Categories
Red Planet Pen

Cameras and Spectrometers Reveal Martian Water Over Decades

The story of how technology has changed how we see Mars.

By: Nicole Willett

The ability to see is one of the most important aspects in astronomical discovery.  Scientists have invented many ways to see things, including cameras and spectrometers. Cameras have developed over the past few decades from simple analog black and white photography to ultra high definition colored photography.  Spectrometers can also see things, but in a very different way than cameras. Spectrometers have also developed rapidly over the decades. Where cameras can see things visibly, spectrometers can determine the make-up of any object.  Spectrometers can determine something as simple as biotic versus abiotic material, to the isotopic ratios of the mineral content of a rock on Mars. The use of spectrometers on spacecraft have added significantly to our knowledge of stars, planets, and natural satellites.  Mars is the planet most visited by spacecraft that happen to include cameras and spectrometers. It is no surprise that the things we can see on Mars have come clearer, due to technological advancement, over the 50+ years we have been visiting the Red Planet.  For centuries humans have speculated about Mars and its habitability, with habitability comes water. The fleet of spacecraft that have visited Mars had a particular interest in finding out if water has ever or does now exist. 

Mariner

In the 1960’s NASA sent two flyby’s past the planet Mars.  Both of these spacecraft had what would now be considered primitive technology. In 1965, NASA’s Mariner 4 spacecraft flew by Mars and sent images back to Earth. The images were taken with what is described as a television camera mounted on the spacecraft along with a Cassegrain telescope and a vidicon tube that to translate the images. Scientists received the signal and had 22 small, black and white, crude images of the rocky and barren surface of Mars.(NASATech) The technology of the time was limited and, though the mission was a success, the information gleaned was hampered by this. In 1969 the Mariner 6 and 7 flew by Mars taking hundreds of pictures and other data and sending them back to Earth.  These were nearly identical spacecraft with a television camera and an IR and UV spectrometer. The cameras imaged approximately 20% of the surface of the planet but did not image the 4 large volcanoes or Valles Marineris. The spacecraft confirmed the canali, previously predicted by Giovanni Schiaparelli in the late 19th Century, on Mars were merely an optical illusion and misinterpretation of data from Earth based telescopes.  (NASATech)

Image 1: Image taken from the Mariner 4 television camera. (NSSDC)

Viking

The Viking I and II missions by NASA were composed of two landers and two orbiters.  The orbiters imaged the entire planet with two vidicon cameras and took scientific data readings with an infrared spectrometer, to seek and track water vapor in the atmosphere.  The landers took images from the surface with two facsimile cameras and a gas chromatograph mass spectrometer. (NASANatl) The Viking Orbiters’ instrument, called the Mars Atmospheric Water Detector, detected upwards of approximately 100 microns of atmospheric H2O. (Geo) Atmospheric water is an important discovery in order to establish a baseline for a planetary water cycle. The Viking landers carried gas chromatograph mass spectrometers (GCMS) to look for signs of organic material in the Martian regolith. The GCMS analyzes a sample by warming it up and sensing the gases that come off the sample and then a detector determines the spectrum of the sample.  This is how we can see the elemental and isotopic make-up of objects. 

Rampart craters were photographed by the Viking orbiters vidicon cameras, developed in the 1950s.  The cameras were high technology at the time, but compared to our ultra high definition cameras now, the technology is obsolete. (dePater & Lissauer) 

Image 2: Mars from the Viking orbiter spacecraft, mosaic of 102 images. (NASAMars)

 

Mars Reconnaissance Orbiter

The Mars Reconnaissance Orbiter (MRO) entered the orbit of Mars in March 2006.  The MRO also carried the High Resolution Imaging Experiment (HiRISE) camera, made by University of Arizona (UofA), which operates in visible to near infrared and has a resolution of about a meter. As of 2006, HiRISE had the best resolution of any camera sent to space. The HiRISE camera has imaged many Recurring Slope Lineae (RSL) on Mars.  RSLs are briny water flows that were discovered on the slopes of craters during warm weather on Mars. (NASAjpl)

Image 3:  Recurring Slope Lineae photographed by the HiRISE camera on MRO.  (NASAMRO)

 

 

 

Spirit and Opportunity

The Mars Exploration Rovers (MER) Spirit and Opportunity landed on Mars a few weeks apart in January 2004. The Opportunity Rover landed near and explored Eagle Crater. Opportunity had a suite of cameras, including a panoramic camera (Pancam), a navigation camera (Navcam) and hazard cameras (Hazcam). The Pancam, made by ASU, has a resolution of 1mm per pixel and functions in the range of near IR to near UV. As images from the Pancam were processed and viewed by the geologists on the team, it was discovered that a vast field of small round nodules had been discovered.  (NASAMER)

The team next used the Miniature Thermal Emission Spectrometer (Mini-TES), made by ASU and Raytheon Santa Barbara Remote Sensing (SBRS), to determine the make-up of the nodules.  The Mini-TES is an IR spectrometer that is best utilized for looking at the mineral content of rocks.  It can peer through the dusty coating on the rocks and make a determination of the content. The spectroscopic analysis revealed the concretions to be hematite and jarosite.(Science)

Spirit landed three weeks later in a dry lake bed and found evidence of past water in a rock named Humphrey.  The MER team instructed the rover to examine Humphrey with the Rock Abrasion Tool (RAT) and then utilized the Mini-TES to determine that the crystalline structures inside Humphrey had been in contact with water.  (NASAPress)

At Gusev Crater, Spirit examined a grouping of rocks, including a rock named Clovis.  The team investigated Clovis utilizing the Mossbauer spectrometer, made by Johannes Gutenberg University, which examines objects using the absorption and emission of gamma rays.  This revealed the presence of eight iron bearing minerals including goethite, which only forms in the presence of water. (AGU)

Phoenix 

The Phoenix Lander landed near the north polar region on Mars in May 2008. (Phoenix) Notable images, taken by the Surface Stereo Imager (SSI), built by the UofA, included a vast panorama of polygon shaped regolith which were indicative of ices beneath the regolith. The SSI was a stereo camera with a higher resolution than that of Pathfinder. The Robotic Arm Camera, made by the Max Planck Institute and U of A, was designed to take close up and microscopic, to a scale of 23 μm/pixel, images in color.  The SSI took an image of a block of a frozen white substance that was later identified as water ice.  This was the first surface observation of water ice on Mars. (Chaisson & McMillan) The thrusters had blown away the regolith and revealed the ice.  Its photos taken over a period of approximately 30 days, revealed globules on the landing struts of Phoenix. The globules grew and receded then eventually completely disappeared.  They were found to be liquid water mixed with perchlorates by the Thermal and Evolved Gas Spectrometer (TEGA), made by UofA and University of Texas, Dallas. TEGA was a high temperature mass spectrometer.  It heated samples to a temperature in order to collect the gas coming off the samples to analyze. (AGUPhoenix)

Image 4: Ice sublimation on Mars, taken by he Phoenix Lander. (NASAPhoenix)

Mars Science Laboratory Curiosity (MSL)

The Curiosity Rover landed on Mars in August 2012.  A few days later it was announced by John Grotzinger, Project Scientist for MSL, that Curiosity had landed in an ancient riverbed that flowed vigorously with fresh water up to waist deep.  Grotzinger explained the water was so pure, based on chemical analysis of the surrounding area, that a person could have scooped up the water and drank straight from the river. (NASAcuriosity)  This discovery was made initially by the Mastcam of the area that showed what appear to be concretions of rocks that would have been arranged in the position by the flow of water over a long period of time.  Another clue to the ancient riverbed was the rounded pebbles, imaged by the Mastcam, jutting out of the edge of the compacted rocks and pebbles. The rounded pebbles show that the water had to have persisted for a period of time long enough for rocks to tumble over each other and reshape them from their former jagged appearance. (NASANews) The Mastcam, built by Malin Space Science Systems, is a panoramic camera mounted on the mast with a resolution of 7.4 cm per pixel at a distance of 1 km. The eyes have individual resolutions of 150 to 450 μm to a distance of 1 km.  One of the cameras has a lens that can see the landscape, in color or monochromatic, at a much farther distance than those of the MER camera systems. Mastcam has video capability with a high resolution at 10 frames per second and has an eight gigabyte memory which can store thousands of images for a period of time long enough for the rover to uplink the data to the orbiter, which then send the information to Earth.  (NASAcuriosity) The Sample Analysis at Mars (SAM), a GCMS made at NASA’s Goddard Space Flight Center, was designed to identify specific organic compounds by separating the gases and sending them through a series of spectrometer parts which detect elements like carbon, hydrogen, nitrogen, oxygen, phosphorous, and sulfur, the key elements for life, then to the next spectrometer to determine if water vapor is present. SAM has 74 small sample cups, including several for calibration.  The sample sensitivity is less than one part per billion for organic compounds. The oven on SAM has the ability to heat the samples to 1000* C for analysis. (NASACuriosity) Later, SAM sampled the surface regolith and determined water made up about 2% of the sample. (NASANews)

Image 5: Jutting rock conglomeration in Gale Crate on Mars imaged by MSL’s Mastcam. (EarthSky)

 

 

Astronomy is the oldest science and started by visually observing objects, thousands of years ago, which is still incredibly important today.  As technology has improved, images sent to Earth by various spacecraft had better resolution and scientific instruments have been able to gather more detailed information. Rovers, orbiters and landers have benefitted from the technological advancements in miniaturization of instruments, allowing more scientific equipment to be carried on each craft.  The implementation of cameras on telescopes and spacecraft have added to our knowledge of astronomy in so many ways that it cannot be calculated. Spectrometers see inside of things, not like an X-ray, but at an elemental level. The technology of cameras and spectrometers has changed astronomy by verifying the presence of water on Mars after over a century of speculation.

 

References:

AGU: American Geophysical Union. https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2005JE002584. (Accessed 19 oct 2019)

AGUPhoenix: American Geophysical Union.   https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2007JE003044  (Accessed 19 oct 2019)

Chaisson & McMillan: Astronomy Today Text 7th edition. P.256. 

dePater & Lissauer: 2016. Planetary Sciences. P.208. 

Geo: Journal of Geophysical Research.  https://agupubs.onlinelibrary.wiley.com/doi/pdf/10.1029/JS082i028p04225.  (Accessed 18 Oct 2019)

Geo2:  Journal of Geophysical Research.   https://ui.adsabs.harvard.edu/abs/1997JGR...102.4027R/abstract  (Accessed 19 Oct 2019)

NASA:  NASA Mission Pages. https://www.nasa.gov/mission_pages/mars/images/pia09028.html#.WsP_M4jwZPZ. (Accessed 19 Oct 2019)

NASAcuriosity. NASA Curiosity Page. https://mars.nasa.gov/msl/spacecraft/instruments/mastcam/ (Accessed 20 Oct 2019)

NASAGeo: NASA Geology and Geomorphology. https://mars.nasa.gov/MPF/science/geology.html.  (Accessed 19 Oct 2019)

NASAjpl. NASA Jet Propulsion Laboratory News. https://www.jpl.nasa.gov/news/news.php?feature=4722. (Accessed 19 Oct 2019)


NASAMER: NASA’s Mars Exploration Rover page. https://mars.nasa.gov/mer/mission/spacecraft/ (Accessed 19 Oct 2019)


NASANatl. NASA’s National Space Science Data Center. https://nssdc.gsfc.nasa.gov/planetary/viking.html. (Accessed 18 Oct 2019)

NASANews. NASA News. https://www.jpl.nasa.gov/news/news.php?feature=4722. (Accessed 18 Oct 2019)

NASAPhoenix: NASA JPL. https://www.nasa.gov/mission_pages/phoenix/images/press/sol_020_024_change_dodo_v3.html (Accessed 1-1-2020)

NASApress: NASA Press Release. https://mars.jpl.nasa.gov/mer/newsroom/pressreleases/20040305a.html. (Accessed 19 Oct 2019)

NASAPS: NASA Mars JPL. https://mars.jpl.nasa.gov/MPF/mpf-pressrel.html. (Accessed 19 Oct 2019)

NASATech: NASA Technical Reports Server. https://ntrs.nasa.gov/search.jsp?R=19700009038#. (Accessed 18 Oct 2019)

Nature: The Journal Nature. https://www.nature.com/articles/ngeo2412. (Accessed 18 Oct 2019)

Phoenix: NASA Phoenix Lander Page. https://www.nasa.gov/mission_pages/phoenix/overview. (Accessed 19 Oct 2019)

PRSD. Planetary Science Research. http://www.psrd.hawaii.edu/Nov03/olivine.html (Accessed 19 Oct 2019)

Science: The Journal Science. http://science.sciencemag.org/content/sci/306/5702/1740.full.pdf. (Accessed 19 Oct 2019)

 

Categories
Red Planet Pen

Liquid Water on Mars (Issue #39)

By: Nicole Willett

Edited by: Margaret Lattke

Introduction

Scientists have carefully studied and tracked the history of water on the Red Planet.  It is now widely accepted due to the geomorphological evidence that Mars had an ocean of liquid water billions of years ago.  This ocean covered the northern hemisphere. This is indicated by the lower altitude of the surface, smoother and geologically newer surface of the northern hemisphere, as opposed to the higher altitude and the more jagged appearance of the highlands of the southern hemisphere.  An ocean covering most of the northern hemisphere has consequences such as a thicker atmosphere and warmer temperatures. It is clear by photographic evidence that volcanic activity was very active in Martian history. In close proximity to ancient volcanoes are areas of catastrophic flooding, caused when volcanic heat rapidly melted the subsurface ice.  This evidence can still be seen today. (Nature6) Mars has a significant CO2 atmosphere, which would have been important to sustaining a warmer and wetter planet in the past.  This thicker atmosphere could have been in place for 10 million to a billion years. Volcanism and cycling of carbonate rocks would have helped to keep the atmosphere intact for this lengthy geologic time.  (Icarus)

Current science indicates Mars was once a warm and wet planet and currently has liquid water on the surface for short periods of time.  Data consistent with liquid water has been observed. It is proposed water appears seasonally as minerals are mixed with water that erupts through the surface and runs down the sides of craters, keeping it liquid at temperatures below freezing.  There is ample evidence, morphologically and spectroscopically, from the fleet of spacecraft that have been and are now presently working on and around Mars.

History

Water on Mars makes headlines often and has been debated for over a century.   Astronomer Giovanni Schiaparelli’s observations in approximately 1877 started the frenzy over water on Mars.  When Schiaparelli observed what he thought were channels on Mars, he called them canali which means channels. (See Figure 1)  When his findings were published, the term was misinterpreted as canals which led many people to believe intelligent life existed on Mars.  Channels and canals are distinctly different. A channel is a naturally occurring groove in the ground where water or some other fluid has eroded the soil away to make a riverbed.  A canal is made by sentient beings, for water to flow through. (Chaisson & McMillan) Schiaparelli declared his disbelief for water on Mars in a letter to Professor Holden in April 1893, in which he rejected the idea of water on Mars.  This was based on his study of the planet and the colors he observed. He states that when you view water on Earth from a higher point, it appears black which he did not observe. (Pacific)(Willett)

 

Figure 1: Giovanni Schiaparelli’s hand drawn map of Mars based on observations and assembled between 1877 to 1886. (NASAH)

For nearly two decades in the late 19th and early 20th Century, Percival Lowell utilized a telescope he built specifically to observe Mars.  He was intrigued with the findings of Schiaparelli. The Lowell Observatory was built in Flagstaff, Arizona, USA and still stands.  Lowell’s sketches show many features that were considered to be evidence of intelligent beings on Mars. He authored three books on the subject, which included references to canals and oases.  Many people disagreed with Lowell’s observations and he was ostracized by some. (Chaisson & McMillan)(Willett)

Studies searching for water on Mars continued.  From February to April 1937 observations at the Mount Wilson Observatory using a plane grating spectrograph on the telescope detected water vapor in the Martian atmosphere.  The spectrograph indicated that a wavelength of 7200. The peaks on the spectrogram were consistent with H2O.  The data was determined not to be of Earthly origin. (Pacific2)

The Modern Era Seeks Water on Mars

As technology advanced, we discovered that some of these geological features were present, but not in the exact state recorded by Lowell.  The Mariner 4 and 9 were launched in the 1960’s and early 1970’s. These spacecrafts proved that the drawings Lowell made were not accurate. (Chaisson & McMillan) Each spacecraft that visited the Red Planet added to the data set being compiled regarding water on Mars.  During the latter half of the 20th Century, the fleet of spacecraft orbiting, landing, and roving Mars increased.  Geologic periods on Mars have been established as: Pre-Noachian which was a period lasting from 4.5 billion years ago (bya) to 4.1 bya,, Noachian from 4.1 bya to 3.7 bya, Hesperian from 3.7 to 3.0 bya, and Amazonian which started 3.0 bya to present day.  As the data came in Martian geologists identified two types of channels carved by water, runoff channels and outflow channels. Runoff channels formed during the Hesperian Period are often found in the southern highlands and can be hundreds of miles long.  They appear nearly identical to interconnecting riverbeds on Earth. Outflow channels are found in the equatorial region and appear to be relics of catastrophic flooding during the late Hesperian. They are not interconnected and are thought to be paths of huge volumes of water. (Chaisson & McMillan)(Willett)

As the 21st Century has brought increased technology and data, the estimates for the period when water existed in liquid form on the surface of Mars has changed dramatically.  In the last decade alone, the estimates have gone from billions of years ago to millions, thousands, hundreds, decades ago and more recently it has been said there may be water on the surface now.  (NASAtv)(Willett)

Geological Conditions and Observations

Mars does not have the appropriate global conditions for liquid water to sit on the surface for extended periods of time.  The triple point on Mars for liquid water is 0oC with a pressure of 0.088 pounds per square inch (psi) at the average surface altitude.  The average temperature is below the freezing point of water and the pressure is 0.087 psi.  Typically, these conditions are inconsistent with sitting liquid water, unless we explore areas of lower altitude or add certain molecules to water.  No vast areas of liquid water sit on the surface and no rivers flow today. As specific conditions are met, it is possible that liquid water can flow and puddle on Mars.  (Chaisson & McMillan)

During the late-Noachian and early-Hesperian periods ice sheets were laid down on Mars.  In 2018, it was reported that vast water ice sheets were discovered that are at least 100 meters thick. The ice sheets appear to have been laid down over different time periods, some may be as recently as 100 million years ago.  The team analyzed eight ice sheets that were semi-exposed for the study. All of the ice sheets were within 55o of the equator.    It is suspected by the unique layering pattern that the ice was laid down by periods of H2O snow.  This would be an essential part of a planet wide water cycle, whereby meltwater would recharge any aquifers beneath the surface and likely still exists on Mars.  Spectroscopy indicates the water ice is pure enough for Martian astronauts to melt and utilize for drinking water and other human necessities. The purity of the water ice causes sublimation into vapor, thus causing further collapse of the ice sheets. (Icarus2)(Science5)  The vapor can then be deliquesced into the salts in the regolith causing dampness on the surface as photographed by the rovers.

Amateur astronomers on Earth can see the polar ice caps on Mars on a clear night from a small telescope.  The ice caps on Mars are made up of CO2 and H2O ice.  They grow and recede throughout the year.  CO2 and H2O are present in the Martian atmosphere as well. CO2 makes up 96% of the atmosphere and H2O only exists in trace amounts.(Science)(NASA) The interest in water on Mars has influenced the scientific community to further study the planet searching for clues to verify or debunk the mystery.  

Mariner Missions

In 1965, NASA’s Mariner 4 spacecraft flew by Mars and sent images back to Earth.  After many arduous hours, scientists received the signal and had 22 small crude images of the rocky and barren surface of Mars.(NASATech) To the scientists it was an incredible feat of engineering, however to the public, it was a disappointing confirmation of the lack of anything very interesting, including water, on Mars. In 1969 the Mariner 6 and 7 flew by Mars taking hundreds of pictures and other data and sending them back to Earth.  The spacecraft confirmed the canali on Mars were merely an optical illusion and misinterpretation of data from Earth based telescopes.  (NASATech)

Viking

The Viking I and II missions by NASA were composed of two landers and two orbiters.  The orbiters imaged the entire planet while taking scientific data readings, including an infrared spectrometer, to seek and track water vapor in the atmosphere.  The landers took images from the surface and sampled the soil and atmosphere on opposite sides of the planet. Viking I landed at 22.27°N 47.95°W and Viking II at 47°38′24″N, 225°42′36″W. They were also tasked with seeking evidence of life, which would need a source of water to survive. (NASANatl) The Viking Orbiters’ instrument, called the Mars Atmospheric Water Detector, detected upwards of approximately 100 microns of atmospheric H2O. (Geo) Atmospheric water is an important discovery in order to establish a baseline for a planetary water cycle.

Rampart craters were photographed by the Viking orbiters.  The craters are surrounded by what appear to be muddy flows.  This is called fluidized ejecta, a type of muddy mixture, and is the result of the friction from an impact of a meteorite and the subsurface ice which interacted.  The melted ice and regolith mixed together during the event and created the fluidized ejecta that is seen surrounding the rampart craters. (dePater & Lissauer)

Scientists examined and reexamined the Viking data trying to piece together some semblance of a story regarding the history of Mars’ water.  Some were adamant that water could not exist on Mars today, but if water ever existed on Mars it had to be billions of years ago. Other scientists were starting to speculate that it may have existed more recently. As the scientific method goes, more data needed to be collected.  

Pathfinder Sojourner Mission

On July 4, 1997 the two-part spacecraft, Pathfinder-Sojourner, landed on Mars at 19°7′48″N 33°13′12″W.  The pair was made up of a lander and the first rover to ever be deployed on another planet.  The Sojourner Rover, a small solar-powered rover, at about a meter in length. Its planned lifespan was 30 sols (Martian days) but lived to transmit valuable information back to Earth for 83 sols.  Part of the scientific mission of the lander-rover complement included finding evidence of past liquid water on Mars. The mission findings included round pebbles near the landing site. Round pebbles occur in running water that has a strong enough flow to tumble jagged rocks over and around each other, dulling the edges and metamorphosing the jagged rocks into small round pebbles. The suggestion is that Mars was warmer with a thicker atmosphere that allowed for liquid water to flow and stand on the surface. (NASAPS)

The visible evidence from Pathfinder in Chryse Planitia indicated an area of ancient catastrophic flooding equaling a volume of hundreds of km3.  The images of the rocks themselves showed some to be rounded and others sharp and stacked.  Geologists state that these features indicate catastrophic flooding as seen by analogues on Earth.  The sharp and stacked rocks appear to have been shoved on top of each other by flood water. Some evidence of rock conglomeration was imaged, but the results were inconclusive to whether this was caused by water.  (NASAGeo) More data needed to be collected.

Mars Global Surveyor

Orbiters have continued to fly to and orbit Mars for decades providing photographic evidence of riverbeds, channels, flooding, ice cap growth and recession. The evidence for water flowing on Mars was not only growing but appeared to be indicative of a more recent existence.

The Mars Global Surveyor (MGS) orbiter reached orbital insertion in September 1997, shortly after the Pathfinder mission arrived it was tasked with many things, some of which were determining the geological processes that occur; imaging the surface seeking evidence of past water erosion; examining the physical properties of ice; monitoring the polar ice caps; and tracking weather patterns and the seasons.  MGS had a suite of scientific instruments which included cameras, a laser altimeter, and a spectrometer. The instruments worked together to give planetary scientists a clearer picture of the history of water on Mars. One such instance occurred when MGS imaged the same crater six years apart. To the surprise of the scientific community, there had been a change in the crater wall.  The crater lies in the Centauri Montes region at 38.7o S 263.3o W.  The image in 1999 showed a non-distinct crater. In 2005 when the crater was imaged again, a sediment trail was identified.  Spectroscopy indicated that the sediment was made up of salts and minerals that could be the result of briny water that flowed down the slope of the crater.  When the water evaporated, a dry sediment of minerals would have been left behind, as indicated by the bright material imaged by MGS. (NASA)

Some scientists stated the sediment could have been caused by water erupting through a weak spot on the crater wall, staying liquid due to the salt and minerals, flowing down the side of the crater, the water evaporating, and leaving remnants of minerals behind. (See Figure #2) Over the duration of the MGS mission, many more gullies were discovered. (NASA)

Figure #2:  Mars Global Surveyor images of an unnamed crater. Images captured six years apart as indicated in the upper left of each image.  The 1999 image showing a non-distinct crater. In the 2005 image a sediment trail has been laid down by a mechanism speculated to be water mixed with salts and minerals in order to maintain the liquid state under the temperature and pressure conditions present on Mars. (NASA)

Another interesting clue to the history of water on Mars was when the Thermal Emission Spectrometer (TES) on board the MGS discovered vast amounts of hematite consistent with forming in water. Hematite is found abundantly on Earth and has been widely researched and found to be formed when the interaction of iron and water occur over long periods of time.  Hematite forms in spherule shapes, concreting over time. (Geo2)

Mars Odyssey

In late 2001, the Mars Odyssey entered the Martian orbit.  This spacecraft mapped and verified the water ice that exists beneath the surface of Mars. (UofA) As the evidence mounts for liquid water existing on Mars today, some scientists insist this is not the case.  It has been suggested that the evidence put forth for water on Mars today is instead moving sand or deliquescence of perchlorate salts. Perchlorates act as a natural antifreeze on Mars. Deliquescence is the act of water vapor from the atmosphere being absorbed by the salts in the regolith and forming sitting liquid water, which in itself is contrary to the proposition that sitting liquid water does not exist on the surface.(Brit)  Hundreds of features have been imaged in crater walls and slopes of canyons named recurring slope lineae (RSL). Part of the astronomical community believes RSLs are swaths of water moving down the slopes and other scientists disagree vehemently. Others believe the moving sand theory which is due to the slope of the crater walls that have been studied. The incline of the slopes has been found to be 27o or more which during testing of similar materials, shows that sand can move down a slope moving the surrounding materials. (Science4) A 2016 study of RSLs by Odyssey’s Thermal Emission Imaging System were shown to be as dry as the Atacama Desert, yet this did not contradict the hydrated salts data collected in 2011. (NASAOdyssey)

Mars Reconnaissance Orbiter

The Mars Reconnaissance Orbiter (MRO) entered the orbit of Mars in March 2006, a few months before NASA lost contact with MGS.  The MRO also carried cameras and spectrometers. The HiRISE camera has imaged many RSLs. (See Figure 3) In 2015 NASA announced MRO had discovered hydrated minerals in the area of the dark streaks on steep slopes.  The RSLs grow and recede with the temperature and seasonal changes and appear more commonly at mid-latitudes where the temperature is warmer.(NASAjpl) The streaks appear more often as Mars’ axial tilt aims the areas toward the Sun and the temperature reaches -23oC.  This is below the freezing point for fresh water on Mars.  (Nature4) However, water that contains perchlorates and other minerals, dubbed hydrated salts or briny water, can exist at the temperature and pressure on Mars. (NASAjpl)(Nature4)

Figure 3: Recurring Slope Lineae in Coprates Chasma imaged by HiRISE on MRO. (NASA/JPL-altech/Univ. of Arizona)

 

Other scientists have proposed water is not the cause at all but instead blocks of CO2 ice moving down the slopes are causing the linear gullies.  The theory proposes that as the seasons change blocks of CO2 ice are loosened by sublimation.  Blocks of carbon dioxide ice then fall down the steep slopes carving gullies that appear to be evidence of flowing water. (ScienceDirect)

Spirit and Opportunity

The Mars Exploration Rovers Spirit and Opportunity (MER) landed on Mars a few weeks apart in January 2004. Each rover contributed greatly in the search for evidence of water.  Steve Squyres, Principle Investigator for MER, stated the mission was a “follow the water” mission. (NASA) Early in the history of Mars a large planetesimal hit the planet and melted the entire surface, this is known as the Borealis Impact.  Any water or life that existed on the Red Planet would have been vaporized. The “follow the water” mission of the MER was tasked with finding out if water existed on the surface of Mars after the Borealis Impact. The Opportunity Rover landed at 1.94°S 354.47°E and explored Eagle Crater at Meridiani Planum shortly after landing on Mars.  As images from the area were processed and viewed by the geologists on the team, it was discovered that a vast field of hematite had been discovered. The hematite was nicknamed “blueberries” due to the bluish hue in the images and the appearance of a spattering of blueberries on the ground. (Universe) The Opportunity Rover used the Rock Abrasion Tool (RAT) to grind and examine a blueberry.  The team next used a spectrometer to determine the mineral content of the nodule. The spectroscopic analysis revealed the concretion to be hematite and jarosite.(See Figure 4) (Science3)

The Utah desert is home to a vast region of fossilized sand dunes that is a perfect analog to Eagle Crater and the surrounding Meridiani Planum on Mars with its own vast area of fossilized sandstone and hematite.  Hematite only forms in the presence of water. Water penetrates the sandstone and pours through the cracks. As the water contacts the rock it brings with it minerals, like iron, that forms concretions around the sand.  The dense iron nodules fall out of the sandstone as wind erosion dissipates the rock around the nodules. Over millennia, more blueberries fall out of the sandstone and pile up on the surface of the planet. For the tens of thousands of hematite nodules found by the Opportunity Rover, vast amounts of water must have existed on the surface of Mars.  The water could only be sustained in liquid form with a much thicker atmosphere. The atmosphere also must have been much denser in order to cause the amount of wind erosion seen that caused the hematite to fall out of the sandstone. (Universe)

Spirit landed in January 2004 at 14.56°S 175.47°E in a dry lake bed.  By March the Spirit Rover found evidence of past water in a rock named Humphrey.  The MER team instructed the rover to examine Humphrey with the RAT which ground 2mm into the surface of the rock.  It was discovered that the crystalline structures inside Humphrey had been in contact with water in order for the crystal to form.  (NASAPress)

Figure 4: Mossbauer spectrometer results for the nodule examined by the Rock Abrasion Tool (RAT) at Meridiani Planum.  Chart A: A composite of all outcrop spectra including Eagle and Fram Craters. Chart B: Spectra obtained after the RAT grinding of a blueberry, indicating the spectrum for hematite and jarosite.  (Science3)

Spirit roved Mars for over 1200 sols when she was nearly crippled by a wheel that was no longer operational, but continued to rove and drag the wheel behind her.  As the wheel drug through the regolith, a white powdery substance was revealed. The substance was examined by the X-ray spectrometer and determined to be 90% pure silica.  Squyres stated that via teleconference, this was a “remarkable discovery”. Silica is often found on Earth in areas where hot springs exist. The silica discovered by Spirit may have formed in a hot spring and later have flowed to an area further from the source.  Another option for the formation of silica in the region is possibly the interaction with acidic vapors from volcanic activity combined with the regolith and water. (NASAmer)

At Gusev Crater in the Columbia Hills, Spirit examined a grouping of rocks, including a rock named Clovis.  The team investigated Clovis utilizing the Mossbauer spectrometer which revealed the presence of eight iron bearing minerals including goethite, which only forms in the presence of water. (See Figure 5)(AGU)

Figure 5:  Mossbauer Spectrum of the rock named Clovis at Columbia Hills.  The spectrum revealed hematite, silicates, and goethite. (AGU)

Phoenix

The Phoenix Lander landed near the north polar region at 68.22oN 125.7oW on Mars in May 2008. The lander used a parachute and reverse thruster, retrorockets landing method. (Phoenix) Notable images from Phoenix included a vast panorama of polygon shaped regolith which were indicative of ices beneath the regolith that had frozen and thawed, thus leaving behind a polygon shape.  The polygons are formed by the freezing and thawing process as the regolith is blown by the wind and into the cracks in the ices. (See Figure 6) The camera on the underneath of the lander took an image of a block of a frozen white substance that was later identified as water ice. This was the first surface observation of water ice on Mars. (Chaisson & McMillan)  The thrusters had blown away the regolith and revealed the ice. The most intriguing photos were taken over a period of approximately 30 days and revealed globules on the landing struts of Phoenix. The globules grew and receded then eventually completely disappeared. They were found to be liquid water mixed with perchlorates. (SpaceSci) This elemental composition was later proven to be the reason the water could stay liquid at sub zero temperatures and pressures far below that of Earth. (Astrobio2)(Science2)

The Phoenix lander also imaged, for the first time, water ice clouds and snow falling.  The temperatures at the time were not cold enough to form CO2 clouds which requires -120o C.  Instead the temperatures hovered between -97.7 o C and -19.6 o C, and would be conducive to H2O clouds and snow.  (Science2)(Geoscie)

Figure 6: Polygon shapes imaged by the Phoenix Lander in 2008 near the North Polar region of Mars. The polygons are formed by the freezing and thawing of the ice below the sand and the sand falls between the cracks of the ice as it expands and contracts.

Mars Science Laboratory Curiosity

As technology improved, images sent to Earth by various spacecraft had better resolution and scientific instruments have been able to gather more detailed information. Rovers, orbiters and landers have benefitted from the technological advancements in miniaturization of instruments, allowing more scientific equipment to be carried on each craft.   The implementation of the sky crane landing method has allowed for the landing of unprecedented payloads on the surface of Mars.

The Mars Science Laboratory Curiosity (MSL) is an 899 kg rover that landed via the sky crane landing method.  The rover has an entire laboratory on its back, many cameras, and a versatile arm. When NASA was deciding on a landing spot for Curiosity it was important to find an area with evidence of previous water activity in order to assess habitability.  Gale Crater is only 4.5o south of the equator and is the site of a significant alluvial fan from previous water activity.  

Within a few days after Curiosity landed at 4.58°S 137.44°E, it was announced by John Grotzinger, Project Scientist for MSL, on a NASA telecast, that Curisoity had landed in an ancient riverbed that had flowed vigorously with fresh water up to waist deep.  Grotzinger explained the water was so pure, based on chemical analysis of the surrounding area, that a person could have scooped up the water and drank straight from the river. This discovery was made initially by the photographs of the area that showed what appear to be concretions of rocks that would have been arranged in the position by the flow of water over a long period of time.  (See Figure 7) Another clue to the ancient riverbed was the rounded pebbled seen jutting out of the edge of the compacted rocks and pebbles. The rounded pebbles show that the water had to have persisted for a period of time long enough for rocks to tumble over each other and reshape them from their former jagged appearance. (NASANews)

Figure 7: Gale Crater ancient riverbed photographed by the Curiosity Rover in 2012.   Evidence include round pebbles and concretions that are clearly visible in this image. (NASANews)

The Curiosity team also discovered perchlorates in Gale Crater.  Perchlorates allow water to be liquid at temperatures below freezing.  Liquid brines can form in the pre-dawn hours on Mars. It has been proposed that within 5 cm of the surface, liquid brines form in Gale Crater.  This liquid evaporates after sunrise. Studies up to 15 cm beneath the surface indicate that an exchange of atmospheric vapor interacts with the surface regolith and through deliquescence liquid water forms. (Nature5)

Desiccated mud cracks have also been discovered in Gale Crater. (See Figure 8) This implies liquid water stood for a period of time, around 3 billion years ago, and mixed with the regolith making mud.  The water evaporated from the mud and what was left were polygon shaped muddy cracks. The cracks were buried over time by sediment that was blown across the surface. In more recent geologic history, the sediment was eroded away and what we see now are the remnants of dried mud cracks that were filled with sand.  In close proximity to the mud cracks were layers of mudstone and sandstone. This indicates periods of time when a body of water was sitting in the area. The water would have moved somewhat tidally over the boundary of the lake and what is left behind are areas that appear to be a lakeshore. Another point of view is that the mud cracks could have been formed during a dry period of blowing sediment.  Either way, indicating a dry period is by default pointing to a period of water in the area. (JPLnews) The data collected will continue to be studied.

Figure 8: Mud cracks in Gale Crater.  Desiccation of mud and subsequent filling with sand, leave eroded evidence of sitting water on Mars. (JPLnews)

 

 

Is it Water?

It is a fact that water has previously flowed on Mars and that frozen water exists in the polar caps, beneath the regolith, and chemically bound to the regolith.  The major issue is; does liquid water exist on Mars now for any period of time? Some scientists have looked at the evidence and come to the position that Mars is now dry and liquid water does not exist on the surface. The evidence against liquid water on Mars comes in various forms.  A percentage of scientists are diligently working to prove the evidence set forth regarding liquid water on Mars currently, is not water at all. This is the way science is performed. Scientists need to thoroughly look at every aspect of a scenario to attempt to disprove a theory only to try to prove it is a fact.  The major evidence supporting liquid water on Mars currently are the RSLs. However, some evidence suggests this may not be water at all but consists of sand flows. The explanations given are: the RSLs do not exist on any crater wall with less than a 27o gradient downslope and the MRO has not detected a signature for H2O at the RSLs in question. (JPL)  

The Knudsen pump effect explains that the amount of water present in the Martian atmosphere and beneath the surface of Mars in the area of RSLs is not sufficient for RSLs to be liquid water.  The mechanism thereby would be gases pushing the sand up due to heating from the Sun and the particles then fall down the slope of the crater. (Nature3) The MRO has taken measurements and the results indicate a lack of H2O in the area of the RSLs has been detected by the spectrometers onboard.  (arXiv)

Colin Dundas and his team at the U.S. Geological Survey’s Astrogeology’s Science Center in Flagstaff, Arizona created models of the RSLs, after studying over 150 of the phenomena, out of the thousands that have been discovered.  Dundas’ models indicated that the RSLs are more consistent with sand flowing down the side of a slope than liquid water. (JPL)

The aforementioned information appears to prove water is not in liquid form on the surface of Mars today.  However, these data do not explain all of the aspects of the RSLs. These features fade quickly, which would be more consistent with water.  The RSLs grow over a period of time gradually and appear during the warmer season. Hydrated salts have also been detected in the areas of RSL appearance. Hydrated salts can form as, though a miniscule amount has been detected, water vapor does exist in the Martian atmosphere, and the salts absorb H2O from the atmosphere.  This process may be creating salty water droplets.  The amount of water absorbed into the salt molecules would be small, but enough to cause the seasonal flows we see on the slopes of Mars.  Over 50 areas have been identified thus far to include RSLs. The location of the RSLs that have been identified stretch from the equator to approximately 45o N and S.  

Astrobiology

The implications for finding liquid water on Mars cannot be stated strongly enough.  Through the years astronomers have stated in various iterations the number one reason we study astronomy is to find out if we are alone in the universe.  Water is an essential ingredient to life as we know it. Steve Squyres, has stated many times NASA’s mission was to follow the water to try to build up evidence of finding a habitable environment on Mars.  Each mission has discovered that Mars has water in some form. Dr. John Grotzinger, project scientist for the Curiosity mission, when speaking about the discovery of an ancient freshwater riverbed in Gale Crater, went so far as to state, “We have found a habitable environment.  The water that was here was so benign and supportive of life that if a human had been on the planet back then, they could drink it.”  (NASArsl)

If liquid water exists on Mars today, extant life could exist.  Our studies on Earth of extreme organisms show that anywhere liquid water exists, we find life.  Extermophiles in the Atacama Desert can lie dormant for many years until a small amount of moisture encounters them.  Suddenly they wake up and reproduce and return to dormancy. (PNAS2) Extreme organisms, called halophiles, have been studied on Earth which can also tolerate salty environments, including perchlorates. (PubMed) This model can be used analogously to RSLs and small damp areas on Mars.

Conclusion

Water on Mars has been well established for decades. Every few months, NASA will release a statement ‘confirming’ water on Mars, due to the evidence collected from Martian spacecraft and Earth-based spectroscopy.  Water can remain in liquid form on the surface of the Red Planet for short periods of time when mixed with perchlorates and other salts.

When Christian Huygens looked through his telescope at Mars, he saw what he interpreted as definitive evidence of the polar ice caps.  Many astronomers tried to disagree and state another explanation. This is how the history of finding water on Mars has proceeded since that time.  Science is in the business of disproving to prove.

In the 1990’s Michael Carr wrote a book called Water on Mars, and in it stated that a water table must exist on Mars and to reach it, one should look about one-half of a kilometer underground.  If this is true, then water could break through the sides of craters and flow down the sides, bringing with it salts and minerals to be left behind and imaged by spacecraft.  Another fact that leads science to conclude liquid water exists on Mars is the age of the volcanoes on Mars. Many of the volcanoes were active 400,000,000 years ago.  This is about ten percent of the age of Mars.  Geologically the volcanoes are young, thus heat still exists beneath the crust of Mars.  If Mars is hot on the inside and cold on the outside, the temperature in the middle would be suitable for liquid water to exist and move toward the surface.  As we have seen briny water remains liquid at temperatures below freezing. The Curiosity Rover has imaged damp regolith on the surface of the Red Planet, this is sitting water mixed with the molecules in the dirt and causing dampness to occur.   “Since the 1990’s debunkers have said liquid CO2 or rivers of sand were the cause of the channels on Mars.  People are trying to come up with theories and ignoring the most obvious, these channels were created by transient water on the surface of Mars.” (Zubrin)

 

 

Bibliography:

AGU: American Geophysical Union. https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2005JE002584. (Accessed 6 April 2018)

arXiv. Archive Astro Physics. https://arxiv.org/pdf/1708.00518.pdf. (Accessed 5 April 2018)

Astrobio: Astrobio.net. https://www.astrobio.net/mars/liquid-water-ice-salt-mars/. (Accessed 4 March 2018)

Astrobio2: Astrobio.net. https://astrobiology.nasa.gov/missions/phoenix/. (Accessed 3 April 2018)

Astrobio2: Astrobio.net. http://www.astrobio.net/pressrelease/5150/meltwater-on-mars-could-sustain-life. (Accessed 2 April 2018)

Brit: Britannica online. https://www.britannica.com/science/deliquescence. (Accessed 26 April 2018)

Chaisson & McMillan: Astronomy Today Text 7th edition. P.256. 

dePater & Lissauer: 2016. Planetary Sciences. P.208. 

Geosci: The Journal Nature Geoscience. https://www.nature.com/articles/ngeo3008. (Accessed 24 April 2018)

Geo: Journal of Geophysical Research. https://agupubs.onlinelibrary.wiley.com/doi/pdf/10.1029/JS082i028p04225.  (Accessed 3 April 2018)

Geo2:  Journal of Geophysical Research. http://www.utsa.edu/LRSG/Teaching/EES5053-06/Christensen_2000_Detection%20of%20crystalline%20hematite%20mineralization%20on%20Mars%20by%20the%20TES_JGR.pdf . (Accessed 3 April 2018)

Huff: The Huffington Post. https://www.huffingtonpost.com/marc-dantonio/the-case-for-standing-water-on-mars-_b_7307406.html.  (Accessed 4 March 2018)

Icarus: The Journal Icarus. https://www.sciencedirect.com/science/article/pii/0019103587901473?via%3Dihub. (Accessed 26 April 2018)

Icarus2. The Journal Icarus. https://www.sciencedirect.com/science/article/pii/S0019103516000634?via%3Dihub. (Accessed 27 April 2018)

JPL: NASA’s Jet Propulsion Laboratory. https://www.jpl.nasa.gov/news/news.php?feature=7005. (Accessed 5 April 2018)

JPLnews: NASA JPL Cal Tech News Release. https://www.jpl.nasa.gov/news/news.php?feature=6721. ( Accessed 26 April 2018)

MarsFacts: NASA Mars Facts. https://web.archive.org/web/20130607140708/http://quest.nasa.gov/aero/planetary/mars.html. (Accessed 2 April 2018)

MarsNASA. NASA Mars News. https://mars.nasa.gov/news/1482/mars-rover-opportunity-trekking-toward-more-layers/. (Accessed 5 April 2018)

NASA:  NASA Mission Pages. https://www.nasa.gov/mission_pages/mars/images/pia09028.html#.WsP_M4jwZPZ. Accessed 3 April 2018)

NASAGeo: NASA Geology and Geomorphology. https://mars.nasa.gov/MPF/science/geology.html.  (Accessed 3 April 2018)

NASAjpl. NASA Jet Propulsion Laboratory News. https://www.jpl.nasa.gov/news/news.php?feature=4722. (Accessed 21 April 2018)

NASA/JPL: NASA Jet Propulsion Laboratory. https://www.jpl.nasa.gov/spaceimages/details.php?id=PIA17075. (Accessed 5 April 2018)

NASA/JPL-Caltech/Univ. of Arizona. NASA/JPL, Caltech, U of Arizona. https://www.jpl.nasa.gov/spaceimages/details.php?id=PIA18119. (Accessed 21 April 2018)

NASANatl. NASA’s National Space Science Data Center. https://nssdc.gsfc.nasa.gov/planetary/viking.html. (Accessed 3 April 2018)

NASANews. NASA News. https://www.jpl.nasa.gov/news/news.php?feature=4722. (Accessed 21 April 2018)

NASANews2. NASA News. https://www.nasa.gov/mission_pages/msl/multimedia/pia17062.html#.WuIzmC7wapo. (Accessed 26 April 2016)

NASAmer: NASA Mission Section, Mars Rovers. https://www.nasa.gov/mission_pages/mer/mer-20070521.html. (Accessed 6 April 2018)

NASAH: History NASA page. https://history.nasa.gov/SP-4212/p6.html. (Accessed 21 April 2018)

NASAPS: NASA Mars JPL. https://mars.jpl.nasa.gov/MPF/mpf-pressrel.html. (Accessed 21 
April 2018)

NASAOdyssey. NASA JPL Mars Odyssey News. https://www.nasa.gov/feature/jpl/test-for-damp-ground-at-mars-seasonal-streaks-finds-none. (Accessed 27 April 2018)

NASApress: NASA Press Release. https://mars.jpl.nasa.gov/mer/newsroom/pressreleases/20040305a.html. (Accessed 6 April 2018)

NASArsl. NASA. https://www.nasa.gov/image-feature/jpl/pia19916/recurring-lineae-on-slopes-at-hale-crater-mars. (Accessed 19 April 2018)

 NASATech: NASA Technical Reports Server. https://ntrs.nasa.gov/search.jsp?R=19700009038#. (Accessed 3 April 2018)

NASAtv. NASA Television Live Broadcast. (March 2013)(June 2013)

Nature: The Journal Nature. https://www.nature.com/articles/s41467-017-01213-z. (Accessed 4 March 2018)

Nature2: The Journal Nature. https://www.nature.com/articles/nature05594,

https://www.nature.com/articles/446150b [Image]. (Accessed 4 March 2018)

Nature3: The Journal Nature. https://www.nature.com/articles/ngeo2917. (Accessed 5 April 2018)

Nature4: The Journal Nature. https://www.nature.com/articles/ngeo2014. (Accessed 21 April 2018)

Nature5: The Journal Nature. https://www.nature.com/articles/ngeo2412. (Accessed 26 April 2018)

Nature6: The Journal Nature. https://www.nature.com/articles/352589a0. (Accessed 26 April 2018)

Pacific: Astronomical Society of the Pacific. http://iopscience.iop.org/article/10.1086/120651/pdf. (Accessed 6 April 2018)

Pacific2: Astronomical Society of the Pacific. http://iopscience.iop.org/article/10.1086/124817/pdf. (Accessed 6 April 2018)

Phoenix: NASA Phoenix Lander Page. https://www.nasa.gov/mission_pages/phoenix/overview. (Accessed 24 April 2018)

Phys: Phys.org. https://phys.org/news/2012-09-temperatures-gale-crater-higher.html. (Accessed 2 March 2018)

PNAS: Proceeding of the National Academy of Sciences. http://www.pnas.org/content/108/48/19159.  (Accessed 4 March 2018)

PNAS2: Proceedings of the National Academy of Sciences. http://www.pnas.org/content/early/2018/02/20/1714341115. (Accessed 27 April 2018)

Pubs: Geoscience World. https://pubs.geoscienceworld.org/msa/elements/article-abstract/2 /3/157/137699 (Accessed 4 March 2018)

PubMed. US National Library of Medicine. https://www.ncbi.nlm.nih.gov/pubmed/24150694. (Accessed 27 April 2018)

Science: The Journal Science. http://science.sciencemag.org/content/341/6143/263. (Accessed 3 April 2018)

Science2: The Journal Science. http://science.sciencemag.org/content/325/5936/64.full?ijkey=BVZRNinUWg62c&keytype=ref&siteid=sci. (Accessed 3 April 2018)

Science3: The Journal Science. http://science.sciencemag.org/content/sci/306/5702/1740.full.pdf. (Accessed 6 April 2018)

Science4: The Journal Science. http://science.sciencemag.org/content/325/5936/64. (Accessed 21 April 2018)

Science5: The Journal Science. http://science.sciencemag.org/content/359/6372/199. (Accessed 27 April 2018)

ScienceDirect: Science Direct Journal. https://www.sciencedirect.com/science/article/pii/S0019103513001668. (Accessed 21 April 2018)

Space: Space.com. https://www.space.com/17048-water-on-mars.html. (Accessed 4 March 2018)

SpaceSci: Space Science Review Journal. https://link.springer.com/article/10.1007%2Fs11214-012-9956-3. (Accessed 24 April 2018)

UofA: University of Arizona. https://grs.lpl.arizona.edu/grs-web/latestresults.jsp. (Accessed 21 April 2018)

Universe: How the Universe Works, Life and Death on the Red Planet. Jani Radebaugh, BYU, (24 January 2017)

Willett: The Red Planet Pen. http://education2.marssociety.org/category/redplanetpen/.  (Accessed 21 April 2018)

Zubrin: Robert Zubrin, PhD. Phone conversation. 6 April 2018. 
Categories
Red Planet Pen

Insight Launch Guide: “Witnessing History” (Issue #38)

Guest blog by: Rich Cabral

I would like to extend a very special thanks to Mr. Cabral for his tireless work, dedication, and commitment to ensuring the public has every opportunity to view this historic launch.   -N. Willett

“It should prove to be a real crowd pleaser.” –Col. Gregg Wood, Vice Commander, 30th Space Wing, Vandenberg Air Force Base

Launch window opening:  May 5th, 2018, 4:05-6:05 a.m. PST (7:05-9:05 a.m. EST)

Insight will launch from Space Launch Complex-3 (SLC-3), Vandenberg Air Force Base, California, aboard an Atlas V-401.  The rocket will fly in a 401 vehicle configuration and will have no side mounted boosters.

The Mission:  Insight is the first West Coast Interplanetary Launch.   All previous interplanetary launches have been from the Kennedy Space Center, Florida.

“InSight, short for Interior Exploration using Seismic Investigations, Geodesy and Heat Transport, is a Mars lander designed to give the Red Planet its first thorough checkup since it formed 4.5 billion years ago. It is the first outer space robotic explorer to study in-depth the “inner space” of Mars: its crust, mantle, and core.

Studying Mars’ interior structure answers key questions about the early formation of rocky planets in our inner solar system – Mercury, Venus, Earth, and Mars – more than 4 billion years ago….”  –NASA/JPL

Besides being a major scientific event, Insight is a milestone in the story of humans in space..

Viewing:  recommended viewing sights:  Click the map below for sights, where to get breakfast or an early morning snack, and where to stay if you plan on hanging around “The Valley”.

Map

Safe Viewing:  There’s nothing like a live view of a launch.  The roar of the engines, the white trailing flame, and the crowd of fellow launch enthusiasts: Its exciting, no doubt about it.  But, Vandenberg Air Force Base is, above all, a highly secure Government sight. So, it’s a good idea to be on one’s best behavior during a launch. Base business is serious business.  Military, city, and county police launch presence makes sure that business is respected and understood. Treat those officials with respect and they’ll do everything they can to help.

Weather/Mechanical/Delays:  Central coast weather is temperamental.  Then, there are equipment problems. As a result, weather, mechanical delays and launches go hand-in-hand.   Three attempts before a successful launch is about average.  Less or more attempts are also to be expected.  Plan to go to a launch, based on the understanding it may or may not happen.  Anything else is unrealistic.

Clothing: At 4am it can be cold in the Lompoc Valley.  Dress in layers.

Hotels:  Here’s a list of Lompoc hotels if you plan on staying overnight.

Hilton Garden Inn

Embassy Suites

Lompoc Valley Inn & Suites

O’cairns Inn & Suites

Holiday Inn Express

If Lompoc is sold out, there are hotels in nearby Buellton, Solvang, Santa Maria

Breakfast after the launch:

Hilton Garden Inn, Valle Eatery, 1201 N. H St, Lompoc  93436; opens 5:30 am.  The Hilton is planning on having food available for purchase prior to the launch. Contact the hotel at (805) 735-1880 for more information.

American Host, 113 N. I Street, Lompoc  93436; opens 5:30 am. If the door is locked, knock and ask for Lisa.  Tip:  this is where the launch crew often goes after a launch.

Cajun Café, 1508 N. H Street,  Lompoc  93436; opens  at 6:30 am.

Stay up-to-date: Insight on Twitter;  Insight on Face book;  Vandenberg on Face book

If you can’t be there: 

Watch the launch live:

https://mars.nasa.gov/insight/

https://spaceflightnow.com/

Listen to the sound of  a rocket launch in binaural audio immersion.  This is a recording of Falcon Heavy. But, it comes about as close as can be to what a launch sounds like when you’re actually there.

https://www.youtube.com/watch?v=ImoQqNyRL8Y&feature=youtu.be

Musically, this is what a launch feels like, particularly at Vandenberg, where the setting, the land itself and the ocean, tell a timeless story of an  epic journey in the human saga: In the early morning hours, with launch lovers all around you, turn up the volume, and know what you are about to witness.

 John WilliamsAmerican Journey- Flight and Technology

Rich Cabral:  Rich has worked many launches at  “Vandy.”

His passion:   “What else:  The biggest step of all in human migration!”

Categories
Red Planet Pen

Building Mars: Modeling Permanent Structures Using Mars-Sourced Materials (Issue #37)

Guest Blog By: Lorena Bueno

Edited by: Margaret Lattke

Crack open any mid-level science novel from the last 70 years and you’ll find, among fanciful descriptions of grand canals and sand-scattering weather systems, varied descriptions of what’s underfoot (or boot): Martian sand. Regolith, powder, basalt rock, even clay, hint at a time when Mars had enough water and geologic activity to create clay.

As we plan our first trips to Mars on Earth with the Mars Desert Research Station (MDRS) of the Mars Society, the next few missions on Mars will give us more data on the clay deposits of our near neighbor. With this data we can add clay-based structures to our plans of more permanent structures.

What can we do with clay?

If the clay deposits are significant enough, this ancient building material may give us one of the first resources we can use to help protect and define the boundaries of our research and colonization outposts. While our first clay bricks may be as handmade as those first made on Earth, we’ll bring with us approximately 9,000 years of advanced knowledge and technology. We’d start by studying how clay behaves in the environment of Mars before and after it is shaped into usable chunks. A team of engineers at the University of California San Diego has already created no-bake brick samples out of simulated “Martian Soil”.

While ancient Earthlings mixed, shaped, and dried their bricks outside in sunny, warm climates, that won’t work as well on Mars. We’ll need to create processes on Earth to simulate the kind of brickworks we can create in Mars’ atmosphere (1/100th of our atmosphere here on Earth) or in a pressurized habitat. These experiments will help us figure out how to keep the mixture of clay, water, and other ingredients together long enough to be shaped and finished.

After test bricks of various recipes are created, we’ll simulate how well the bricks wear in a Mars-like environment. First, each type of brick will be tested individually to see how it reacts to the extreme heat and freezing cold temperatures characteristic of a typical Martian day during any season.

Next, we’ll subject the bricks to weather testing: blowing the bricks through a series of Martian storms. Despite what we’ve seen in the movies, the winds of Mars don’t do nearly as much damage as a comparable storm on Earth. Winds on Mars don’t get higher than 60 or 70 miles per hour. That much wind speed on Earth would knock you over! But with Mars’ 1% atmospheric pressure, 60 mph on Mars would feel like 6 mph on Earth just about enough to launch and fly a medium-sized kite.

Then we’ll move on to testing bricks in groups. Studying bricks of different sizes and shapes, set up as solid walls and berms, will determine how they withstand the weather, wind, and dust storms of Mars. We may even skip shaping blocks directly, and simply make a brick “mix” that can be sprayed or extruded into the shapes we need to build our permanent structures.

 

Building walls on Mars … with math

Constructing a protective barrier from Martian-sourced bricks provides its own special engineering challenges. Modern bricks on our planet are bound together using specialized adhesives and mortars; Mars’ thin atmosphere makes those solutions unworkable.

The solution lies in the way the bricks are shaped and stacked. Interlocking bricks, laid in deep, long patterns, can be built up enough to serve as weather berms. By directing the worst gusts of stronger windstorms away from habitats or remote sensor arrays, we can extend the life of the buildings we bring from Earth.

Simple structures can be built with a combination of Earth and Mars materials as well. While we have to live in pressurized habitats, movable equipment, such as rovers or trailers, may only need a simpler protective shelter. Picture a basic structure made up of brick walls topped with solar panels. These shelters can be built around a metal or composite frame with a protective door to keep out the worst of the blowing sands.

We can set up a series of emergency maze-style shelters as well. A shelter you can drive in and out of, designed to keep sand out during a sudden storm. Stage these along known trails or byways to help keep travel between far-flung sites safe.

Though solar panels are a popular means for capturing energy in most of our plans for Mars, we can also corral and use the energy created by the planet’s vast winds. Mars-made bricks might be used to create funnels designed to speed wind through specialized wind turbines, hardened to work on Mars and provide power backup during the worst of the hemispheric or global storms.

Reducing the costs of exploration – Getting more with less

As a species, every dollar we spend learning and exploring lifts us higher. Once we’ve done the hard work of getting the first explorers to our neighboring planet, everything we do there, along with the support of those teams, will make it easier for the next generation of explorers and humans watching from afar.

As humans, we’ve spent our history expanding our horizons, finding new ways to innovate and grow. Taking that tradition, and all we’ve learned, to Mars and beyond, is in our DNA. Sure we can send modules, supplies, food, and people to Mars. However building or augmenting or augmenting permanent structures from local materials gives us more than a way to save money; we can learn from and apply science in the field and export it back “home”.

~Humans to Mars as a Bridge to the Stars

 

 

Research links:

http://theconversation.com/research-on-clay-formation-could-have-implications-for-how-to-search-for-life-on-mars-88507https://www.space.com/16895-what-is-mars-made-of.htmlhttps://brickarchitecture.com/about-brick/why-brick/the-history-of-bricks-brickmakinghttp://www.extension.umn.edu/garden/landscaping/implement/soil_berms.htmlhttps://en.wikipedia.org/wiki/History_of_construction
http://ucsdnews.ucsd.edu/pressrelease/engineers_investigate_a_no_bake_recipe_to_make_bricks_from_martian_soil

Image Credits: IB Times, The Mars Society

 

 

Categories
Red Planet Pen

Origin of Life Theories and Mars Exploration (Issue #36)

Guest Blog by Bob Bruner

Bob Bruner has attended and presented at the scientific conferences described below since 2015.  His contribution is entitled “Special Exhibit on Meteorites and Minerals associated with the Origin of Life on Earth or Mars” and can be found on the web. He is a long-time member of the Mars Society and is a volunteer at the Denver Museum of Nature and Science.

I would like to offer a special THANK YOU to Mr. Bruner for traveling the world to bring us this first hand report and his tireless passion in the pursuit of scientific knowledge. 

 

Four popular origin of life theories that have influenced the hunt for life on Mars.  The first are the clay theories which probably started in the late 1950’s with Dr. Bernal of the UK.  They were further developed in the 1970’s and 1980’s by Dr. Cairns-Smith of the UK, then in the 1990’s by Dr. Ferris of the USA.  They were added to in the 2000’s by Dr. Hashizume of Japan and Dr. Hansma of the USA.  The theories claim that the structure of clay can provide compartments for proto life to begin, with large molecules like RNA developing later.

The second are the Black Smoker-type hydrothermal vents at the bottom of the ocean theories primarily developed by Dr. Wachtershauser of Germany with an emphasis on iron-sulfur and Dr. Mulkidjanian of Germany with an additional emphasis on zinc.  These theories claim that the minerals have the ability of powering the chemical reactions that allow small organic molecules to get larger and larger, ultimately becoming proto life.  They were popular in the 1980’s and 1990’s.

The third are the warm hydrothermal vents at the bottom of the ocean theories primarily developed by Dr. Russell of the USA, Dr. Sleep of the USA, Dr. Schulte of the USA, and Dr. Holm of Sweden.  These theories took off when the Lost City hydrothermal field was discovered by Dr. Kelley of the USA in the 2000’s.  The process of serpentinization, where olivine/pyroxene interacts with CO2 and sea water to produce serpentine, magnetite, brucite, CH4 and H2, gives new proto life energy and food.

The fourth are the surface hydrothermal pool theories which probably started with Darwin in 1859, but gradually fell out of favor until revived by Dr. Deamer and Dr. Damer of the USA in 2016.  They envision small areas of land above a mostly-ocean Earth which contain warm pools interacting with the surrounding environment creating wet-dry cycles which create ever larger organic molecules, ultimately becoming proto life.  Opaline silica and geyserite and sinter line hydrothermal pools.

For many years the clay theories dominated the hunt for life on Mars, not only as proof of water (the existence of clay proves past water) but lately in the case of montmorillonite as a source of food for microbes according to Dr. Craig of the USA.  The next hot theory was black smoker-type hydrothermal vents where abundant life forms were spotted by expeditions to the bottom of the sea.  But some scientists said the hot water would not allow large molecules like RNA to develop.  Then came the warm hydrothermal vents where the water was not too hot for large organic molecules to develop. This theory became the most popular theory because life would be protected from bad things happening on the surface such as bombardment by asteroids and comets.  In fact it was adopted by the Europeans in their roadmap ASTROMAP published in 2015.  But in 2016, the idea that surface hydrothermal pools provide required wet-dry cycles started to dominate.  At the NASA Biosignature Conference in 2016 this idea dominated the conference report so much so that the warm hydrothermal vent people asked for a pre-meeting to produce their own report about rock-

Three Finalists for Mars 2020 Landing Site

water interaction before the 3rd Landing Site Meeting for the Mars2020 rover in 2017.  Even so, the landing site Columbia Hills was still promoted to third place over other sites which had more votes because of the work done by Dr. Van Kranendonk and Dr. Walter of Australia and Dr. Farmer and Dr. Ruff of the USA.  At the 4th Landing Site Meeting for the Exomars 2020 Rover in 2017, the only theory NOT promoted was the Black Smoker-type hydrothermal vent theory.

As one can see, politics among scientists have influenced landing site decisions and have no place if good science is to emerge.  If a voting system was agreed to ahead of the conference, it should be followed.  It was followed at the 4th Landing Site Meeting for Exomars 2020, but it was not followed at the 3rd Landing Site Meeting for Mars2020.

[Image Credit: PBS.org, Exploring Earth, NASA]

 

Note and Reference: The key minerals for obiters and rovers on Mars are clays (montmorillonite), serpentine, and opaline silica. See my abstract at astrobiology.gr   scroll down to EANA 2016 abstracts on page B8.