NASA Asteroid Missions

Asteroid day is celebrated every day at NASA. We are constantly gazing to the sky, from expeditions to asteroids in our solar system – some of which even return samples to Earth – to attempts to locate, track, and monitor near-Earth objects and safeguard our planet from possible impact dangers.

Several ambitious missions to investigate unusual asteroids will be launched in the coming years. 

In October and November 2021 NASA will be launching, 

• The Lucy mission

• Lucy is the Trojan Asteroids' First Mission

• These primordial entities may contain crucial insights about the solar system's past, as well as the beginnings of biological stuff on Earth.

• The Double Asteroid Redirection Test (DART) mission

• NASA has entrusted the Double Asteroid Redirection Test (DART) mission to the Johns Hopkins Applied Physics Laboratory (APL), with assistance from several NASA centers including the Jet Propulsion Laboratory (JPL), Goddard Space Flight Center (GSFC), Johnson Space Center (JSC), Glenn Research Center (GRC), and Langley Research Center (LaRC).

• DART is a planetary defense-driven test of technology aimed at preventing an asteroid from colliding with Earth. DART will be the first time a kinetic impactor will be used to alter an asteroid's velocity in space. 

• The DART project is now in Phase C, directed by APL and administered by Marshall Space Flight Center for NASA's Planetary Defense Coordination Office and the Science Mission Directorate's Planetary Science Division at NASA Headquarters in Washington, DC, under NASA's Solar System Exploration Program.

Followed by,

• The launch date for the Psyche mission is set for 2022.

• The Psyche mission will go to a rare metal asteroid that orbits the Sun between Mars and Jupiter. 

• The asteroid Psyche is unusual in that it seems to be the exposed nickel-iron core of an early planet, one of our solar system's building components.

• OSIRIS-REx started its return to Earth in 2021 and is scheduled to arrive in 2023 with an asteroid sample in tow. 

• OSIRIS-REx has arrived at the near-Earth asteroid Bennu and is bringing back a tiny sample for examination. 

• The mission took off from Cape Canaveral Air Force Station on September 8, 2016. 

• In 2018, the spacecraft arrived on Bennu, and in 2023, it will return a sample to Earth.

• The Near-Earth Object Wide-field Infrared Survey Explorer (NEOWISE) satellite observatory has also received a two-year mission extension to continue its hunt for asteroids and comets.

• It has verified infrared sightings of over 39,100 objects in our solar system to far.

• From December 2009 to February 2011, NASA's Wide-field Infrared Survey Explorer (WISE) was a NASA infrared-wavelength astronomical space telescope. 

• The spacecraft was revived in September 2013, renamed NEOWISE, and given a new mission: to help NASA in identifying and characterizing the population of near-Earth objects (NEO).

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Mars Robotics - Robotic Exploration of Mars

NASA's Mars Exploration Program (MEP) is managed by JPL. For many years, this program has been conducting a series of robotic missions to investigate Mars. 

• The success of the Mars Pathfinder, Mars Exploration Rover, and Mars Science Laboratory missions has shown that autonomous rovers can effectively and efficiently explore the surface of Mars and collect scientific data in small regions. 

• As a consequence, the MEP has created an ambitious long-term strategy for in situ exploration based on a consensus among top Mars scientists. 

• The hunt for past or current life on Mars is the highest priority objective. 

For instance, a JPL website addresses the question, “Why Explore Mars?” 

• Mars has the most pleasant environment in the solar system after Earth. 

• It was once so welcoming that it might have supported primitive, bacteria-like life. =

• Outflow channels and other geologic structures on Mars' surface offer sufficient evidence that liquid water flowed billions of years ago. 

• Although liquid water may exist deep under Mars' surface, the temperature is presently too low and the atmosphere is too thin for liquid water to exist at the surface. 

What caused the climate on Mars to change? 

Were the prerequisites for the emergence of life ever exist on Mars? 

Is it possible that microorganisms in the subsurface are still living today? 

 

These are the kinds of questions that motivate us to go to Mars. 

Mars' environment has clearly cooled significantly.... 

We must initially ask the following questions when we begin to explore the cosmos and seek for planets in other solar systems: 

Is there evidence of life on another planet in our solar system? 

What are the bare minimum requirements for the emergence of life? 

Four topics were prioritized by the Mars Exploration Program 

1. Look for traces of a previous existence. 
2. Investigate hydrothermal environments. (The chances of finding evidence of past and current life have considerably increased.) 
3. Look for the current moment. 
4. Investigate the development of Mars. 

The hunt for proof of previous life was the main short-term aim. If hydrothermal vents were identified (which they haven't yet), the search would be narrowed down to those areas. 

The hunt for current life would “follow on from previous orbiting or landing missions discovering that current Mars conditions have the capacity to sustain life.” 

Only if the... presently accepted theories for Mars' climatic history are wrong will the subject of Martian evolution be highlighted. 

If future missions show that there is no convincing evidence of wet conditions on ancient Mars involving standing bodies of water, as has been interpreted from orbital remote sensing to date, the program's current focus on the search for surface habitats will be lowered significantly — unless, of course, liquid water is discovered on or near the surface of Mars today. 

With this unexpected finding would arise the conundrum of how the terrestrial planets developed so differently, despite their striking resemblance. 

Liquid water, on the other hand, is unstable at Mars' surface temperatures and pressures. 

As a result, standing pools of liquid water cannot exist on or near Mars' surface. 

Liquid water might theoretically exist far under the surface, where temperatures are greater, and liquid water under pressure could sometimes rush up to the top owing to a subterranean event, where it would rapidly freeze. 

                                                                

The loss mechanisms and sinks for water and CO2 on Mars would be studied throughout time, as well as comparisons of the parallels and differences between the three terrestrial planets: 

Venus, Earth, and Mars. More than 130 terrestrial and planetary scientists gathered at Jackson Hole, Wyoming, to study early Mars. 

The report's primary topic was the hunt for life on Mars. In their 26-page study, the term "life" appears 119 times, or almost five times each page. 

According to the report's introduction, "perhaps the single most compelling reason scientists find this early period of Martian geologic history so compelling is that its dynamic character may have given rise to conditions suitable for the development of life, the creation of habitable environments for that life to colonize, and the subsequent preservation of evidence of those early environments in the geologic record." 

“Did life emerge on early Mars?” was listed as one of the three “top scientific questions linked to early Mars.” 

“The issue of Martian life contains basically three fundamental aspects,” the study continues. 

• The first was the idea that Mars might have had its own separate genesis of life. 

• The second was the possibility of life developing on one planet and then being transported to another via impact ejection and gravitational capture (i.e., panspermia). 

• The third looked at the possibility of life on Mars having survived and developed after its first appearance. The study goes on to say that “how life starts anyplace remains a basic unsolved mystery,” and that “the closeness of Earth and Mars raises uncertainty as to whether Earth and Mars had genuinely separate beginnings of life.” 

Microorganisms may have been transferred between the two worlds as a result of meteoritic collisions, such as those that brought Martian meteorites to Earth. 

In the distant geologic past, impact events were much more common and significant, including at the time when life started on Earth. 

As a result, it's impossible to say if the finding of life on Mars entails the discovery of a genuinely separate genesis of life. 

Because liquid water is thought to be a required (but not sufficient) prerequisite for life to develop from inanimate materials, the Mars scientific community puts a high priority on finding evidence of liquid water's previous effect on the surface (it cannot exist there under present conditions). 

The hunt for evidence of previous circumstances that might have supported life on Mars is still a major focus of the mission. 

The key issue for Mars exploration, according to the MEP, is: Is there life on Mars? 

Among the many discoveries we've made about Mars, one stands out above the rest: 

the possibility of liquid water on Mars, either in the distant past or now in the subsurface. 

Water is essential because life exists nearly everywhere on Earth where there is water. 

If Mars previously had liquid water, and if it still does now, it's intriguing to speculate about whether microscopic life might have evolved on its surface. 

Is there any proof of life on the earth in the past? 

Is it possible that any of these small live organisms survive today? 

Consider how thrilling it would be to say, "Yes!" 

• The first science goal is to find out whether life has ever existed on Mars. 

• NASA will need to undertake multiple missions over the next several decades to determine if life ever existed on Mars. 

• Similarly, the hunt for life lies at the heart of NASA's exploration of other planets in the solar system and beyond. 

• A hunt for life on Titan, Saturn's moon, and the Search for Extraterrestrial Intelligence (SETI) using radio telescopes are among them. 

The focus on life in the NASA community has swayed a number of otherwise competent and even prominent scientists to develop programs, papers, and reports to analyze, hypothesize, and imagine the possibility of liquid water and life on other planetary bodies, with a particular focus on Mars—and the press has exaggerated these occasional musings. 

Mars scientists are under a lot of pressure to discover implications for water and life in their research. 

An interesting article reports on an interview with Steve Squyres, the project scientist for the Mars Exploration Rovers mission. 

The following are two extracts from the article: 

According to reports, Squyers believes the rovers would provide answers to two questions: 

"Are we alone in the universe?" and "How did life come to be?" 

Most significantly, they've discovered signs of water on Mars. There is life where there is water. It's hard to believe Squyres really stated this. 

How can the media say such ludicrous things? 

What proof is there that a planet with liquid water had life at some point? 

Isn't it possible to tell the difference between essential and sufficient? 

Although water is essential for life, is it sufficient? 

There is no proof that it is. And who in their right mind thinks the MER rovers will provide a solution to the issue of how life forms? 

This isn't science at all. It's the worst kind of pseudoscience. 

In regular news releases ascribed to renowned and competent space experts, the Internet is full with crazy erroneous claims. 

P.S ~ When did science go from proving hypotheses with measurements, cautious understated conclusions, and carefully verifying ideas before going public—to wild untested statements, baseless claims, and repeated press releases reporting nonsense?

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Mars Exploration And The Search For Life

The Apollo human trips to the Moon must be considered one of mankind's greatest technical accomplishments, especially given the rudimentary electronics available at the time. 

• That was undoubtedly the pinnacle of NASA's accomplishments. 

• Since then, NASA has been debating what should happen next in terms of people in space.

• There seems to have been a strong desire to get humans into space, which led to the creation of the Space Shuttle. 

While it is true that any human mission in space requires access, the problems with the Shuttle were that, 

(i) the development and operation of the Shuttle required so much funding that there wasn't much left over to support what humans would do once they did get access to space, and 

(ii) the Shuttle's reliability deteriorated over time, until the main goal seemed to be merely to land sat. 

Following the Shuttle, NASA began on the Space Station, which, like the Shuttle, proved to be a money drain while delivering even less value. 

Michael Griffin was the NASA Administrator at the time, and his perspective aligned with Robert Zubrin's: 

• The NASA budget allocates funding to its constituencies for technology development in the belief that if enough technical work is done, the building blocks for missions will be available (Zubrin 2014). 

• As Zubrin put it, "technology and hardware components are created in accordance with the desires of different technical groups" under this manner. 

These initiatives are therefore justified by the premise that they may be helpful in the future when large-scale flying programs are restarted. 

• In theory, if executed intelligently and successfully, this method has considerable value. 

• However, we know from experience that establishing and maintaining a link between technology development and mission requirements is difficult. 

Furthermore, the requirement to connect technology to particular objectives may suffocate innovation and hinder development on higher-paying technologies. 

• Griffin, unlike his predecessors, was committed to what Zubrin referred to as the Apollo Mode: first, a destination for human space travel is selected. 

• After that, a strategy for achieving the goal is devised. Following that, technologies and designs are created to put the strategy into action. 

• The mission is then flown once these designs have been constructed. 

Griffin's strategy was to choose a particular destination and devote a significant portion of NASA's budget to developing technologies to get there. 

• By rapidly phasing out the Shuttle and the Space Station and diverting NASA Center technology money to shorter-term initiatives directly meeting the requirements of his destination-driven mission idea, his goal was to establish a pool of resources inside NASA for executing his vision. Griffin made the decision to return to the Moon. 

• He most likely postponed a trip to Mars because the finances were just not available. 

An interview with Griffin may provide some insight into Griffin's thoughts (2010). 

• He said in the interview that the Obama administration's strategy "does not bring us out beyond low Earth orbit in a timely and efficient manner." 

• Transporting people to the Moon, he said, was an essential step toward ultimately sending humans to Mars. 

• He also said that "the Moon is fascinating in and of itself." “I believe the experience of learning how to live on another planet just three days from home is extremely valuable...” he said. 

• Griffin's objective, however, was not able to be realized due to a lack of funding in the NASA budget. 

• Griffin's Constellation project was hampered by continued funding for the Space Shuttle and the International Space Station. 

Furthermore, after further consideration, the benefit of returning to the Moon seemed to be extremely speculative. 

President Barack Obama canceled the Constellation program in 2010, and NASA seems to have returned to a constituency-driven model since then. 

 

While NASA has made some crazy promises about sending people to Mars in the 2030s, beautiful PowerPoint slides do not seem to be enabling for this trip. 

• How, where, and when life emerged from inorganic materials is an unanswered question. 

• One fundamental piece of information we have is that life lived on Earth in a rudimentary form over 3 billion years ago (BYA). 

• This was discovered in dated strata using fossil remnants of early forms of life. 

What was the method through which lifeless matter gave birth to life in its earliest stages? 

Is there life beyond the solar system or somewhere in the solar system? 

All of these issues are subordinate to the main question: 

• Is the emergence of life from inanimate matter a probable (or perhaps predictable) process given enough time, a warm environment, liquid water, and a scattering of chemical elements from the lower periodic table? 

• Some scientists have used logic and creativity to concoct a broad range of possible scenarios for the emergence of life, many of which are based on little evidence. 

To this writer, they seem to be extremely questionable. 

• Science despises the lack of solutions to critical problems, just as nature despises a vacuum. 

• As a consequence, scientists have come up with a variety of "explanations" for how life started.

• There are many articles on livable worlds. Surely, there must be a large number in the different galaxies. But the issue isn't whether there are livable planets; there are. 

What is the likelihood that life would emerge spontaneously on such a planet? 

• The commonly held idea seems to be that any planetary body with enough heat, water, and a few components would spontaneously develop life. 

• Given this viewpoint, Mars seems like an obvious location to look for alien life. 

As a result, NASA's exploration missions are primarily focused on looking for life on Mars. 

But how likely is it that life will develop on such a planet?

Is NASA looking for an ephemeral fantasy with a very little chance of occurring?

~ Jai Krishna Ponnappan

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