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As new probes reach Mars, here’s what we know so far from trips to the red planet.

This resource covers science outcomes across all sciences from Years 5-10. It may be of particular interest to students learning about the needs for life, rocks on Mars, and the global effort to explore other planets.

Word Count / Video Length: 931 / 0:59 mins / 2:01 mins

Three new spacecraft are due to arrive at Mars this month, ending their seven-month journey through space.

The first, the United Arab Emirates’ Hope Probe, should have made it to the red planet last week. It will stay in orbit and study its atmosphere for one complete Martian year (687 Earth days).

China’s Tianwen-1 mission also enters orbit this month and will begin scouting the potential landing site for its Mars rover, due to be deployed in May.

If successful, China will become the second country to land a rover on Mars.

These two missions will join six orbiting spacecraft actively studying the red planet from above:

The oldest active probe – Mars Odyssey – has been orbiting the planet for 20 years.

The third spacecraft to reach Mars this month is NASA’s Perseverance rover, scheduled to land on February 18 [UPDATE: Perseverance landed successfully in the Jezero Crater, Mars on Friday 18 February, 2021.]. It will search for signs of ancient microbial life but its mission also looks ahead, testing new technologies that may support humans visiting Mars one day.

Now NASA hopes Perseverance will land on Mars.

Laboratories on wheels

NASA has an impressive track record for landing on Mars. It has operated all eight successful missions to the Martian surface.

What began with the two Viking landers in the 1970s continues today with the InSight lander, which has studied the daily weather on Mars and detected Marsquakes for the past two years.

Just minutes after landing, Viking 1 captured the first ever photograph taken from the Martian surface. Credit: NASA/JPL

Perseverance will be the fifth rover to arrive on Mars that’s capable of venturing across the surface of another planet.

These amazing laboratories on wheels have extended our knowledge of a faraway world. Here’s what they’ve told us so far.

The first rover – Sojourner

Twenty years after Viking 1 & 2 landed stationary probes on Mars, a third spacecraft finally reached the planet, but this one could move.

On July 4, 1997, NASA’s Pathfinder literally bounced onto the Martian surface, safely enclosed in a giant set of airbags. Once stable, the lander released the Sojourner rover.

See the Sojourner probe from Pathfinder’s viewpoint.

The first rover on Mars could move at a maximum speed of 1cm a second and was about as long (63cm) as a skateboard — smaller than some of the boulders it encountered.

Sojourner explored 16 locations near the Pathfinder lander, including the volcanic rock “Yogi”. Pictures of its landing site, Ares Vallis, showed it was littered with rounded pebbles and conglomerate rocks, evidence of ancient flood plains.

The geologists – Spirit and Opportunity

A pair of upsized rovers arrived on Mars in early 2004. Spirit and Opportunity were geologists, searching for minerals within the rocks and soil, hidden clues that dry, cold Mars may once have been wet and warm.

This overhead ‘selfie’ was combined with Spirit’s largest ever panorama – it contains hundreds of individual images of Gusev Crater taken over three Martian days. Credit: NASA/JPL-Caltech/Cornell

Spirit landed in Gusev Crater, a 150km-wide crater created billions of years ago when an asteroid crashed into Mars.

Spirit discovered evidence of an ancient volcanic explosion, caused by hot lava meeting water. Small rocks had been thrown skyward but then fell back to Mars. Examination of the impact or “bomb sag” showed the rock had landed on wet soil.

The arrow points to a small crater or bomb sag, just 4cm across, that formed in the soaking wet ground when an ejected rock fell back to Mars. Credit: NASA/JPL-Caltech/USGS/Cornell

Even when things went wrong, Spirit made new discoveries. While dragging a broken front wheel, Spirit churned up a track of soil revealing a patch of white silica.

This mineral usually exists in hot springs or steam vents, ideal environments where life on Earth tends to flourish.

A 20cm track revealing white silica and a clue that Mars was once wet and warm. Credit: NASA/JPL/Cornell

The rover that kept on going

Opportunity arrived on Mars three weeks after Spirit. Its original three-month mission was extended to 14 years as it travelled almost 50km across the Martian terrain.

Landing in the small Eagle Crater, Opportunity went on to visit more than 100 impact craters. It also found a handful of meteorites, the first to be studied on another planet.

Outlined in yellow is Opportunity’s journey from Eagle Crater towards its final resting spot on the rim of Endeavour Crater. The blue outline of Victoria’s Phillip Island is included for scale. Credit: NASA/JPL-Caltech/MSSS/Museums Victoria

The rover was descending into Endeavour Crater when a dust storm ended its mission. But it was along the crater’s edge that Opportunity made its biggest discoveries.

It found signs of ancient water flows and discovered the crater walls are made of clays that can only form where freshwater is available — more evidence that Mars could well have been a place for life.

The chemist – Curiosity

Curiosity landed in Gale Crater on August 6, 2012, and continues to explore the region today. During the coronavirus pandemic, scientists and engineers have been commanding the rover from their homes.

An artist’s impression of Curiosity as it descends from the top of the Martian atmosphere to softly touchdown on the planet’s surface. Credit: NASA/JPL-Caltech

In a first for space exploration, NASA’s Curiosity was lowered to the Martian surface using a “sky crane”. After a successful soft landing, the crane’s cables were cut and the spacecraft’s descent stage flew away to crash elsewhere.

Curiosity is a fully equipped chemical laboratory. It can shoot lasers at rocks and also drill into the soil to collect samples. It’s confirmed ancient Mars once had the right chemistry to support microbial life.

Curiosity also found evidence of ancient freshwater rivers and lakes. It seems that water once flowed towards a basin at Mount Sharp, a central peak that rises 5.5km from within Gale Crater.

Curiosity takes a picture of itself, working through the COVID-19 pandemic and drilling holes in a possible ancient riverbed. Credit: NASA/JPL-Caltech/MSSS

From being on the surface of Mars, we’ve learned it was once very different to the dry, dusty planet it is today.

With flowing water, possible oceans, volcanic activity and an abundance of key ingredients necessary for life, the red planet was once much more Earth-like. What happened to make it change so dramatically?

It’s exciting to consider what the Perseverance and Taiwen-1 rovers may discover as they explore their own patch of Mars. They might even lead us to the day when humans are exploring the red planet for ourselves.

The colours in this image from Gale Crater have been adjusted to match conditions on Earth – this helps geologists interpret the rocks but it also changes the natural pink Martian sky to an Earth-like blue. Credit: NASA/JPL-Caltech

The Conversation
Authored by Tanya Hill, Honorary Fellow of the University of Melbourne and Senior Curator (Astronomy), Museums Victoria

This article is republished from The Conversation under a Creative Commons license. Read the original article.

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Years: 5, 6, 7, 8, 9, 10


Biological Sciences – Cells

Chemical Sciences – Chemical Reactions

Earth and Space Sciences – The Solar System, Rocks, Plate Tectonics

Physical Sciences – Forces

Additional: Careers, Technology, Engineering.

Concepts (South Australia):

Biological Sciences – Diversity and Evolution, Form and Function

Chemical Sciences – Change of Matter

Earth and Space Sciences – The Earth’s Surface, Earth in Space

Physical Sciences – Forces and Motion