The Sun’s photosphere, photographed during a solar maximum. Credit: Filipe Pires (Porto Planetarium – Ciência Viva Center & Instituto de Astrofísica e Ciências do Espaço
With data from the Kepler (NASA), Gaia (ESA) and SOHO (NASA/ESA) satellites, a team, led by Instituto de Astrofísica e Ciências do Espaço (IA) researcher Ângela Santos, seems to have put an end to the idea that the sun might not be a regular “sun-like” star. The results were published today (April 6) in Astronomy & Astrophysics.
Although it might seem odd to try to find out if the sun is a sun-like star, Ângela Santos, a researcher at IA, explains the problem: “In the community, there is an ongoing debate on whether the sun is a ‘sun-like’ star. In particular, about its magnetic activity, several studies suggested that stars similar to the sun were significantly more active. However, the problem doesn’t seem to be with the sun, but with the stars classified as sun-like, because there are several limitations and biases in the observational data and the inferred stellar properties,” adds Santos. Extreme ultraviolet (17,1 nm) video of solar activity during the last solar maximum, including the solar Flare of 2014/02/25. Credit: NASA/SDO AIA
For this work, the team chose several stars with similar properties to the sun. The team used a new stellar properties catalog, from Kepler data, plus some Gaia data and the team’s rotation period and magnetic activity index catalog. The stellar data were compared with data of activity from the last two solar cycles, from the VIRGO/SPM instrument aboard the SOHO spacecraft. Extreme ultraviolet (30,4 nm) video of solar activity during the last solar maximum, including the solar Flare of 2014/02/25. Credit: NASA/SDO AIA
One of the studied stars, chosen from the Kepler catalog, was lovingly named Doris by the astronomers. In a previous work, the team had already observed that Doris’ cycle amplitude was twice that of the sun for the latest solar cycles, even though Doris has similar properties to the sun. Santos says, “The difference was the metallicity. Our interpretation is that the effect of metallicity, which leads to a deeper convection zone, produces a more effective dynamo, which leads to a stronger activity cycle.” Continuum (visible light) video of solar activity during the last solar maximum. Credit: NASA/SDO HMI
For this work, when the team selected stars similar to Doris, without considering metallicity in the selection, they found an excess of high metallicity stars. “In our selection, the only parameter that could lead to this excess is the rotation period. In particular, Doris had a longer period than the sun. And, in fact, we found evidence of a correlation between the rotation period and metallicity,” says Santos. Magnetogram video of the Sun, during the last solar maximum. Credit: NASA/SDO HMI
The two studies have consistent results, because stronger magnetic activity means that the magnetic braking process leads to a slower rotation period, which explains why Doris rotates slower than the sun, despite being very similar and slightly younger than the sun.
Ângela Santos says, “What we found is that although there are stars which are more active than the sun, the sun is indeed a completely normal sun-like star.”
