You selected the right star to explore.
What you are probing is the acoustic oscillations in stars, which is their speed of sound. The acoustic oscillations can tell us about the density and size of an object. As stars get older, they get less dense and bigger. The oscillations in the older stars are deeper (lower frequency). Take for example a cello. It has a low sound because its oscillation cavity is bigger and it is more hollow. The stellar oscillation frequencies can therefore tell us the age of stars. Older stars are less active, so planet signals are easier to detect. Selecting the oldest star would allow for the best potential research. As a result, you must select the oldest star, which is the star with the deepest oscillations in order to win.
You selected the wrong star to explore.
What you are probing is the acoustic oscillations in stars, which is their speed of sound. The acoustic oscillations can tell us about the density and size of an object. As stars get older, they get less dense and bigger. The oscillations in the older stars are deeper (lower frequency). Take for example a cello. It has a low sound because its oscillation cavity is bigger and it is more hollow. The stellar oscillation frequencies can therefore tell us the age of stars. Older stars are less active, so planet signals are easier to detect. Selecting the oldest star would allow for the best potential research. As a result, you must select the oldest star, which is the star with the deepest oscillations in order to win.
You must select a star to continue