Is this project an undergraduate, graduate, or faculty project?
Undergraduate
group
What campus are you from?
Daytona Beach
Authors' Class Standing
Rithika Nagarajan - Junior Jacob Burdge - Sophomore Jaden Caradine - Freshman Brendan Hayden - Sophomore Kasey Klink - Freshman Evan Murdock - Freshman Evan Root - Freshman Jacob Wotowiec - Freshman Ethan Yemm - Freshman
Lead Presenter's Name
Rithika Nagarajan
Faculty Mentor Name
Sean Crouse
Abstract
Weather balloons play a crucial role in atmospheric data collection, but their vulnerability to lightning strikes remains a significant concern. This study seeks to address two primary objectives: (1) to test the hypothesis that lightning does not significantly interfere with the accuracy of data collected by weather balloon payloads, and (2) to explore the feasibility of using a lightweight Faraday cage to protect the balloon from potential lightning damage. The payload will be equipped with standard sensors for measuring temperature, pressure, and humidity, along with lightning detection equipment to monitor any strikes during the flight. Additionally, the project includes secondary objectives of testing 3D-printed components for CubeSat construction and developing a parachute deployment system for safe recovery of the payload.
As the launch is forthcoming, no results have been obtained yet; however, the study is designed to provide quantitative data on lightning interference, if any, and the protective efficacy of the Faraday cage. The results are expected to offer valuable insights into enhancing the durability of weather balloons in storm-prone environments, while contributing to advancements in CubeSat design and recovery technologies. These findings will contribute to the broader field of atmospheric data collection and space technology development, potentially improving safety and efficiency in future missions.
Did this research project receive funding support from the Office of Undergraduate Research.
No
Project Minerva
Weather balloons play a crucial role in atmospheric data collection, but their vulnerability to lightning strikes remains a significant concern. This study seeks to address two primary objectives: (1) to test the hypothesis that lightning does not significantly interfere with the accuracy of data collected by weather balloon payloads, and (2) to explore the feasibility of using a lightweight Faraday cage to protect the balloon from potential lightning damage. The payload will be equipped with standard sensors for measuring temperature, pressure, and humidity, along with lightning detection equipment to monitor any strikes during the flight. Additionally, the project includes secondary objectives of testing 3D-printed components for CubeSat construction and developing a parachute deployment system for safe recovery of the payload.
As the launch is forthcoming, no results have been obtained yet; however, the study is designed to provide quantitative data on lightning interference, if any, and the protective efficacy of the Faraday cage. The results are expected to offer valuable insights into enhancing the durability of weather balloons in storm-prone environments, while contributing to advancements in CubeSat design and recovery technologies. These findings will contribute to the broader field of atmospheric data collection and space technology development, potentially improving safety and efficiency in future missions.