion, and cardiovascular illnesses (Kilbourne 1997; Barnett et al. 2007; Lin et al. 2009). It was noted that when the core body temperature exceeds 103° F severe heat strokes can occur resulting in damaged organs and/or death. Previous research has also mentioned since heart related illnesses are driven by blood pressure, these illnesses might occur as a result of decreasing blood pressure as temperature increases. Semenza et al. (1996) performed a study regarding the heat related deaths in the 1995 Chicago Heat Wave. They noted living conditions and social contacts played an important role in determining the death risk someone would have during a heat wave. People who had access to air conditioners had a much lower risk of death compared to those who did not. Having access to a working air conditioner resulted in an 80% reduction in the risk of death associated with cardiovascular diseases. Also, the authors noted that people who lived alone and who had preexisting medical conditions were more susceptible to death during these extreme heat events. The term “harvesting” has been used to describe the large amount of deaths that typically occur at the beginning of a heat wave (Pattenden et al. 2003). This particular round of deaths during heat waves is usually attributable to preexisting medical conditions. Air pollutants during heat waves tend to be increased greatly within urban cities due to the air circulation becoming stagnant under a persistent upper-level ridge and surface high pressure that lasts for a long period of time. These pollutants impact the human body and result in an increased risk of respiratory diseases. Several deaths in the European Heat Wave of 2003 (Filleul et al. 2006) and the Russian Heat Wave of 2010 (Zvyagintsev et al. 2011) are attributable to the increased air pollution (e.g. ozone). However, the risk of air pollutants may be minimal if the duration of the extreme heat event is short lived, such as the Chicago Heat Wave of 1995. Kovats and Hajat (2008) noted that one reason why so many deaths occurred in the 2003 European Heat Wave was the lack of an emergency plan for heat waves in the cities. There also seemed to 4 be a lack of coordination between the social services and health agencies. This project aims to help create an emergency plan by allowing emergency managers the knowledge of where the most vulnerable populations exist within their respective cities. With this information, emergency managers would have the potential to save several lives by sending aid to the most at risk populations before an increase in mortality can occur. 3) Data and Methodology This project focuses on the 2008 summer heat wave of central Oklahoma. The authors defined the 2008-summer heat wave to last from July 31, 2008 through August 7, 2008. This study utilized both Oklahoma Mesonet data and Oklahoma City Micronet data in addition to demographic data obtained from the Census Bureau and ozone data obtained form the Oklahoma Department of Environmental Quality. All data was inserted into the ArcGIS program for further analysis, which was subsequently followed by the assignment of vulnerability levels for individual census tracts. 3a) Oklahoma Mesonet Data This network consists of ~120 remote sensing stations located in rural areas across the state of Oklahoma (McPherson et al. 2007). Each station measures numerous types of data including the data utilized for this project, 2-meter air temperature. These stations transmit measured data every 5 minutes to a central location for quality assurance and archival. This particular study used 11 stations near the Oklahoma City metropolitan area to aid in the interpolation of temperature data for the Oklahoma City census tracts that were on the edge of our study area. 3b) Oklahoma Micronet Data This network consists of ~36 stations mounted on traffic signals within Oklahoma City, Oklahoma (Basara et al. 2011). Each station measured numerous types of data including the data utilized for this project, 9-meter air temperature. These stations are not currently transmitting data; therefore data from the 2011 and 2012 heat waves were unavailable for this research project. Measured data was transmitted every minute to a central location for quality assurance and archival, similar to that of the Oklahoma Mesonet. The locations of all Oklahoma Mesonet and Oklahoma City Micronet stations used throughout this study are shown in Figure 2. 5 Figure 2: Oklahoma Mesonet and Oklahoma City Micronet station locations around the Oklahoma City metropolitan area. 3c) Census Bureau Data and Ozone Data This project utilized census tract data obtained from the Census Bureau, which contained several population attributes including population density, age, income, and education. Hall and Basara (2010) combined the latter three attributes to form 5 clusters in an attempt to aid with simplifying the data (Figure 3). This study also explored ozone concentration data across the census tracts; however, according to the Environmental Protection Agency Air Quality Index, ozone concentration did not reach significant health concern levels during this event. Therefore, the authors decided not to assign vulnerability levels based on ozone concentration for this specific event. 6 Figure 3: Cluster analysis data as defined by Hall and Basara (2010). 3d) Geographic Information System (GIS) The geographic information system used primarily in this project was ArcGIS 10. Graphics were created for each variable with the census tract outlines overlaid. Ozone concentration and the cluster analysis data did not require any further calculations prior to creating GIS graphics. Population density was calculated to be in units of persons per square kilometer for each individual census tract using analysis tools within ArcGIS 10. Maximum daily temperature and minimum daily temperature were obtained from all Mesonet and Micronet stations being utilized in this research project throughout the time period being investigated. Maximum daily temperature was defined to occur between 1300 UTC and 0100 UTC, while minimum daily temperature was defined to occur between 0100 UTC and 1300 UTC. Due to the poor spatial resolution of Mesonet and Micronet locations on the periphery of the Oklahoma City limits, the authors used the kriging interpolation method (Oliver and Webster 1990) in order to interpolate the point temperature data from point to raster format. Once the temperature data was interpolated, the authors calculated the mean temperatures throughout the spatial area of each census tract in order to assign each tract a daily minimum and daily maximum temperature for each day during the defined event (Figure 4). This particular field was also averaged over the duration of the event to allow for the assignment of vulnerability levels on both a daily timescale and event-long timescale. 7 Figure 4: Model used in ArcMap 10 to interpolate temperature and calculate the statistical mean for each census tract. 2e) Assigning Vulnerability Levels The assignment of vulnerability levels was quite subjective due to the nature of this research field. No previously peer-reviewed research has explored vulnerability mapping for extreme heat events on a community scale with the use of GIS, and only very little research has been done assigning vulnerability levels to differing populations based on demographic data in addition to temperature extremes. There has been previous research done regarding vulnerability due to extreme temperature thresholds alone, however (Armstrong 2006; Lin et al. 2009). Additionally, Reid et al. (2009) studied vulnerability mapping based solely on ten demographic variables with each variable assumed to have a linear relationship with vulnerability; therefore, for this study the authors chose to assume a linear relationship between all demographic variables (population density, age, education, and income) and vulnerability. The authors used a scale from 1 to 5 with 1 representing the lowest relative risk and 5 representing the highest relative risk for these demographic variables. Hajat and Kosatky (2010) discovered an increasing trend of vulnerability with increasing age, especially for those above 65 years old. For this reason, the cluster with the oldest population was given the highest vulnerability level, with the middle age groups receiving a vulnerability level of 3 and the young adults receiving a vulnerability level of 2. Education and income were determined to have separate vulnerability levels based on the work done by Reid et al. (2009). The authors decided to assume higher education and higher income would lead to decreased vulnerability. Research shows that high income drastically reduces vulnerability to heat waves simply due to the fact that people can afford air conditioning in their homes. As mentioned before, Semenza et al. (1996) noted a significant decrease in mortality when people were able to access air conditioning. In regards to the cluster data, since age, education, and income were combined to form five different clusters, vulnerability levels for each cluster were obtained by averaging the vulnerability levels given to each of the three demographic attributes (Table 1). The authors then normalized the averaged vulnerability levels to 1 in order to aid in the comparison of one census tract to another. 8 Table1: Assignment of vulnerability levels to the cluster data with 1 representing the lowest risk and 5 representing the highest risk. Similar methods of vulnerability assignments were used with the population density and temperature data. Cluster # Vulnerability Age Vulnerability Education Vulnerability Income Average Vulnerability Level Normalized Vulnerability Level 1 2 2 4 2.66 0.415 2 3 2 2 2.33 0.333 3 3 5 5 4.33 0.833 4 3 4 5 4.00 0.750 5 5 1 1 2.33 0.333 Similar tables were also created for the population density and temperature data for each individual census tract. For population density, research demonstrates that higher population densities tend to result in larger heat effects on humans (Medina-Ramon and Schwartz 2007). The authors first took the range of population densities and divided it into 5 equal groupings. Vulnerability levels were then determined so that a vulnerability level of 1 corresponds to the lowest population densities and a vulnerability level of 5 corresponds to the highest population densities. These vulnerability levels were also normalized to 1 for comparison purposes. Hajat and Kosatky (2010) also discovered that most heat slopes within literature show that for every 1ºC increase past a certain temperature threshold, a subsequent increase of 1-3% in human mortality occurs. This research allowed the authors to assume a linear relationship and assign a vulnerability level based on the number of degrees Celsius past a certain threshold for both daytime and nighttime temperatures. The thresholds were determined to be the maximum average summertime (June, July, August) temperature for the daytime temperature and the minimum average summertime temperature for the nighttime temperature due to the work assessed in Hajat and Kosatky (2010). These temperatures were calculated using the 1971 to 2000 climate normals data for Oklahoma County from the Oklahoma Climatological Survey. The daytime temperature threshold value used for this project was 32.76ºC (90.97ºF) and the nighttime temperature threshold value used for this project was 20.56ºC (69.0ºF). Vulnerability levels for temperature were assessed on a scale of 1 to 10, with 1 representing 1ºC above the climatological average, 2 representing 2ºC above the climatological average, and so on, up to 10. All vulnerability levels were again normalized to 1 for comparison purposes. Hajat and Kosatky 9 (2010) also discussed how observed temperature and apparent temperature are essentially interchangeable in regards to the heat slope mentioned above. In order to determine the most at risk areas for any duration of the extreme heat event, the authors combined the defined normalized vulnerability levels for all attributes (cluster data, population density, maximum temperature, and minimum temperature) using the following equation (1) for each census tract. The temperatures used for the event total risk assessment were the averaged maximum and minimum temperatures of the event and the temperatures used for the daily total risk assessment were the daily maximum and minimum temperatures. Every attribute was assumed to hold equal weighting for the determination of total risk (Reid et al. 2009). After total risk was calculated for each census tract, the values were once again normalized to 1. πππ‘ππ π ππ π = 0.25 ∗ ππππ₯ + 0.25 ∗ ππππ + 0.25 ∗ πππ. π·πππ ππ‘π¦ + 0.25 ∗ πΆππ’π π‘ππ π·ππ‘π (Eq. 1) 4) Results and Discussion Figure 5 displays the outlines of all census tracts utilized with the color fill representing its designated cluster based on the cluster data defined in Hall and Basara (2010) (cluster data shown in Figure 3). Based on the cluster data alone, the authors hypothesized that census tracts within clusters 3 and 4 would have the highest potential risk during an extreme heat event. Figure 6 shows census tract vulnerability based on the cluster data. Table 1 displayed the detailed vulnerability levels given to each cluster, in which clusters 3 and 4 did indeed have the highest vulnerability levels with 0.833 and 0.750, respectfully. These two clusters were determined to have the lowest income and lowest education levels of all the clusters; these two factors played a key role in the clusters’ high vulnerability levels since these two groups would most likely not be able to have access to air conditioning. Cluster 1 had a moderate risk during the heat wave event of 0.415, which was primarily due to the low to middle income level. Clusters 2 and 5 were determined to have the lowest risk in heat waves, primarily due to their higher income and higher education levels. 10 Figure 5: Census tracts within the Oklahoma City area defined by their cluster. Figure 6: Census tract vulnerability based solely on the cluster data defined by Hall and Basara (2010). Population density in units of persons per square kilometer is shown below in Figure 7. It can be easily be seen that the highest densities lie within the most urbanized regions of the Oklahoma City Metropolitan area and the lowest densities lie within the rural areas on the outer regions of the urbanized portion of the city. These features are extremely important in regards to the urban heat island phenomenon, in which the urbanized areas can experience temperatures several degrees above their rural 11 counterparts during both the daytime and nighttime hours. This phenomenon, as stated before, tends to be most prominent during the nighttime hours with temperatures as much as 2ºC higher within the urbanized areas due to the thermal storage and anthropogenic heating. Higher vulnerability levels tend to exist where the population densities are highest. Figure 8 displays the vulnerability levels associated with this population density. Indeed, the highest vulnerability levels of 0.6 and greater are within the most urbanized areas of the Oklahoma City Metropolitan area. These results are to be expected due to the linear relationship assumed for this particular project. When comparing these values to the cluster data vulnerability (Figure 5), it can be seen that several census tracts within cluster 3 also have the highest vulnerability levels for population density. These census tracts not only experience a 0.833 vulnerability level due to cluster data but also 0.8 and greater vulnerability levels due to the population density data. Figure 7: Population density map of the Oklahoma City Metropolitan area. 12 Figure 8: Population density vulnerability map of the Oklahoma City Metropolitan area. Figure 9 displays the recorded daily maximum temperature and Figure 10 shows the recorded daily minimum temperature for what was defined to be the most impactful day based on temperature alone. August 4, 2008 had the hottest daytime maximum temperature and the hottest nighttime minimum temperature throughout the heat wave event. The daily maximum temperature for August 4 across the Oklahoma City Metropolitan area ranged from approximately 38.8ºC to just above 40ºC, while the minimum temperature for this day ranged from 24ºC to nearly 27ºC. The urban heat island and the heat island plume were quite noticeable within these plots with the center of downtown, and northward, experiencing the hottest temperatures both during the daytime and nighttime. Graphs similar to those shown for August 4 were also generated for each day and for the duration of the extreme heat event. By examining the event-long average maximum and minimum temperatures, areas where the temperatures were relatively high for a longer period of time begin to become more apparent. 13 Figure 9: Interpolated daily maximum temperature for August 4, 2008. Figure 10: Interpolated daily minimum temperature for August 4, 2008. 14 The vulnerability associated with the daily maximum and daily minimum temperature graphics shown above are displayed in Figure 11 and Figure 12, respectfully. In Figure 11, vulnerability levels across the area range from 0.6 to 0.8. The highest vulnerability levels, associated with the hottest temperatures, were assessed to be in the most urbanized area of downtown Oklahoma City. Stronger gradients of the vulnerability levels are seen in Figure 12, where the levels range from 0.4 to 0.8. Due to the urban heat island and heat island plume, populations within the more urbanized portions of the Oklahoma City Metropolitan area definitely see a higher potential risk due to nighttime temperature alone. The hottest temperatures, and subsequently the highest vulnerability levels, are seen in the northcentral region of Oklahoma City, northeast of Lake Hefner. Graphics similar to these were also created for each day as well. Comparing these vulnerability attributes to the cluster data once more, it can be seen that cluster 3 again lies within the region of highest vulnerability for both the daytime maximum and nighttime minimum temperatures. Portions of cluster 1 and 4 are also impacted greatly by the high nighttime temperatures. However, looking solely at the nighttime temperatures, portions of clusters 2 and 5 actually have the highest vulnerability levels. Figure 11: Vulnerability levels for each census tract based on daily maximum temperature for August 4, 2008. 15 Figure 12: Vulnerability levels for each census tract based on daily minimum temperature for August 4, 2008. Vulnerability levels associated with temperature were not only generated for each day but also for the entire duration of the event as well. Figure 13 displays the average maximum temperature vulnerability and Figure 14 shows the average minimum temperature vulnerability. These vulnerability levels were assessed on the same conditions as was the daily maximum and daily minimum temperatures, with the per 1ºC increase of temperature past the given thresholds resulting in an additional vulnerability level. Vulnerability levels given to each census tract based on the average maximum temperature were relatively low for the majority of census tracts compared to the levels given based on the average minimum temperature. Values range from 0.3 to 0.5 for the daytime temperatures while at night the values range from 0.2 to 0.6. The impact from urban heat island plume is also quite noticeable on the average minimum temperature vulnerability plot with higher vulnerabilities associated with its existing location. 16 Figure 13: Vulnerability levels for each census tract based on the average maximum temperature from the entire duration of the extreme heat event. Figure 14: Vulnerability levels for each census tract based on the average minimum temperature from the entire duration of the extreme heat event. 17 Potential total risk was determined by combining each of the vulnerability factors previously discussed with equal weighting on both daily and event-long timescales. Figure 15 shows the total risk for August 4, 2008. This was determined using the population density, cluster data, daily maximum temperature, and daily minimum temperature. Figure 16 displays the total risk for the entire event. Population density and cluster data were used in this calculation, in addition to the average maximum temperature and average minimum temperature of the event. On August 4, 2008 the vulnerability levels ranged from 0.3 on the outskirts of the city to 0.8 within the city. The highest levels for this day were seen in south-central Oklahoma City, south of Interstate 40 and north of Interstate 240. Recall that these census tracts lie within cluster 3, which was known to be the poorest and least educated of the clusters. For the entire event, vulnerability levels ranged from 0.2 in the outskirts of the city to 0.7 within the city. Similar patterns are seen in regards to which census tracts are considered to have the highest potential total risk. When comparing this total risk to the cluster data, it can be seen that the highest total risk is most likely to be seen in census tracts that are within clusters 1 and 3, and the lowest total risk is most likely to be seen in census tracts within cluster 2. Figure 15: Potential total risk assessed for August 4, 2008. 18 Figure 16: Potential total risk assessed for the entire extreme heat event from July 31, 2008 to August 7, 2008. 5) Conclusion This research served as a pilot project for exploring the plausibility of vulnerability mapping on a community level scale. Overall, the project proved to be successful and displayed the potentially most at risk census tracts within the Oklahoma City Metropolitan area on both a daily scale and event-long scale. Using this information, emergency managers could potentially send aid to the most at risk populations during extreme heat events and possibly save lives by utilizing a targeted approach. 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