New research suggests that a close encounter between the Solar System and a passing star in the past could have resulted in significant changes to Earth's orbit, potentially causing disruptions to the climate.

According to Nathan A. Kaib, Senior Scientist at the Planetary Science Institute and the lead author of the study titled "Passing Stars as an Important Driver of Paleoclimate and the Solar System's Orbital Evolution," perturbations caused by the gravitational pull of nearby stars can lead to lasting alterations in the orbital paths of the sun's planets, including Earth.

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Passing Star May Have Disrupted Earth's Orbit, Leading to Drastic Climate Changes 56 Million Years Ago

Geology, Modeling, and Galactic Intricacies Earth's 4.5 Billion-Year History

In assembling Earth's 4.5 billion-year history, a combination of geology, modeling, and statistical analysis is employed. During the Paleocene-Eocene Thermal Maximum, a perplexing temperature rise of 5 to 8°C occurred. This led planetary scientist Nathan Kaib and astrophysicist Sean Raymond to suggest a random encounter as the likely catalyst.

Reconstructing Earth's orbital evolution is challenging due to uncertainties. Past theories suggested high orbital eccentricity during the warming event. However, Kaib's research highlights that passing stars adds complexity, making precise predictions uncertain and expanding the range of possible orbital behaviors.

Commonly, scientists rewind the Solar System in simulations to understand orbital evolution. Yet, these simulations overlook the dynamic galactic context. Stars, moving at different speeds and trajectories, can influence the Solar System through gravitational interactions, potentially impacting Earth's orbit.

While the Solar System is generally stable, it undergoes tweaks, influenced by factors like the gravitational pull of giant planets. Milankovitch cycles, occurring over tens of thousands of years, bring about changes in Earth's orbital eccentricity, axial tilt, and precession. However, the broader galactic environment, including passing stars, adds layers of complexity to the understanding of Earth's orbital history.

READ ALSO: Earth's Ever-Changing Surface Caused Dynamic Plate Tectonics That Started 1.3 Billion Years After the Planet Formed

Stellar Encounters: HD 7977's Influence on Solar System Dynamics

Kaib and Raymond investigated the potential impact of a passing star, even at a considerable distance. Their study centered on a specific event approximately 2.8 million years ago when a Sun-like star named HD 7977 traversed the Solar System, possibly venturing inside the Oort Cloud.

Although the star's closest approach might have been around 4,000 astronomical units, simulations consistently indicated that even distances closer to the smaller end of the range influenced the planets' movements relative to the Sun.

More specifically, their simulations indicate that the passage of a star near the Solar System might have caused sufficient disturbance to alter the orbits of planets, subtly shifting Earth's trajectory. This significance lies in the geological evidence linking changes in Earth's orbital eccentricity to climate fluctuations.

According to Kaib, understanding Earth's orbit during past climate anomalies is crucial for accurately identifying their causes in the geological record.

While HD 7977 is a singularly identified flyby, scientists estimate that a star passes within 50,000 astronomical units approximately every million years and within 10,000 astronomical units roughly every 20 million years. This implies that a passing star could have impacted Earth's climate in the past, potentially contributing to the thermal maximum.

Kaib and Raymond suggest that future studies on the Solar System's long-term evolution should consider these stellar encounters. They emphasize the importance of these passers-by in the Solar System's extended dynamical evolution, noting that although it takes tens of millions of years for their effects to significantly manifest, they are intricately linked to the long-term orbital evolution of Earth and other planets.

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