![]() To improve its understanding of plume-surface interactions (PSI), researchers at NASA's Marshall Space Flight Center in Huntsville, Alabama, have developed new software tools to predict PSI environments for NASA projects and missions, including the Human Landing System, Commercial Lunar Payload Services initiative, and future Mars landers. Credit: Patrick Moran, NASA Ames Research Center/Andrew Weaver, NASA Marshall Space Flight Center Lower shear stress is dark purple, and higher shear stress is yellow. ![]() Here, the fluctuating radial patterns show the intensity of predicted shear stress. Known as shear stress, this is the amount of lateral, or sideways, force applied over a set area, and it is the leading cause of erosion as fluids flow across a surface. This animation depicts the last half-minute of descent before engine cut-off, showing the predicted forces exerted by plumes on a flat computational surface. ![]() Researchers at NASA’s Marshall Space Flight Center in Huntsville, Alabama produced a simulation of the Apollo 12 lander engine plumes interacting with the lunar surface. Although craters were not formed for Apollo-scale landers, it is unknown how much the larger landers being planned for upcoming Artemis missions will erode the surface and whether they will rapidly cause cratering in the landing zone, posing a risk to the lander's stability and astronauts aboard. This can cause hazards like visual obstructions and dust clouds that can interfere with navigation and science instrumentation or cause damage to the lander and other nearby hardware and structures.Īdditionally, the plumes can erode the surface under the lander. This happens in an extreme environment that's hard to replicate and test on Earth, namely, a combination of low gravity, no atmosphere, and the unique properties of lunar regolith-the layer of fine, loose dust and rock on the moon's surface.Įach time a spacecraft lands or lifts off, its engines blast supersonic plumes of hot gas toward the surface and the intense forces kick up dust and eject rocks or other debris at high speeds. ![]() When missions fly crew and payloads to the lunar surface, spacecraft control their descent by firing rocket engines to counteract the moon's gravitational pull. ![]()
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