Importance Of Environmental Weather Monitoring for Emergency Management in Oklahoma

This dissertation used a mixed approach of methods (i.e., survey data, NOAA’s Storm Events Database, Google Analytics, focus groups, and interviews) to assess the relevance of environmental weather monitoring and associated training in Oklahoma. The chapters from the dissertation detail what motivates emergency managers and public safety officials to seek training and information sources related to hazardous weather events. The chapters further explore how important (in value and impact) weather training and data are to emergency managers (EMs) and how weather data sources and constraints differ between those in the military and those in local government positions. Keywords: Emergency management, Decision making, Extreme weather events, Military installations Non-market valuation, OK-First, Oklahoma, Oklahoma Mesonet, Public Safety Officials, Weather Decision Support Systems, Weather impacts, Weather monitorin

Growing Season Air mass Equivalent Temperature (T\u3csub\u3eE\u3c/sub\u3e) in the East Central USA

Equivalent temperature (TE), which incorporates both dry (surface air temperature, T) and moist heat content associated with atmospheric moisture, is a better indicator of overall atmospheric heat content compared to T alone. This paper investigates the impacts of different types of air masses on TE during the growing season (April–September). The study used data from the Kentucky Mesonet for this purpose. The growing season was divided into early (April–May), mid (June–July), and late (August–September). Analysis suggests that TE for moist tropical (MT) air mass was as high as 61 and 81 °C for the early and mid-growing season, respectively. Further analysis suggests that TE for different parts of the growing seasons were statistically significantly different from each other. In addition, TE for different air masses was also statistically significantly different from each other. The difference between TE and T (i.e. TE-T) is smaller under dry atmospheric conditions but larger under moist conditions. For example, in Barren County, the lowest difference (20–10 °C) was 10 °C. It was reported on 18 April 2010, a dry weather day. On the other hand, the highest difference for this site was 48 °C and was reported on 11 August 2010, a humid day

Growing Season Air mass Equivalent Temperature (TE) in the East Central USA

Equivalent temperature (TE), which incorporates both dry (surface air temperature, T) and moist heat content associated with atmospheric moisture, is a better indicator of overall atmospheric heat content compared to T alone. This paper investigates the impacts of different types of air masses on TE during the growing season (April–September). The study used data from the Kentucky Mesonet for this purpose. The growing season was divided into early (April–May), mid (June–July), and late (August–September). Analysis suggests that TE for moist tropical (MT) air mass was as high as 61 and 81 C for the early and mid-growing season, respectively. Further analysis suggests that TE for different parts of the growing seasons were statistically significantly different from each other. In addition, TE for different air masses was also statistically significantly different from each other. The v between TE and T (i.e. TE-T) is smaller under dry atmospheric conditions but larger under moist conditions. For example, in Barren County, the lowest difference (20–10 C) was 10 C. It was reported on 18 April 2010, a dry weather day. On the other hand, the highest difference for this site was 48 C and was reported on 11 August 2010, a humid day

U.S. military installations and extreme weather: an Oklahoma case study on preparation

The readiness and execution of national security missions by The United States Department of Defense (DoD) hinges on military installations being equipped with infrastructure that can support the actions needed to protect the U.S., including extreme weather responses. Extreme weather threatens human lives, property, and military operations nationally. Thus, it is paramount to mitigate these impacts and improve preparedness. Oklahoma is home to five federal military installations, all of which are susceptible to hazardous weather, such as severe thunderstorms, tornadoes, and flooding. At a local level, hazardous weather events can be quite costly in a variety of ways, including disrupting operations, causing economic losses, and leading to injuries. This case study examines the preparedness and impacts of extreme weather events as well as climate change considerations at two Oklahoma military installations (Tinker Air Force Base and Fort Sill). Interviews and a focus group revealed weather-related decisions at these installations were unit-specific and dependent on the weather event. These installations have both short- and long-term preparedness plans for different weather scenarios. The impacts of these weather events ranged from delays/cancellations of training to installation closures. Lastly, climate considerations from DoD have been, and continue to be, included in planning. This study highlights the nuances across different military installations as a function of their differing roles; there is not a ‘one size fits all’ preparedness plan that will work across the board. Further, there is much room to improve military-civilian collaboration to mitigate the effects of extreme weather events and climate change on military installations and their operations.</p

Growing Season Air mass Equivalent Temperature (TE) in the East Central USA

Equivalent temperature (TE), which incorporates both dry (surface air temperature, T) and moist heat content associated with atmospheric moisture, is a better indicator of overall atmospheric heat content compared to T alone. This paper investigates the impacts of different types of air masses on TE during the growing season (April–September). The study used data from the Kentucky Mesonet for this purpose. The growing season was divided into early (April–May), mid (June–July), and late (August–September). Analysis suggests that TE for moist tropical (MT) air mass was as high as 61 and 81 C for the early and mid-growing season, respectively. Further analysis suggests that TE for different parts of the growing seasons were statistically significantly different from each other. In addition, TE for different air masses was also statistically significantly different from each other. The v between TE and T (i.e. TE-T) is smaller under dry atmospheric conditions but larger under moist conditions. For example, in Barren County, the lowest difference (20–10 C) was 10 C. It was reported on 18 April 2010, a dry weather day. On the other hand, the highest difference for this site was 48 C and was reported on 11 August 2010, a humid day