What keeps Venus looking so young? A powerful jolt early on, perhaps

A new study suggests that higher-energy bolide impacts created a superheated core and extended volcanism on Venus — leading to its younger surface appearance.
A depiction of Venus being bombarded by bolides.

(Credit: SwRI)

Researchers at Yale and the Southwest Research Institute may have discovered the secret to Venus’s youthful appearance: a high-energy, rejuvenating boost it received in its earliest years.

For decades, the relatively unblemished surface of Venus has distinguished it from nearby planets and moons, including Earth.

Mars, for instance, and Earth’s moon, bear the craggy scars and craters from the bombardment of bolides — bright meteors that hit the surface as fireballs — over billions of years. Earth’s surface appearance, by contrast, benefits from its system of plate tectonics that “recycles” the surface of the planet on a regular basis.

Venus does not have plate tectonics. Even still, despite being about 4.5 billion years old, Venus has the outward appearance of a much younger planet; its surface age is only 500 million years.

We would expect Venus to be heavily cratered, but surprisingly, it is much less cratered than the moon or Mars,” said Jun Korenaga, a professor of Earth and planetary sciences in Yale’s Faculty of Arts and Sciences and co-author of a new study in Nature Astronomy.

Many scientists have tried to explain this young surface age of Venus,” Korenaga said. “One popular idea is that Venus used to have plate tectonics, but somehow it stopped about 500 million years ago. This explanation is admittedly ad hoc, so others have tried to come up with models that are physically more sound, with limited success.”

Yale’s Korenaga, working with lead author Simone Marchi and co-author Raluca Rufu of the Southwest Research Institute in Boulder, Colorado, believe they have solved the mystery.

In their study, they consider the idea that Venus systematically experienced more powerful bolide impacts than Earth did, particularly in the early years of the solar system, about 4.5 billion years ago. During that period, Korenaga said, the rate and magnitude of bolide bombardments were quite high because an abundance of leftover planetary building material remaining in space. As time went by, the intensity of bombardments declined.

This high resolution (1 million particles) computer simulation illustrates a 1,800-mile-diameter (3,000-kilometer) projectile striking Venus head-on at 18 miles per second (30km/s). On the left, the colors indicate different materials — brown for Venus core; white for projectile core; and green for the silicate mantle of both objects. The colors on the right side indicate the temperature of the materials. Created by Dr. Simone Marchi (Southwest Research Institute)

Earth and Venus formed in the same neighborhood of the solar system as solid materials collided with each other and gradually combined to form the two rocky planets. The slight differences in the planets’ distances from the sun changed their impact histories, particularly the number and outcome of these events.

One of the mysteries of the inner solar system is that, despite their similar size and bulk density, Earth and Venus operate in strikingly different ways, particularly affecting the processes that move materials through a planet,” Marchi said.

After running simulations of more systematic bolide impacts, the researchers noticed an intriguing trend: more impacts blasting deeper into Venus led to a superheating of the planet’s core.

This superheated core could have a long-lasting influence on the volcanic history of Venus,” Korenaga said. “It could keep heating up the mantle for a few billion years, with sufficient volcanic activity to cover up most of the craters and reduce the apparent surface age to only a few hundred million years.”

The researchers noted that two upcoming NASA space missions to Venus — VERITAS and DAVINCI — and well as the planned European mission EnVISION, are expected to provide new, high-resolution data on the tectonic and bolide impact history of Venus.

We will be able to test various predictions from our hypothesis, based on this data,” Korenaga said.

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Michael Greenwood: michael.greenwood@yale.edu, 203-737-5151