Mars could be a hidden factor behind Earth’s long-term climate cycles, say scientists | – The Times of India

Scientists who work on long-term climate patterns usually stay close to Earth. The data is here, the records are clearer, and the risks are immediate. A new study shifts that focus slightly outward. Research published in the Publications of the Astronomical Society of the Pacific suggests that Mars plays a role in shaping Earth’s climate over very long timescales. The effect is not dramatic or sudden. It unfolds slowly, through gravity and orbital motion. Using simulations of the inner solar system, researchers examined how Earth’s climate rhythms respond to changes in Mars’ mass and position. The results point to a steady influence rather than a dominant one. Earth’s climate, the study suggests, may be less stable without Mars exactly where it is now.

Research points to Mars as a silent partner in Earth’s climate system

Mars is small compared with Earth and far lighter than Jupiter or Saturn. For that reason, it is often treated as background scenery in climate discussions. The study challenges that assumption. In the simulations, Mars acts as a persistent gravitational presence that nudges Earth’s orbital behaviour.These nudges do not rewrite Earth’s climate. They shape its timing. Certain cycles stretch or compress depending on how Mars behaves. When Mars is removed entirely, some of those cycles fade. Others change their rhythm. The effect is subtle enough to be missed in short records but clearer when viewed over millions of years.

Slow orbital cycles are important

Earth’s climate responds to gradual changes in its orbit and rotation. These changes affect how sunlight reaches the surface. Over long periods, they help pace ice ages and warmer intervals. The study focuses on several of these cycles, often grouped under the term Milankovitch cycles. Some are driven by Earth’s tilt. Others depend on how circular its orbit is, or how that orbit shifts in space. Mars does not control these cycles, but it appears to influence their structure. The simulations show that certain patterns only appear when Mars is present with roughly its current mass.

What happens to Earth’s tilt over time

One area of interest is Earth’s axial tilt, known as obliquity. This tilt gives Earth its seasons. It also plays a role in long-term climate balance. According to the simulations, Mars helps keep Earth’s tilt from drifting too far. When Mars is made lighter or removed, Earth’s tilt varies more widely. Over long stretches of time, that wider range could translate into stronger climate swings. The study does not claim this would end life on Earth. It suggests conditions would be harder to predict and possibly less stable.

What exactly did the simulations change

The research team adjusted Mars’ mass across a wide range, from zero to many times its current size. They did not change Earth itself. Instead, they watched how Earth’s orbital features responded. The models tracked variables such as eccentricity, axial tilt, and orbital orientation. Some climate pacing signals remained largely unchanged, especially those linked to Jupiter. Others shifted noticeably as Mars’ mass changed. The results point to sensitivity rather than fragility. Earth’s climate cycles bend more than they break.

Jupiter still dominates the system

Jupiter’s role remains central. Its size and gravity anchor many of the strongest orbital cycles. The study confirms this. Some climate rhythms stay remarkably stable regardless of what happens to Mars.Where Mars seems to matter is in the details. Medium-scale cycles, the ones that shape variability within broader patterns, respond to its presence. This suggests that climate stability is not just about having a giant planet nearby. The spacing and mass of smaller planets also matter.

What does this information suggest about other planets

The findings extend beyond Earth. Astronomers searching for habitable planets often focus on distance from a star. This study points to another factor. A planet may sit in a comfortable temperature zone and still experience extreme long-term swings.A nearby Mars-like planet could help smooth those swings. Without it, a world might remain habitable in theory but unstable in practice. The study offers a way to contemplate these dynamics, rather than a checklist for habitability.

Where the study holds back

The authors are careful about the limits of their work. Only Mars’ mass was varied. Other factors, such as orbital distance or tilt, were left unchanged. Climate models were not directly coupled to the orbital simulations. As a result, the study does not present a complete picture. It isolates one influence and traces its effects. That influence appears real but not decisive.Mars is often discussed as a place humans might visit or once lived on. This research frames it differently. It functions as a silent participant within a larger system. The influence it exerts is slow and indirect. It does not announce itself. Over long periods, though, it seems to shape the background against which Earth’s climate plays out. That role is easy to overlook. The study leaves it there, without pressing the point further.