Category: Missions

The Phoenix lander team revealed the latest images from the mission at a press briefing on Friday. This first image shows an area dug by Phoenix’s scoop, which disclosed a bright surface just a few inches down, which may be ice. “There’s still some debate about the bright material,” said Phoenix Principle Investigator Peter Smith. “Not everyone is sure that this is ice. So there’s been some debate on our team, centering around that perhaps there’s a salt layer just under the soil that also would be bright. Everyone does believe there’s ice under the surface, and whether this is ice or not is the question. The other question is, is this thick ice that goes down deep beneath the surface, or is this a thin layer and we’ll be able to scrape through? So being able to scrape with our scoop is a high priority for us.”


This pair of images taken by the Optical Microscope on NASA’s Phoenix Mars Lander offers a side-by-side comparison of an airfall dust sample collected on a substrate exposed during landing (left) and a soil sample scooped up from the surface of the ground beside the lander. In both cases the sample is collected on a silicone substrate, which provides a sticky surface holding sample particles for observation by the microscope.

Similar fine particles at the resolution limit of the microscope are seen in both samples, indicating that the soil has formed from settling of dust.

The microscope took the image on the left during Phoenix’s Sol 9 (June 3, 2008), or the ninth Martian day after landing. It took the image on the right during Sol 17 (June 11, 2008).

The scale bar is 1 millimeter (0.04 inch).

This is the latest color image of Phoenix, its surroundings and the scoop with soil.

While we can’t look inside the Thermal and Evolved Gas Analyzer (TEGA) oven which will “bake” the Martian soil to test the type of gases that are released, we can see that some of the soil has gone into TEGA. “We were finally successful and some of the material has slid down over the screen” said Smith, “sort of like material going over a cheese grater, and some of the material has slid down and filled the oven. We sent the commands for the first operation of TEGA last night, but we don’t have our data back yet, so we can’t report on any results. That will be coming later next week. So this is a very exciting time for us. We find the soil is very clumpy, it’s sticky, it’s an unusual soil not at all like the types of soils we used in our tests, which worked just fine with all the instruments. So we’ve developed another method of collecting samples, which is to tilt the scoop and vibrate it, and so it shakes down a small amount of material onto the instruments.”

And finally, here’s the latest weather report for Mars, on the 17th sol of Phoenix’s stay on Mars.

Sources: Phoenix News, NASA TV

When Bill Boynton announced at a Phoenix lander team meeting earlier today that the troublesome, clumpy Martian soil now sits, finally, within the TEGA “oven” on Phoenix, the room erupted with cheers and a standing ovation. Boynton then launched a rendition of “Shake, Shake, Shake” he had cued-up on his laptop, and started dancing. If that mental image doesn’t make it clear, getting the soil into TEGA is big, and the entire Phoenix team is excited about the accomplishment. Boynton, who leads the investigations with the Thermal and Evolved Gas Analyzer instrument, and his team have been trying various methods for several days to get the stubborn soil through a screen and into TEGA. The instrument will heat the soil and analyze the gases released to check for water vapor and other chemicals in the soil.

Commands to vibrate the screen were sent to Phoenix for three separate days. Boynton said that the oven might have filled because of the cumulative effects of all the vibrating, or because of changes in the soil’s cohesiveness as it sat for days on the top of the screen.

“There’s something very unusual about this soil, from a place on Mars we’ve never been before,” said Phoenix Principal Investigator Peter Smith. “We’re interested in learning what sort of chemical and mineral activity has caused the particles to clump and stick together.”

Between the shaking and the other new technique developed with the robotic arm called “sprinkling,” Smith hopes they won’t encounter future problems with getting the soil where they want it to go. “Delivering the soil is something we’re getting better at everyday,” he added.

Tomorrow, Thursday June 12, commands will be sent for the TEGA to heat the soil. Initial results may be available on Friday.

“We’ll do a low temperature bake that will tell us how much ice is in the soil,” said Boynton. ” We really don’t expect there to be much ice in the soil since it has been sitting out in the sun and vibrated through the screen. It does look like the soil has changed.”

TEGA has eight ovens to “bake” soil samples. Once an oven is used, it can’t be emptied and used again, so Phoenix has just eight chances to analyze the soil.

While there’s been some debate about the characteristics of Martian arctic soil, Smith said most researchers on the Phoenix team believe it’s a matter of when and not if Phoenix will definitely prove there is water ice region the lander sits on. “There are very few people who don’t believe there’s ice under the soil,” he said. “There also could be a crusty layer of salt on top because of evaporation.”

“We all have a lot of confidence we’ll get down to the ice,” Boynton added. “We may have exposed some in the act of landing. The MECA instrument will help the debate on salt. In a week or two we hope to get enough data to address these speculations.”

MECA is the Microscopy, Electrochemistry, and Conductivity Analyzer, which contains four single wet chemistry labs that will dissolve small amounts of soil in water, to determine the pH and what minerals are in the soil. Those tests will be done later in the mission.

Plans for today’s activities for Phoenix include sprinkling Martian soil on the delivery port for the spacecraft’s Optical Microscope and taking additional photos for a high-resolution color panorama of the lander’s surroundings.

Original News Sources: Phoenix press conference, Phoenix press release

Phoenix “vibrates” to move soil through a screen.

New motto for the Phoenix spacecraft: If at first you don’t succeed, then dust yourself off and try again. Since the Martian soil is proving to be a challenge for the Mars lander, engineers will try a new technique to try delivering the frozen arctic soil into the TEGA, or the Thermal and Evolved-Gas Anaylzer, designed to bake and sniff samples to identify key ingredients in the soil. The soil is clumping together, and won’t pass through a screen that brings it to the ovens on board the spacecraft. Engineers operating the Robotic Arm on Phoenix Lander are testing a revised method they are calling the sprinkle technique.

“We’re a little surprised at how much this material is clumping together when we dig into it,” said Doug Ming a Phoenix science team member from NASA’s Johnson Space Center, Houston.

Engineers commanded the spacecraft to vibrate the screen for 20 minutes on Sunday but detected only a few particles getting through the screen, not enough to fill the tiny oven below.

“We are going to try vibrating it one more time, and if that doesn’t work, it is likely we will use our new, revised delivery method on another thermal analyzer cell,” said William Boynton of the University of Arizona, lead scientist for the instrument.

The arm delivered the first sample to TEGA on Friday by turning the scoop over to release its contents. The revised delivery method, which Phoenix is testing for the first time today, will hold the scoop at an angle above the delivery target and sprinkle out a small amount of the sample by vibrating the scoop. The vibration comes from running a motorized rasp on the bottom of the scoop.

Phoenix used the arm Sunday to collect a soil sample for the spacecraft’s Optical Microscope, so look for images of that procedure soon. Today’s plans include a practice of the sprinkle technique, using a small amount of soil from the sample collected Sunday. If that goes well, the Phoenix team assembled at the University of Arizona plans to sprinkle material from the same scoopful onto the microscope later this week.

The Phoenix team also discussed this picture, showing a spring on the ground near a footpad of the spacecraft. It came from Phoenix itself, when the biobarrier was opened to free the robotic arm back on May 30, the sixth Martian day of the mission.

Phoenix News

“To see a world in a grain of sand…” – English Poet William Blake

The Phoenix science team tested out the lander’s Optical Microscope by imaging grains of sand and dust particles, some as small as one-tenth the diameter of a human hair. These are the highest resolution image ever of small soil particles from another planet. “We have images showing the diversity of mineralogy on Mars at a scale that is unprecedented in planetary exploration,” said Michael Hecht of NASA’s Jet Propulsion Laboratory.

The microscope observed particles that had fallen onto an exposed surface of the lander. “It’s a first quick look,” Hecht said. “This experiment was partly an insurance policy for something to observe with the microscope before getting a soil sample delivered by the arm, and partly a characterization of the Optical Microscope. All the tools are working well.”

However, some of the particles may be “alien” – that is, they might have come from inside the spacecraft when Phoenix dropped to Mars surface at landing. But at first glance, many of these grains match expectations for Martian particles. “We will be using future observations of soil samples delivered by the Robotic Arm to confirm whether the types of particles in this dustfall sample are also seen in samples we can be certain are Martian in origin,” Hecht said.

The particles show a range of shapes and colors.

“You can see the amount of variety there is in what appears otherwise to be just reddish brown soil,” said Tom Pike, Phoenix science team member from Imperial College London. He noted that one translucent particle resembles a grain of salt, but that it is too early to say for sure.

Meanwhile, Phoenix received commands Thursday to collect its first soil sample to be delivered to its science lab instrument on the lander deck. Those commands were originally sent on Wednesday, but the lander didn’t receive them as the relay for the commands, the Mars Odyssey, had gone into safe mode. The orbiter may have been hit by a cosmic ray, and engineers from JPL say nominal operations of the spacecraft should return by the end of the week. This type of event has occurred a couple of times in the Odyssey mission, and engineers don’t appear overly concerned about the situation.

So, the commands were successfully re-sent via the Mars Reconnaissance Orbiter. Look for the first science results from Phoenix within the next day or so.

Original News Source: Phoenix news release

NASA’s Mars Odyssey has been switched into “safe-mode” after possibly being hit by energetic particles from the Sun, or by cosmic rays. Acting as one of two relay satellites between Earth and Phoenix, this has hindered commands to be sent to the lander, thereby slowing its progress. Phoenix is just about to start scence digging operations on the surface (Martian regolith is shown in the Phoenix test-run scoop of material, pictured). It seems likely that Odyssey will remain in the protective safe-mode until the weekend whilst operators try to understand what caused the problem. For the time being, the second relay satellite NASA’s Mars Reconnaissance Orbiter (MRO) will try to take up the slack and keep the lander in contact with mission control…

This is the second communications error in the otherwise flawless Phoenix Mars mission. The first occurred two days after touch down when the MRO switched its UHF radio into standby mode. Yesterday’s (Wednesday’s) error with another Mars-orbiting satellite, Odyssey, probably won’t be repaired until Saturday. Mission engineers believe the error may have occurred when energetic space particles interrupted Odyssey’s onboard memory. As a safety precaution, the onboard hardware was switched into a low-energy state to protect it from any damage. This event doesn’t seem to be serious, but it does slow down the progress of Phoenix which is currently excavating Mars material from the surface of the red planet, trying to understand the composition of permafrost layers.

Although frustrating, this setback will not cause too many problems to Phoenix, daily commands can still be sent to the MRO and relayed to Phoenix and the first delayed science excavation run is scheduled for today. Test runs over the past few days have revealed a white substance in the fist-sized samples of regolith, so scientists are very excited to “bake” the permafrost material to see if water ice or salt deposits are present. After the preliminary tests, mission scientists believe that Phoenix’s 8-foot robotic arm is up to the task and appears to be functioning excellently.

The following steps will be carried out in the first science run scheduled to start today:

1. Right of the test-dig area, scientists have identified three “science rich” zones. Phoenix will dig into areas known playfully as “Baby Bear”, “Mama Bear” and “Papa Bear”, after the “Goldilocks” fairy tale. Presumably they are looking for a dig that will be “just right”.
2. The first dig will cut 3/10 of an inch into the permafrost at the location of “Baby Bear”, and scoop up the material.
3. With the material safely in the scoop, Phoenix will swing its arm 90 degrees towards the onboard miniature oven. It will then wait for further commands.
4. Assuming the MRO delivers the commands from mission control, Phoenix will be instructed to drop the sample into the oven so it can be baked. Instruments will be used to look deep into the vapour given off to look for signs of carbon or hydrogen-containing organic compounds. It is at this point that the lander will evaluate the samples to see whether there is in fact current water ice on the surface.

Over the next few days samples from all the Goldilocks sites will be analysed. These are exciting times, let’s hope there are no further communications problems…

Source: Associated Press (printed at Physorg.com)

Phoenix’s first dig in the Martian soil. Image credit: NASA/JPL-Caltech/ University of Arizona

The Phoenix lander used its robotic arm scoop to dig up soil on Mars surface for the first time during its activities during its seventh day on the Red Planet. The image above shows the hole dug by Phoenix, and below is a picture of the scoop itself, with the Martian soil inside.

The plan was to do a test dig and then dump the soil. If that works correctly, then Phoenix will dig another scoop and bring it to the TEGA device on board the lander, the Thermal and Evolved Gas Analyzer, a “furnace” and mass spectrometer instrument that scientists will use to analyze Martian ice and soil samples.

During its previous day’s activities on Sol 6, Phoenix reached out and touched Mars with its robotic arm scoop to make an impression on the Martian surface. And please, no conspiracy theories here, but the impression looks like a footprint, and the Phoenix scientists have dubbed the mark “Yeti.” Touching the surface was a preliminary test for the robotic arm and scoop, to make sure everything was working correctly before making the first scoop.

However, the TEGA device has experienced an intermittent short circuit, and the TEGA scientists are developing a procedure to work around the problem. But Phoenix can still deliver the soil sample to TEGA, and the sample can be held there until the device is working.

Original News Source: Phoenix