Facts About Mars

The Phoenix Mars lander is an ongoing success. It is creating its own Mars phoenix pics collection of some sort and is greatly contributing to science. I tried to collect some of the latest Mars pics direct from phoenix on board camera.

Mars phoenix pics collection.

Taken on sol 95 (Day 95) after Phoenix landed on the surface of Mars. This trench is called the “Stone Soup”. It is the deepest trench the Phoenix ever dug, about 7 inches deep. Scientists are very excited to analyze the composition of the soil at that depth.

Another picture of the “stone soup” trench where the depth is clearly seen.

As the Phoenix lander digs, it creates piles out of the dig. This one is called “caterpillar” which is a pile made from the “stone soup” dig. Piles like this also helps scientists identify the composition of the Martian soil. How the pile slopes and the texture of the soil provides information to the scientists. This pile though, does not seem to contain water ice.

A view of the Phoenix’s work place. Shows some of the trenches that Phoenix dug around his workplace. This picture was taken on Sol 90.

A Martian sunrise, taken during Sol 90. The sun doesn’t fully set during the Martian summer. The skylight shown above is a combination of atmospheric dust particles and ice crystals.

Taken during Sol 79. This picture shows a thin layer of ice on the surface of Mars, this picture was taken during sunrise and the ice disappeared after 6am.

This picture was taken on Sol 17. This was a very exciting moment since this was the very first time that Phoenix delivered soil samples to its MECA (Microscopy, Electrochemistry and Conductivity Analyzer) instrument.

A 3D image of a Martian particle. Red is the highest point and purple is the lowest point. 3D images help scientists understand the dust particles that gives Mars its red appearance. The Phoenix Mars lander is the most successful Mars explorer to date. We are getting so close to knowing whether Mars contained an enormous amount of water before and if it is capable of sustaining life. Who knows, maybe Mars was once like Earth before. That’s all for now. Watch out for some more mars phoenix pics collection.

As of this writing, the Phoenix Mars Lander is on its 88th day of digging and gathering of soil samples on the red planet.

The main purpose of the mission is to gather soil samples and water ice, which is abundant beneath the surface of the north arctic of Mars, in order to determine whether Mars is habitable or if it has harbored life before and to study the history of water on the planet which is important in order to know its past climate and future weather conditions.

The samples will undergo sophisticated chemical experiments in order to assess its life-giving elements such nitrogen, phosphorus, hydrogen and carbon.

Liquid water does not presently exist on the surface of Mars but the canyons suggest that water once flowed on the red planet.

EQUIPMENTS

The Phoenix Mars Lander packs sophisticated equipments that will be used to analyze the samples.

• Surface Stereoscopic Imager – The eyes of the phoenix. Situated on top of the Mars lander, it provides 3D images that helps the Phoenix team choose a dig site.

• Solar Array – A pair of 18-ft wide solar array used to convert solar radiation to electricity. This provides the much needed power to the Mars lander.

• Microscopy, Electrochemistry and Conductivity Analyzer (MECA) – Has 4 tools that will be used to examine soil. Three of which will be used to analyze soil samples scooped by the arm and the fourth one, which is located near the end of the arm, will be used to examine the electrical conductivity of the soil.

• Thermal and Evolved-Gas Analyzer (TEGA) – Used to heat samples and study the substances that turned into gas. Determines whether the samples contain organic compounds and it also helps scientists determine the properties of the Martian soil.

• Meteorological Station - Determines daily weather and seasonal changes with the use of temperature and pressure sensors and laser reflection instrument.

• Robotic Arm – Used to collect samples. Can dig about 20 inches deep and deliver the samples to other instruments.

One of the challenges that faced the mission was it EDL or Entry, Descent, and Landing since the Phoenix will be entering Mars’ atmosphere at 12,500mph and it will take only 7 minutes before it touches the ground. The challenge was, how to get the phoenix from 12,500mph to a screeching halt and land safely on the ground in 7 minutes.

Here’s a video of how the EDL phase was addressed.

And the good news is, the Phoenix Mars Lander landed on Mars safely on May 5, 2008. Here’s a video of the suspenseful moment as aired on CNN.

The mission is successful and the Phoenix is now in the process of collecting data in order to fulfill its objectives.

The Phoenix Mission is led by the University of Arizona, Tucson, on behalf of NASA. Project management of the mission is by NASA’s Jet Propulsion Laboratory, Pasadena, Calif. Spacecraft development is by Lockheed Martin Space Systems, Denver.

I’ve always been fascinated with Mars, when I was a kid, I’d spend hours observing and admiring the planet Mars through my telescope. If not, I’d be at the roof top laying down and looking at the sky. I always imagined it to be a tourist destination that we can visit from time to time. I know we can’t live in Mars permanently since dust storms are pretty frequent in there and the big craters suggests that meteors are also constant visitors. I wonder what kind of houses we will be building in there when the time comes, dust storm and meteor proof?

Anyways, I made this blog in order to further educate myself about the planet Mars and also share all the information that I learned. This is going to be a very informative and fun blog. To those who loves Mars, like me, better bookmark this site to keep yourself updated.

Quick Facts

• Mars is the 4th planet and is 227,940,000 kms away from the sun. That’s roughly 1 1/2 times the distance of Earth from the sun
• Known as the “Red Planet” because of its red and rustic appearance. This is because of the iron-rich minerals in the Martian soil.
• The month of March was derived from Mars
• Named after the God of War because its color resembles blood.
• The Martian year equals to 687 Earth days. Same as Earth, Mars also revolves around the sun in an elliptical orbit. But the orbit of Mars is a little bit stretched out that’s why it takes that long for Mars to completely revolve around the sun.
• The Martian day is 24 hrs 39 min and 35 secs.
• Temperatures in Mars could be as low as -125 degrees celcius near the poles and -20 degrees celcius near the equator at midday. I wonder if the word hot, heat, or warm will ever be invented if we were on Mars?
• You will be weighing 62 percent less when in Mars. The gravitational force of Mars is less than the Earth’s because it’s smaller. I calculated my weight and it looks like I’ll be weighing 61 pounds in Mars instead of 160 pounds. Ladies, if you want to drastically lose weight, go to Mars.
• Mars has the largest volcano in the solar system named “Olympus Mons” (Latin for Mount Olympus) which is 27 kilometers high and 600 kilometers wide. It’s 8.85 kilometer higher than Mt. Everest.
• Mars has 2 moons named phobos and deimos
• Mars also have seasons just like Earth does and the sun appears to be half its size when viewed from Mars.
• Air is mostly composed of carbon dioxide.
• Mars’s large channels, valleys and gullies suggest that there is water in the planet.

The Surface

The surface Mars contains canyons, gullies, plains, volcanoes, polar ice and is composed mainly of a rock called basalt – a volcanic rock usually gray to black in color and is fine-grained due to the rapid cooling of lava.

Then, why does Mars look red if it is composed of a gray or black rock?

It is because of the fine particles of iron oxide that composes the Martian dust. Basalt rocks in Mars have higher concentration of iron than those here on Earth and the grinding of those rocks produces that reddish iron dust that covers Mars.

Looking at Mars from above (as shown on the picture above), you’ll notice that the land mass colored red and yellow seems to be elevated than the rest of the crust. That elevated region, which covers the lower half of Mars is called the Highlands. The rest of the surface is called, Lowlands.

The Highlands is in the southern hemisphere of Mars and contains many craters which suggests that it is the older portion of Mars.

The lowlands contains fewer craters and it also houses the Tharsis Ridge, a ridge that contains most of the volcanoes of Mars.

CANYONS

The red planet contains a system of canyons located along the equator called Valles Marineries (Latin for valleys of mariner), which was discovered by the space probe Mariner 9 in 1971. The canyon stretches 4000 kilometers and is upto 8 kilometers deep.

The Canyons have steep slopes and the bottom is filled with boulders and debris.

The Canyon actually looks like the Grand Canyon in Arizona.

PLAINS

Flat, low-lying plains on the northern region of Mars is among the smoothest in the solar system. The plains seems to be formed through deposits of sediments, which suggests that water was once abundant in Mars.

List of Plains in Mars (Planitia is Latin for plains)

Acidalia Planitia, Amazonis Planitia, Arcadia Planitia, Argyre Planitia, Chryse Planitia, Elysium Planitia, Hellas Planitia, Isidis Planitia, Utopia Planitia.

VOLCANOES

The many volcanoes of Mars can be found on the Tharsis Ridge, including the Olympus Mons which is the biggest volcano in the solar system. Three other large volcanoes can also be found on the ridge, namely: Arsia Mons, Ascraeus Mons, and Pavonis Mons.

Olympus Mons (Latin for Mount Olympus) – Stands 27 kilometers high, about 3 times as high as the Mt.Everest, and is about 600 kilometers wide.

Olympus Mons is shield volcano, meaning it grew bigger and bigger due to the lava flows during eruptions.

Arsia Mons – Stands 9 kilometers high and 435 kilometers in diameter. It the southernmost of all the volcanoes on the Tharsis Ridge.

The Arsian Mons produces dust clouds that can be observed in orbit every time the southern winter begins. This happens because the as the sun warms the air on the slopes of the volcano, it rises, bringing along clouds of dust that can reach 15 – 30 kilometers above the volcano.

Ascraeus Mons – Stands 18 kilometers high, the second highest volcano, and is 460 kilometers in diameter and is the northernmost of all the volcanoes on the Tharsis Ridge.

Pavonis Mons (Latin for Peacock Mountain) – Stands 14 kilometers high. A chain of oval shaped pits lined up on the center of a shallow trough can be found on the lower east flank of the volcano.

CRATERS AND IMPACT BASINS

Due to Mars’s thin atmosphere, meteors can easily enter and reach the surface of the planet. Creating large bowl shaped craters and impact basins, some of them have central peaks that was formed when the floor rebounded upwards after an impact.

The southern hemisphere have lots of craters, making it the older portion of Mars. Volcanoes have craters around them too. The number of craters around a volcano will tell you if they were recently active or not as the flowing lava will tend to cover up the surrounding craters. The more craters you see around a volcano will tell you that it has not been active for a long time.

The largest crater can be found in the southern hemisphere. It’s called Hellas Planitia or Hellas Impact Basin. It has a diameter of about 2,300 kilometers and about 9 kilometers deep.

POLAR CAPS

Just like the Earth, Mars’ polar caps are covered with water ice all year round and during the winter, water ice could extend from the poles to half way to the equator.

The polar deposits are composed of stacks of thin layers of water ice that developed overtime. Scientists believe that the layers consists of water ice and dust. An evidence of seasonal changes in Mars and long term climate changes.

CRUST

It is estimated that the crust of Mars is about 50 kilometers thick. The southern hemisphere could be thicker than the north since it is elevated. The crust is primarily composed of Basalt rocks and covered with iron dust.

MANTLE

The Martian mantle is probably the same as the Earth’s which is mainly composed of a rock called peridotite. Peridotite is an igneous rock which is composed mainly of the mineral called olivine. It also contains silica, magnesium, oxygen and Iron.

Main source of heat inside Mars:

• Radioactive Decay
• Break up of nuclei of atoms of different elements such as potassium, uranium and thorium.

Temperature on the mantle of Mars is estimated to be around 1500 degrees celcius.

CORE

The core of Mars is probably solid, unlike the Earth’s molten (Liquid) core, because of the planets low magnetic field.

A Magnetic field is an influence created by a magnetic object, like for example, if your house is magnetic then the surroundings of your house will have a magnetic field.

The movement within a planets liquid core makes the core magnetic. The movement is brought about the rotation of the planet. Now since Mars does not have a significant magnetic field, it suggests that the core is not moving despite the spinning of the planet. Hence, the core could be solid.

Movements within the core will make the core magnetic. But since, the magnetic field in Mars is low, It suggests that there is not too much movement in the core. It is possible that Mars had a strong magnetic field before since the data gathered from the Mars Gloabal surveyor shows that some of the older rocks were formed in the presence of strong magnetic fields.

ATMOSPHERE

Mars’ atmosphere is 95.3% carbon dioxide (CO2), other gases include Nitrogen (N2) 2.7%, Argon (Ar), 1.6%, Carbon Monoxide (CO), 0.07%, and water vapor (H2O) 0.03%.

One problem that will be facing us if we want to visit Mars. Since we live by breathing oxygen which is obviously scarce in Mars

TEMPERATURE

It is sooo cold in Mars. Temperatures at higher altitudes, around 125 kilometers above the surface, could go as low as -130 degrees celcius (remember 0 degrees celcius is the freezing point of water, so I think we’ll literally freeze in there).

During daytime temperature could go from -30 to -40 degees celcius.

It will be warmer during those times where dust particles cover Mars, as dust absorbs heat from the sun and transfers it to the atmosphere.

WIND and DUST

Wind occurs the same in Mars as it is here on Earth. When the sun is up and it warms up the atmosphere, the warm air will rise up and the colder air will take its place along the surface.

Wind in Mars are generally gentle with the exception of occasional sand storms that can cover the entire surface of Mars. Just like the ones that occurred in 1971 and in 2001.

Dust storms are common when Mars is closest to the sun.

SATELLITES/MOONS

Mars has two tiny satellites. Phobos and Deimos, named after the sons of Ares. Phobos is about 27 kilometers in diameter while Deimos is about 15 kilometers.

They were discovered by an American astronomer named Asaph Hall in 1877. The two satellites also have craters due to meteoroids.

Scientists do not know where the moons came from. They possibly formed at the same time when Mars formed. Another theory is that they were asteroids that got pulled into orbit by gravitational force of Mars. After all, both are dark gray which is similar to the color of some asteroids.

As of now, Mars rovers have been sending pictures and feeding us invaluable information to further our study of the planet. Studies show that there may have been life in the planet and it certainly contains the 3 ingredients necessary to support life: Water, Source of energy and Chemical Elements like oxygen, carbon and hydrogen.

Who knows? Maybe someday you can put Mars in your itinerary.