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We Should Become Martians: Part I. ~ Guest Blogger Claude Plymate Returns!

  Claude Plymate is the Telescope Engineer/Chief Observer at  Big Bear Solar Observatory in California, and is the  former chief  wrangler of the McMath-Pierce Solar Telescope at Kitt Peak National Observatory Arizona for many years. He is a regular contributor to Musical Milliner.

It likely won’t come as any surprise to those of you who know me or have read some of my earlier essays that I am a strong advocate of sending humans to Mars. What might surprise you are my reasons which are more about societal needs than about scientific exploration. Our population has now passed the 7 billion mark.

There are indicators all around us that this planet cannot maintain the pressure we’re applying to its resources and resiliency. There is little reason for me to go into the details here; you are all well aware of the risks we are subjecting ourselves to. Global climate change, fresh water depletion, famine, nuclear proliferation, pandemics and war are just a sampling of the dangers we pose to ourselves. On top of our self-imposed hazards, the solar system is in general a menacing place to live.  Asteroid impacts have already wiped out the dominant species on Earth at least once before.  A nearby supernova could disrupt our ozone layer with catastrophic consequences. We are fortunate to have a strong magnetic field and atmosphere that protects us from the harsh radiation coming from solar flares but civilization has left our technology quite vulnerable to such eruptions. It doesn’t appear that a “super flare” will kill us outright but just imagine the disruption to society if the Internet, electric grid, GPS system, radio communications and even telephones suddenly and unexpectedly went ‘dark’– and not just for a few hours but possibly days, weeks or even months!

What I’m trying to point out is that there are many real threats to our civilization and even our existence as a species. Some are self-imposed, some are natural.

This leads us to the question of how to mitigate such threats to humanity.  Consider how you deal daily with risk management of other items you regard as valuable. For example, you wish to protect your documents and photos stored on your computer’s hard drive. What do you do? Of course, you backup your files onto a separate drive stored  in a separate location. (You do back up your files, don’t you?)  Applying this same rationale to society naturally leads to the conclusion that to survive long-term, humanity must expand beyond this one little planet.  Then, even if the unthinkable occurs, all that humanity has achieved won’t completely disappear from history.

The obvious first destination for a human outpost beyond Earth is Mars. Mars is the most Earthlike of the other planets within the solar system. It is close in astronomical terms and has an atmosphere. Mars is a place we can live. Plus, the lower surface gravity of Mars (about 1/4  that of Earth) makes getting on and off its surface much easier than here on the Earth.

Unfortunately, the atmosphere on Mars is very tenuous with a mean surface pressure ~ 600 Pa (0.087 psi), equivalent to an Earth atmospheric altitude of around 90,590 ft (27,612 m). On top of that, it’s a toxic mixture of mostly carbon dioxide. Anyone on the surface would have to wear a pressure suit (space suit). Even this exceedingly thin atmosphere could be used to pressurize suits & shelters. All that would be needed would be a compressor to pressurize the interiors. Simple inflatable structures could even be used for such things as storage, workshops and greenhouses. You still couldn’t breathe in the high CO2 environments but an oxygen mask would be all that’s required for people to work in otherwise shirtsleeve comfort. There are likely many plants that could thrive in these pressurized greenhouses. Obliviously, living quarters would need more oxygen to make a breathable atmosphere which is easily attainable
by liberating O2 from either CO2, water or even iron oxides (rust!) in the soil that gives the planet its red color.

Water means life. We need water to drink, water for crops and water to make oxygen. Recent Mars probes are making it clear that water (at least in the form of ice) is much more common on Mars than previously believed. What is required to harvest the water is energy; energy to drill wells or mine ice, energy to extract the O2. Possible sources for power include solar panels and/or nuclear generators and perhaps even geothermal. I suspect that the atmosphere is simply too thin to support wind power.

There are two primary arguments against going to Mars that people normally state; interplanetary spaceflight is beyond our technical ability and the cost would be far too great. I’d like to address these arguments one at a time.

Stay tuned for We Should Become Martians: Part II next week.

(c)GosGusMusic(ascap)2012

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Ascolta Tutti

Our resident guest columnist, professional astronomer  Claude Plymate of NSO at Kitt Peak takes up more Big Questions.  This week : Life in the Universe, Part I ~ Are We Martians?

One of the foremost questions in science as well as theology has always been “are we alone in the cosmos?” For the first time we are actually making real headway into answering this fundamental question. Recent results in biology have shown that life is far more tenacious than we ever could have imagined. At the same time, astronomers are demonstrating that planets are rather common companions to stars. Current estimates are that between 30 – 60% of stars include planetary systems. That would indicate that there are something like 30 to 60 billion planetary systems in our galaxy alone! That’s 5 – 10 planetary systems for each individual living on Earth. And if you assume our solar system is somewhat typical, each planetary system likely includes several planets. These overwhelmingly huge numbers makes it very easy to assume that Earth cannot be so special as to be the only place in our Universe where life has taken hold.

Observations of Mars from telescopes atop Mauna Kea, Hawaii have found evidence of methane in its thin atmosphere. This methane could be the result of geologic processes but could just as well be a side effect of life – living, farting organisms! What would if mean for the commonality of life throughout the Universe if we were to find it growing right now on our next door planet? Well, it depends. If it was found that life had spontaneously and independently sprang into existence on at least two distinct planets in our solar system, the implication would be that life is easy to get started and that life is likely to be found just about anywhere that the proper conditions exist. If however there is or ever was life on Mars, it is highly likely that it is directly related to life here on Earth and that its origin was not independent.

It is well known that throughout the history of our solar system a significant amount of asteroidal material has been flung back-and-forth between the Earth & Mars. The Martian meteorite ALH84001 made quite a media splash back in the 1996 when a team of NASA researches announced that structures imbedded in the rock appeared to show fossilized evidence of microbes. The controversy continues about the origin and meaning of these structures but it does clearly show that material from Mars occasionally does make the trek to Earth. Presumably, although not nearly as common, rocks that have been blasted off of the Earth by asteroid impacts should also occasionally find their way to Mars. (Mars’ weaker gravity and thinner atmosphere makes it easier to eject material off that planet than from the Earth. At the same time, more meteors will get pulled into Earth’s deeper gravity well.) It’s been shown that many types of microbes can easily survive inside a rock catapulted off of a planet and in the harsh conditions of interplanetary space for the time required for travel between Mars and Earth. This cross-contamination between the two planets would seem to make it highly likely that any life there is directly related to life here. The concept of life on a planet being seeded by life from elsewhere goes by the name panspermia. Panspermia makes it quite possible that we are all Martians!

As cool as it may seem to think that we might have or had microbial relatives living on Mars, it would tell us nothing about how likely or how often life gets started in the first place. Mars, however, is far from our last possible place to look for extraterrestrial life inside our solar system. Several of the moons around Jupiter and Saturn are believed to have liquid water oceans below frozen ice mantles. Any of these sub-surface oceans might make comfortable ecospheres for extraterrestrial critters. And it is rather unlikely that Earth or Martian bugs could have made the journey that far out in the solar system. Any life out there is quite unlikely to be related to us. If any other life that is truly unrelated to life here on Earth is found within our solar system, the odds are overwhelming that life must be pervasive throughout the Universe.

This leaves us at this the moment without knowing how easy it is for life to get itself started. What is clear is that once life does get going, it quickly adapts to a very wide range of conditions; I think the quote from Jurassic Park was “life finds a way.” Even if we find that life is difficult and takes a long time to get started, there are so many planets that have been around for such a very long time that the odds seem good that life – at least microbial life – is common across the galaxy.
Claude Plymate
Engineering Physicist
National Solar Observatory ry
http://www.noao.edu/noao/staff/plymate

(c)GoshGusMusic(ascap)2010

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Scherzo Tutti: Symmetry Violation

Our resident physicist & occasional guest columnist Claude Plymate offers something for our lazy summer brains to consider.

Symmetry Violation

There is something very strange about the universe we live in and the evidence is quite literally all around us. Go ahead, look around. What do you see? Stuff. Everywhere, stuff. Now that might not seem all that profound at first until you think about the conditions in the very early universe. In the smallest fraction of a second after the Big Bang, the entire Universe was compacted into a tiny volume. All the energy in the Universe was contained it this minuscule space. The temperature was so extreme that matter couldn’t yet even exist! The immense energy density would cause material to spontaneously pop in and out of existence. As the Universe expanded, energy was spread over a greater volume and the temperature dropped. Matter & antimatter began to condense out but would pair up and annihilate almost immediately.

Now we were taught that matter & antimatter are exactly symmetric differing only in the sign of some of their parameters, such as charge and spin. It would seem, therefore, that they should have been produced in equal quantities. But obviously this was not the case. After all the matter & antimatter paired up and converted back to energy, there was a small residual amount of matter left over – all the stuff you see around you! All matter we see today is a result of this minor excess in production of matter over antimatter. Apparently, our Universe has a slight proclivity for stuff versus anti-stuff. The fact that more matter was originally produced is what is known as a symmetry violation. (Specifically CP-violation. “C” for charge conjugate and “P” for parity meaning the particles are mirror images of each other.)

Why there is a preference for stuff over anti-stuff isn’t really understood. As a physicist, it would be more satisfying to have a nice simple symmetric universe but without this complication, the Universe would be a very bland place without any matter to look at, or for that matter, no “you” to look at it. It seems quite profound how perfectly CP-violation is tuned to allow a universe so well suited for things like us to exist. Many might see this as an example of intelligent design by some omnipotent deity. It is all too easy to come to such a conclusion. But, must such remarkable-seeming coincidences require invoking the supernatural? Some might argue “what else could it be?” Not at all if you assume ours is not the only Universe, only one amongst an unimaginably huge and diverse multiverse. It doesn’t matter how unlikely the combination of parameters are, if you try enough examples, you’ll eventually hit upon the ideal magical seeming mix. And of course, we find ourselves in one of the extraordinarily rare universes that is ideally fine-tuned to allow us to exist. If it weren’t, there wouldn’t be any stuff and wouldn’t be any you to look at it.

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Claude Plymate, Engineering Physicist

National Solar Observatory
http://www.noao.edu/noao/staff/plymate
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(c)GoshGusMusic(ascap)2010