Integrating K12 Outreach with Undergraduate & Graduate Student Research through BalloonSAT: High Altitude Balloons

The Arkansas BalloonSAT team has successfully launched and recovered 37 BalloonSAT’s dating back to the first flight on December 16, 2006. Numerous instruments measuring such things as atmospheric temperature, humidity, radiation, and light intensity have recorded data from different locations over the State of Arkansas. The initial focus of this project was outreach with the k-12 schools, and still involves outreach; however atmospheric research has become a significant component for this endeavor. This ongoing collaborative projection has involved a number of faculty and students from different academic backgrounds, including physics, chemistry, biology, and astronomy among different ASGC schools who have contributed to this effort. Members of the team have presented at state, regional, national, as well as international conferences. The outreach work with k-12 teachers/students was highlighted in an article Students at the Edge of Space published in the journal The Science Teacher produced by the National Science Teachers Association (January 2008). A photograph taken from a camera mounted in one of the payload boxes flown on Arkansas BalloonSAT 6 made the cover of this journal. Tethered Blimps are a new additional to this program. The investigators have form an initial network of five Arkansas middle & high schools to observe weather trends across the state and engage midlevel & secondary teachers and students in a collaborative research project. These teachers will receive training, equipment, and 13 foot tethered blimps in June 2015. The project aims include but are not limited to identifying urban heat island effects by comparing schools from rural areas and urban areas, and daily variations in relative humidity. A number of these schools are located in rural farming areas where CH4 and CO2 levels will be measured from just above the surface with the blimps to the lower stratosphere via balloons

Long Term Tropospheric and Stratospheric Measurements Using High Altitude Balloons

The Arkansas BalloonSAT program is an educational outreach and research program at Arkansas State University. A variety of instruments including HOBO data loggers, Anasonde, and Arduino methane sensors have been flown on flights in the past five years. Measurements using BalloonSAT provides a cost effective option, while also matching measurements made with satellites and unmanned aerial vehicles. This includes identifying water vapor, pressure, background radiation, methane, carbon dioxide and temperature profiles over seasons and years. Water vapor trends were observed to vary with seasons, with water vapor lowest in the summer and greatest in the spring at stratospheric altitudes. Methane and carbon dioxide were observed to decrease with higher altitudes because of the greater distance from emission sources. Temperature measurements followed typical atmospheric profile measurements with an inversion at the stratosphere

Balloon-borne methane and radiation measurements

The BalloonSAT program is a high altitude research and education outreach program at Arkansas State University. Weather balloons carried a Geiger counter that measured X-ray, β, and γ radiation profiles together and a methane sensor (Arduino and MQ-6 detector) in payload boxes to 30 km (90,000 ft) over the past five years. Payload boxes were foam containers for water resistant and floating abilities in possible water landings, no modifications beyond securing sensors to the payload box were made. Methane and radiation measurements are not directly related, but collected independently and flown on many flights together and therefore presented together. A radiation peak related to decreasing cosmic radiation and increased secondary radiation, or Pfotzer maximum at 10-15 km was found. Lower tropopause temperatures were related to higher radiation counts at the Pfotzer maximum. Methane is 30 times more potent as a greenhouse gas than carbon dioxide. A linear calibration curve was made with known concentrations of methane at various temperatures to convert voltage readings into concentrations. The low temperatures and pressure were not found to significantly impact concentration measurements. Methane concentration was found to decrease with altitude similar to satellite and Unmanned Aerial Vehicle (UAV) measurements. BalloonSAT does not collect data that can replace satellites, but proves to be an effective instrument in identifying radiation and methane profiles in the troposphere and lower stratosphere comparable to other balloon-borne, UAV and satellite studies

Observing the 2017 Total Solar Eclipse in the skies above Central Missouri, USA

We report the work and findings of Arkansas BalloonSAT in participating in the 2017 Eclipse Ballooning Project. Arkansas BalloonSAT was the site-team for Missouri and launched a high altitude balloon from Fulton High School in Fulton, MO an hour prior to totality. This balloon reached an apogee of 24 kilometers shortly after floating for one minute in the moon\u27s umbra. In addition to live-streaming video from one payload as part of the Eclipse Ballooning Project, our mission included carrying a scientific payload and educational outreach. This report will summarize those efforts and include an examination of balloon kinematics with the cooling effect of the moon\u27s umbra and aircraft-balloon interaction. We further discuss developments in the system to minimize payload size for future eclipse studies

Integrating K12 Outreach with Undergraduate & Graduate Student Research through BalloonSAT: High Altitude Balloons

The Arkansas BalloonSAT team has successfully launched and recovered 37 BalloonSAT’s dating back to the first flight on December 16, 2006. Numerous instruments measuring such things as atmospheric temperature, humidity, radiation, and light intensity have recorded data from different locations over the State of Arkansas. The initial focus of this project was outreach with the k-12 schools, and still involves outreach; however atmospheric research has become a significant component for this endeavor. This ongoing collaborative projection has involved a number of faculty and students from different academic backgrounds, including physics, chemistry, biology, and astronomy among different ASGC schools who have contributed to this effort. Members of the team have presented at state, regional, national, as well as international conferences. The outreach work with k-12 teachers/students was highlighted in an article Students at the Edge of Space published in the journal The Science Teacher produced by the National Science Teachers Association (January 2008). A photograph taken from a camera mounted in one of the payload boxes flown on Arkansas BalloonSAT 6 made the cover of this journal. Tethered Blimps are a new additional to this program. The investigators have form an initial network of five Arkansas middle & high schools to observe weather trends across the state and engage midlevel & secondary teachers and students in a collaborative research project. These teachers will receive training, equipment, and 13 foot tethered blimps in June 2015. The project aims include but are not limited to identifying urban heat island effects by comparing schools from rural areas and urban areas, and daily variations in relative humidity. A number of these schools are located in rural farming areas where CH4 and CO2 levels will be measured from just above the surface with the blimps to the lower stratosphere via balloons

Long Term Tropospheric and Stratospheric Measurements Using High Altitude Balloons

The Arkansas BalloonSAT program is an educational outreach and research program at Arkansas State University. A variety of instruments including HOBO data loggers, Anasonde, and Arduino methane sensors have been flown on flights in the past five years. Measurements using BalloonSAT provides a cost effective option, while also matching measurements made with satellites and unmanned aerial vehicles. This includes identifying water vapor, pressure, background radiation, methane, carbon dioxide and temperature profiles over seasons and years. Water vapor trends were observed to vary with seasons, with water vapor lowest in the summer and greatest in the spring at stratospheric altitudes. Methane and carbon dioxide were observed to decrease with higher altitudes because of the greater distance from emission sources. Temperature measurements followed typical atmospheric profile measurements with an inversion at the stratosphere

Balloon-borne methane and radiation measurements

The BalloonSAT program is a high altitude research and education outreach program at Arkansas State University. Weather balloons carried a Geiger counter that measured X-ray, β, and γ radiation profiles together and a methane sensor (Arduino and MQ-6 detector) in payload boxes to 30 km (90,000 ft) over the past five years. Payload boxes were foam containers for water resistant and floating abilities in possible water landings, no modifications beyond securing sensors to the payload box were made. Methane and radiation measurements are not directly related, but collected independently and flown on many flights together and therefore presented together. A radiation peak related to decreasing cosmic radiation and increased secondary radiation, or Pfotzer maximum at 10-15 km was found. Lower tropopause temperatures were related to higher radiation counts at the Pfotzer maximum. Methane is 30 times more potent as a greenhouse gas than carbon dioxide. A linear calibration curve was made with known concentrations of methane at various temperatures to convert voltage readings into concentrations. The low temperatures and pressure were not found to significantly impact concentration measurements. Methane concentration was found to decrease with altitude similar to satellite and Unmanned Aerial Vehicle (UAV) measurements. BalloonSAT does not collect data that can replace satellites, but proves to be an effective instrument in identifying radiation and methane profiles in the troposphere and lower stratosphere comparable to other balloon-borne, UAV and satellite studies