UCLA – Institute for Planets and Exoplanets (2024)

In the third of a ‘trilogy’ of the latest missions to explore Mars, first China with Tianwen-1 successfully reaching the Red Planet (with plans to ambitiously deploy a rover to the surface in May/June of this year). Second was Dubai and the United Arab Emirates successfully sending their Hope spacecraft to Mars, being the very first Arab nation to make a stake in the field of planetary science with a successful mission, paving the way for other countries to do the same. Finally, today, it is with tremendous pleasure to announce that the United States and NASA has successfully launched, deployed, and landed another rover (Perseverance) this afternoon (Earth time) on Mars at Jezero Crater.

Many UCLA scientists have a major stake in this mission such as fellow iPLEX member, Dr. David A. Paige, the Deputy Principal Investigator of the RIMFAX instrument. Paige, his research team, and his Graduate Students will lead the charge in new science found on Mars with this instrument, in easily, the heaviest, most scientifically capable, and best technology yet to land on Mars. As interestingly, another UCLA professor and iPLEX member, Dr. Mackenzie Day has led a team of students and researchers interested in studying Jezero Crater and the likelihood of water on Mars, and what this may mean geologically, and biologically for everything to be found at this scientifically fascinating location. The list goes on and on for other researchers in UCLA’s Earth, Planetary, and Space Sciences Department (EPSS) where we are interested to know more about the origins of life, planetary science, geology, seismology, space physics, and how each of these fields are actually intertwined together.

We hope that much great science will be done in the years to come and look forward to a treasure trove of data and scientific analysis that will come from this rover and mission. Not only is it a testament to the engineering teams at NASA’s Jet Propulsion Laboratory, making another successful touchdown on Mars, but it is also to inspire others to do the same, and learn more about planetary science.

-Dave Milewski

  • NASA’s Perseverance rover has landed on Mars following a 239 million-mile journey through space
  • It traveled around 12,000mph and will deploy a parachute to slow down before landing safelyon the surface
  • The sky crane performed the same landing maneuver as with Curiosity using long Nylon cords
  • The crane released Perseverance from its grasp and flew to safety, allowing the rover to start its journey
  • Perseverance will search for biosignatures in the Jezero crater that is said to be an extinct lake
  • It will collected samples and cache them across Mars for a separatemission in 2023 to retrieve

NASA’s Perseverance rover has successfully landed on Mars following a 239 million-mile journey.The rover survived the ‘seven minutes of terror’ when it endured tumultuous conditions that battered the craft as it entered the Martian atmosphere and approached the surface.

‘NASA works. When we put our arms together and our hands together and our brains together, we can succeed. This is what NASA does,’ says chief engineer and landing veteran Rob Manning.

Perseverance shot like a speeding bullet through the atmosphere going 12,000mph and successfully deployed the sonic parachute which slowed it down to make a soft landing on the surface.

It descended down on the parachute, the backshell separated and the sky crane maneuver carried Perseverance to the ground attached to long Nylon cables.

Perseverance touched downat the base of an 820-foot-deep (250 meters) crater called Jezero, a former lake which was home to water 3.5 billion years ago.

The Martian surface is littered with craters but what makes Jezero Crater so special is that itan inflow and outflow channel, which suggests it was filled with water some 3.5 billion years ago.

Thomas Zurbuchen, of the NASA Science Mission directorate, said: ‘It was an exciting day to think we’re looking to bring samples of Mars back to Earth.’

‘We’re turning our rover into a robotic geologist and astrobiologist, collecting samples that we will be bringing back to Earth, that is what we’re looking forward to.’

UCLA – Institute for Planets and Exoplanets (1)
UCLA – Institute for Planets and Exoplanets (2)

Radio signals between Perseverance and NASA took 11 minutes to be sent due to the time it takes for the signals to travel all the way to Mars and back again.

As a result, Perseverance’s on-board computers and 19 cameras were entirely responsible for the descent.

Former US Vice President, Mike Pence, congratulated NASA on the achievement, adding that ‘Perseverance will help us continue to unlock the mysteries of space and one day land Americans on the Red Planet’.

Unlike previous NASA rovers to Mars — Sojourner, Spirit, Opportunity and Curiosity — Perseverance is purposely being sent to a more treacherous part of the red planet.

This is because the Jezero Crater is thought to be an extinct lake and is also close to curious rock formations, all of which are of great scientific interest back on Earth.

The massive crater is said to have once flowed with water and is littered with carbonates and hydrated silica.

Carbonates similar to those at the crater’s inner rim have been found in fossils on Earth which are billions of years old. Hydrated silica is known for its ability to preserve biosignatures.

UCLA – Institute for Planets and Exoplanets (3)
UCLA – Institute for Planets and Exoplanets (4)
UCLA – Institute for Planets and Exoplanets (5)

Prior to the landing, NASA officials did say ‘it is not guaranteed that we will be successful.’


To increase the chance of success, Perseverance was the first mission to be fitted with ‘Terrain Relative Navigation’ which will take images of the Martian surface during the descent. The information gathered from this will be used to inform the rover’s decision as to where it will land.

UCLA – Institute for Planets and Exoplanets (6)
UCLA – Institute for Planets and Exoplanets (7)
UCLA – Institute for Planets and Exoplanets (8)
UCLA – Institute for Planets and Exoplanets (9)
UCLA – Institute for Planets and Exoplanets (10)
UCLA – Institute for Planets and Exoplanets (11)

It completed the final approach to the surface and slowed the craft down from 190 miles per hour to a mere 1.7 miles per hour while also steering the lander.

The craft will then attempt the ‘skycrane’ maneuver which was first developed for Curiosity in 2012.

Nylon cords will hold Perseverance 25 feet below the jetpack and gently place the rover down on the red soil.

At this point, the craft will cut the nylon cords and fly away to ensure it does not damage Perseverance.

Dr Brown says the whole process is fraught with danger.

‘You never know what Mars throws at you for surprises while the lander carries out these complex maneuvers by itself,’ he adds.

NASA established a radio connection with the rover before Perseverance did a series of checks and then starts its experiments and investigations.

Unlike previous NASA rovers to Mars — Sojourner, Spirit, Opportunity and Curiosity — Perseverance is purposely being sent to a more treacherous part of the red planet.

This is because the Jezero Crater is thought to be an extinct lake and is also close to curious rock formations, all of which are of great scientific interest back on Earth.

‘NASA works. When we put our arms together and our hands together and our brains together, we can succeed. This is what NASA does,’ says chief engineer and landing veteran Rob Manning.

Perseverance, the biggest, most advanced rover ever sent by NASA, became the ninth spacecraft to successfully land on Mars, every one of them from the U.S., beginning in the 1970s.

Deputy project scientist Ken Williford said: ‘Are we alone in this sort of vast cosmic desert, just flying through space, or is life much more common?’

‘Does it just emerge whenever and wherever the conditions are ripe?’

‘We´re really on the verge of being able to potentially answer these enormous questions.’

UCLA – Institute for Planets and Exoplanets (12)
UCLA – Institute for Planets and Exoplanets (13)

The first act of Perseverance — which has been based on the blueprint of Curiosity and is the seven feet tall, nine feet wide and weighs 2,260 pounds — was to release its accompanying Ingenuity helicopter.

The copter will fly at an altitude that is similar to 100,000 feet on Earth, allowing it to gather geological data in areas the rover is unable to reach.

This exceptional height is made possible due to the thin atmosphere on Mars, which is just 1/1,000 as thick as Earth’s. Its two levels of blades will rotate in opposite directions at up to 2,400 rpm.

This will be the first time a terrestrial helicopter has not only flown at such altitudes, but also the first time it will take flight on another planet.

NASA is comparing this mission ‘to the Wright brothers moment’ and believes Ingenuity is going to transform how we think about exploring worlds in the future.

Perseverance’s primary goal is to look for ‘biosignatures’ — signs of past or present microbial life — as well as gathering rock samples which will be picked up by another mission in 2026.

The rover will drill into the dusty surface and gather material into titanium, germ free tubes that will be placed in the vehicle’s belly.

NASA aims to gather at least 20 samples with a variety of material that can be brought back to Earth for further analysis.

The successful landing of the rover was metwith applause and loud cheers across eight rooms as the teams were split up in order to be Covid secure.

Steve Jurczyk, Nasa’s acting administrator, said: ‘It’s amazing to have Perseverance join Curiosity on Mars and what a credit to the team.

‘Just what an amazing team to work through all the adversity and all the challenges that go with landing a rover on Mars, plus the challenges of Covid.

‘And just an amazing accomplishment.’

NASA has teamed up with the European Space Agency (ESA) for the follow up mission to retrieve the samples, with at least two crafts expected for the project.

‘In 2026, we’re going to launch a mission from Earth to Mars to go pick up those samples and bring them back to Earth,’ NASA administrator Jim Bridenstine said previously.

‘For the first time in history, we’re doing a Mars sample return mission.’

UCLA – Institute for Planets and Exoplanets (14)

Lori Glaze from NASA’s planetary science division, said scientists have wanted to bring samples of Mars back to Earth fro a ‘very long time’.

‘We have samples of Mars that have come to Earth as meteorites, but we don’t know exactly where they came from on Mars and they had to travel through space which changes the rocks from what they were on Mars.

‘Going to Mars and bringing samples back from Mars which we know we can keep pristine will help us answer questions about the history of Mars and how it evolved’

She added it will also help to answer questions about the geologic history of Mars, understanding how it evolved and answer important questions about whether life existed three and a half billion years ago and whether it has been preserved.

The sample tubes that Perseverance will be placing rock and soil samples into are the ‘cleanest things ever created on Earth’.

This is because they want to check whether those samples contain ancient Martian life and so it had to be created so they wouldn’t be contaminated by Earth DNA.

This is probably the most challenging thing we have ever tried to do and have partners with the European Space Agency who are providing a fetch rover that will pick up samples left by Perseverance and load them into a rocket.

The Mars Ascent vehicle will be the first ever launch from another planet and it will rendezvous with a European spaceship that will return it back to Earth.

British researchers and the UK Space Agency are also involved in this process.

Academics at Imperial and the Natural History Museum will help decide which samples of Martian terrain should be saved and returned by the ESA mission.

The British Government provided almost half a million pounds towards the Perseverance project.

The rover itself is estimated to have cost $2.2billion (£1.6billion) to build, according to the Planetary Society.

Its launch atop the Atlas V 541 rocket likely cost a further $243million (£174.5million) and the two-year cost of operations is estimated to run up a bill of a further $300million (215million), taking the total estimated cost of Perseverance to $2.7billion (£1.94billion).

All of Perseverance’s missions on Mars will be orchestrated by its 19 cameras and powered 10.6 pounds of plutonium carried in a custom container roughly the size of a bucket.

The plutonium provides 2,000 watts of thermal power and will last for around 14 years. NASA says.

Other work of Perseverance, which is scheduled to be operational for one Martian year (687 Earth days), involvesinvestigating if materials found on Mars can be utilised to facilitate return missions.

This task is called the Mars Oxygen In-Situ Resource Utilization Experiment (MOXIE) and is preparing for human exploration of Mars.

One goal of MOXIE is to convert elements of the carbon dioxide-rich Martian atmosphere into oxygen.

If successful, this will lay out the blueprint for how future crewed missions will turn the Martian atmosphere into rocket fuel and breathable air for astronauts.

Once the ESA mission collects and returns the samples of Mars to Earth in 2031, scientists will cut the slabs into thin sheets of rock in order to determine if individual microbial cells are hiding in the samples.

Perseverance is also fitted with other instruments, including advanced cameras, radar, and a laser.

The rover will use its high-powered laser, called SuperCam, at the top of its mast to shoot high-energy pulses capable of vaporizing rocks up to 20 feet away.

The laser beam heats the target to 18,000 degrees Fahrenheit, which is hot enough to transform the solid rock into plasma that can be imaged by a camera for further analysis.

UCLA – Institute for Planets and Exoplanets (15)
UCLA – Institute for Planets and Exoplanets (16)

This instrument will help researchers identify minerals that are beyond the reach of the rover’s robotic arm or in areas too steep for the rover to go.

Although the rover is very similar in design to Curiosity, it has a new array of sensors and equipment, including, for the first time, microphones.

These will record what the entry, descent and landing sounds like, as well as revealing any noises on the surface of Mars.

Dr Brown said: ‘Not only will we then be able to see a region of Mars in all its detail, but also handle material from there and hear what it would be like standing there.

‘Indeed a striking achievement of rover technology when it all comes together this evening. I can’t wait.’

Perseverance launched on July 30 from Cape Canaveral Florida aboard a United Launch Alliances Atlas V rocket following probes also sent to Mars by the UAE and China.

The recent spate of launches to Mars is because astronomers are keen to take advantage of a rare alignment in the orbits of Earth and Mars which makes the red planet relatively close and accessible for a period of a few weeks.

The United States has plans to send astronauts to Mars in the 2030s under a program that envisions using a return to the moon as a testing platform for human missions before making a more ambitious crewed journey to Mars.

Earlier this month, the United Arab Emirates become the first Arab nation and only the fifth nation overall to place a spaceship in orbit around Mars.

The country’s space probe, called Hope, officially entered Mars orbit at around 16:15 GMT on February 9.

Hope will be the first probe to provide a complete picture of planet’s atmosphere and its layers, according to the UAE.

China’s orbiter and rover combo – named Tianwen-1 – successfully reached Martian orbit on February 10.

Story reprinted from dailymail.co.uk by Authors: Stacy Liberatore For Dailymail.com and Ryan Morrison For Mailonline and Joe Pinkstone For Mailonline

UCLA – Institute for Planets and Exoplanets (2024)

FAQs

Why is it hard to study exoplanets? ›

Because exoplanets exist outside our solar system, orbiting other stars, they can be hard to capture with a telescope. In fact, even Neptune, in our own solar system, is a blurry blue ball when viewed form Earth's orbit. Because of this, it can be hard to find exoplanets.

Why is it so difficult to take pictures of extrasolar planets? ›

The major problem astronomers face in trying to directly image exoplanets is that the stars they orbit are millions of times brighter than their planets.

Why is the presence of a planet orbiting a nearby star often detectable because the planet will make the star? ›

This is because the parent star will wiggle more with a large planet nearby, thereby creating a larger and more easily detectable spectral shift. Most planets discovered around other stars have been very massive and orbit extremely close to their parent star.

What has been the most successful method for detecting exoplanets around other stars? ›

The transit method for finding exoplanets has been wildly successful for NASA's Kepler and K2 missions, which have discovered more than 3,000 confirmed planets to date, and is currently used by NASA's Transiting Exoplanet Survey Satellite (TESS).

What is the hardest planet to study? ›

Difficult to observe

Out of the five planets known since ancient times as the 'wandering stars', Mercury is the one least explored. Unlike Venus, Mars, Jupiter and Saturn, Mercury is notoriously difficult to observe from Earth. Being the innermost planet of the Solar System, it always appears too close to the Sun.

What is the hardest thing to learn in astronomy? ›

Neil: The hardest thing, I think by far, is how we analyze spectra — light broken up into its component colors. It's so abstract, so removed from the actual object we're studying. See, chemists can study actual chemicals in the lab. Biologists can study actual plants.

Has anyone ever photographed an exoplanet? ›

2M1207b is the first exoplanet directly imaged and the first discovered orbiting a brown dwarf. It was imaged the first time by the VLT in 2004.

Will we ever take real images of exoplanets? ›

Will we ever take real images of exoplanets? Yes! In recent years, NASA has taken images, called direct imaging, of exoplanets that are light-years away.

Is it possible to directly image an exoplanet? ›

That's why nearly all of the worlds we've discovered around other stars so far have been found indirectly, thanks to the effect they have on their host star. However, relatively recent advancements in technology allow astronomers to take real images and spectra of exoplanets.

Was it ever possible or is it currently possible for Jupiter to become a star? ›

Jupiter, while more massive than any other planet in our solar system, is still far too underweight to fuse hydrogen into helium. The planet would need to weigh 13 times its current mass to become a brown dwarf, and about 83 to 85 times its mass to become a low-mass star.

How can astronomers tell if planets are orbiting other stars? ›

The vast majority of planets around other stars have been found through the transit method so far. This technique involves monitoring the amount of light that a star gives off over time, and looking for dips in brightness that may indicate an orbiting planet passing in front of the star.

Was our solar system created by the gravitational collapse? ›

The nebular hypothesis says that the Solar System formed from the gravitational collapse of a fragment of a giant molecular cloud, most likely at the edge of a Wolf-Rayet bubble. The cloud was about 20 parsecs (65 light years) across, while the fragments were roughly 1 parsec (three and a quarter light-years) across.

What was the first planet discovered without a telescope? ›

Uranus was discovered in 1781 by William Herschel. Until then, the Solar System was thought to consist of the planets Mercury, Venus, Earth, Mars, Jupiter and Saturn. All of those are visible to the naked eye, and are known since prehistoric times.

What is the biggest problem to detect exoplanets? ›

Distance: Exoplanets are often located many light-years away from Earth, making their detection and study more complicated due to the vast distances involved. False Positives: Signals that might indicate the presence of an exoplanet can sometimes be caused by other phenomena, leading to false detections.

What is the closest exoplanet to Earth? ›

Proxima Centauri b is the closest exoplanet to Earth, at a distance of about 4.2 ly (1.3 parsecs). It orbits Proxima Centauri every 11.186 Earth days at a distance of about 0.049 AU, over 20 times closer to Proxima Centauri than Earth is to the Sun.

What are the challenges of finding exoplanets? ›

Challenges in Detecting Exoplanets
  • Brightness of Stars: Stars are much brighter than the planets that orbit them. ...
  • Small Size and Mass: Many exoplanets, especially those similar in size to Earth, exert only a tiny gravitational effect on their host stars, making them harder to detect through the radial velocity method.
Oct 18, 2023

Why is it difficult to observe an exoplanet directly through a telescope? ›

Direct imaging of exoplanets is extremely difficult and, in most cases, impossible. Being small and dim, planets are easily lost in the brilliant glare of the stars they orbit. Nevertheless, even with existing telescope technology, there are special circ*mstances in which a planet can be directly observed.

Why is it difficult to detect planets? ›

Planets are extremely faint light sources compared to stars, and what little light comes from them tends to be lost in the glare from their parent star. So in general, it is very difficult to detect and resolve them directly from their host star.

What are two reasons it is difficult to directly image exoplanets? ›

Taking images of exoplanets is difficult
  • Problem One: planets are faint.
  • Problem Two: stars are bright.
  • (Partial) solution: move to the infrared.

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