A breakthrough in simulating the Moon’s electrostatic environment on Earth offers a promising foundation for future lunar exploration. By accurately replicating and assessing the effects of lunar dust, this technology provides essential insights for overcoming one of the major obstacles in space missions, paving the way for advanced lunar research and in-situ resource utilization initiatives. Photograph of photoelectric current measurement unit. Credit: Korea Institute of Civil Engineering and Building Technology (KICT)
Developing a lunar base faster by creating an electrostatically charged environment.
Research on establishing the Moon as a forward base for deep space exploration is ongoing worldwide, and Korea is no exception in these efforts. The Korea Institute of Civil Engineering and Building Technology (KICT, President Kim, Byung-suk) successfully implemented an electrostatic environment that simulates the Moon’s surface conditions, not in space but on Earth. The researchers also assessed its performance and effectiveness.
Among the most serious threats in executing lunar missions is the Moon’s surface environment, which is electrostatically charged. Due to its extremely thin atmosphere, the Moon is directly exposed to solar ultraviolet rays, X-rays, solar wind, Earth
KICT’s Simulation Chamber
KICT’s research team led by Dr. Shin, Hyusoung (along with senior researcher Chung, Taeil, and Dr. Park, Seungsoo) developed a chamber designed to simulate electrically charged conditions. The aim is to implement an electrostatic environment that resembles the Moon’s surface.
Diagram showing principle of designed measurement unit with description (not to scale). Credit: Korea Institute of Civil Engineering and Building Technology (KICT)
The chamber developed by KICT incorporates ultraviolet lamps, electronic beams, and plasma generators to positively or negatively charge the surfaces of test objects. Going forward, this equipment can be used to electrostatically charge a replica of lunar soil using ultraviolet radiation and electron beams. It will help to determine how much material adheres to rovers and to anticipate potential problems. This technology goes beyond simply conducting electrostatic charging to simulate the Moon’s electrically charged environment under various conditions, such as day or night environments and while being influenced by Earth plasma.
Advancements in Electrostatic Environment Simulation
The greatest achievement of this research work lies in the developed equipment’s ability to measure, in a quantitative and independent manner, the amount of photoelectric current generated, which has the most significant effect on the charging of lunar dust during the day of the Moon. The error between the experimental measurement obtained in this research and the corresponding theoretical value was within approximately 5%, demonstrating the reliability of the developed technology.
As such, KICT’s attempts have been successful not only in reproducing a Moon-like environment where soil dust remains electrostatically charged but also in developing assessment technology for it. This research work has laid the groundwork for equipping a large-scale dirty thermal vacuum chamber (DTVC) with the developed equipment to implement an electrostatically charged environment and further assess its performance.
Dr. Shin, who led this project, said, “Our research presents the possibility of effectively integrating the full-size DTVC, developed by Korea for the first time in the world, with lunar dust charging technology. This solution will serve as a test bed for a series of technologies to implement in-situ resource utilization (ISRU) on the Moon in the future, addressing and responding to a range of potential technological challenges posed by electrically charged lunar dust.
Reference: “Design and Validation of a Photoelectric Current Measuring Unit for Lunar Daytime Simulation Chamber” by Seungsoo Park, Taeil Chung, Jihyun Kim, Byunghyun Ryu and Hyusoung Shin, 10 January 2024, Aerospace.DOI: 10.3390/aerospace11010069
This research was supported by the KICT Research Program (project no. 20230081-001, Development of Environmental Simulator and Advanced Construction Technologies over TRL6 in Extreme Conditions) funded by the Ministry of Science and ICT.