Life Before Oxygen


The gringa would like to share an interesting timeline of the earliest Earth events. Now, ancient history might seem boring but the gringa discovered a very peculiar fact she had never thought about before. There was life on Earth before there was even oxygen! How in the world is that possible? Well, think about it. In order for biological life as we know it to exist on Earth, oxygen must be the second most plentiful  gas in the atmosphere.  In general, the air we breathe is about:

  • 78% Nitrogen
  • 21% Oxygen
  • Less than 1% Argon
  • Less than 1% Carbon Dioxide

To create this winning oxygenated atmospheric recipe on ancient Earth, trees had to be photosynthesizing. But there was stuff living here long before there were trees! How the heck did it survive? Well, let’s look at the timeline first:

  • 4.5 billion years ago (or thereabouts) Earth comes into existence
  • 3.5 billion years ago (or thereabouts) microbes are living on Earth
  • 2.5 billion years ago (or thereabouts) sulfur-eating bacteria is living on Earth
  • 530 million years ago (or thereabouts) fish are living on Earth
  • 400 million years ago (or thereabouts) trees emerged on Earth
  • 230 million years ago (or thereabouts) dinosaurs are living on Earth

So, the gringa wants to know how the heck microbes, bacteria and fish were surviving on an Earth that had, compared to today’s atmospheric standards, a virtually zero oxygen environment. Scientists believe that early Earth’s atmosphere consisted of methane, carbon monoxide, hydrogen sulfide and ammonia.  Earth’s earliest microbes lived in the sediments below the shallows of the planet’s oceans shorelines. They fed and breathed on the sulfur in the atmosphere.  As they absorbed sunlight for energy, they became the first life form to contribute oxygen to the atmosphere through the process of photosynthesis. But shoreline colonies of microbes could by no means contribute oxygen on the same level as vast forests. So oxygen was basically a trace atmospheric gas at this time.

Ancient bacteria ate sulfur and converted hydrogen sulfide into sulfate, which is oxidized sulfur.  Cyanobacteria, commonly called blue-green algae, began to proliferate and also performed a photosynthesis function adding oxygen to the planet’s oceans and atmosphere.

As microbes and bacteria died, they received a burial at sea. Their decomposition also contributed more oxygen to the waters. As the world’s oceans began to become more oxygenated, fish started making their appearance during the Cambrian era. They were typically invertebrate species like jellyfish, worms, crustaceans and molluscs.

Jellyfish diffuse oxygen through their cells. Giant tube worms, that still live in our oceans near underwater volcanic vents, an inhospitable environment for most carbon based life, have a special organ to convert carbon dioxide and hydrogen sulfide into oxygen. Today’s molluscs have a respiratory system that uses gills, just like fish.

And from these strange beginnings, it has been a slow evolutionary crawl to the world we know today. The gringa is amazed. We all owe our lives to the humble microbe and smelly sulfur. Fascinating. But where did microbes come from? Did they simply just “appear” out of thin air? Could they have originated from another planet, arriving here by accident or delivered on purpose by ancestral aliens? Let’s look at planets that had similar atmosphere’s to early Earth, which would have then naturally been a likely choice for microbes looking for a new home:

  • Venus has an atmosphere enveloped by sulfuric clouds.
  • Jupiter, Saturn, Uranus & Neptune all have methane and ammonia in their atmospheres, as does Saturn’s moon, Titan
  • Pluto has an atmosphere dominated by carbon monoxide
  • The atmosphere of Mars is 96% carbon dioxide but also has ammonia and hydrogen sulfide

So, the gringa thinks it’s possible that the ancestral microbes we humans evolved from may have originated from outer space. But, over time, a life form evolved that can never naturally survive on the planet of its origins. So much for a homecoming party!

Sources:

www.livescience.com/earliest fossils

www.space.com

forestry.about.com

www.livescience.com/dinosaurs

www.astrobio.net/early atmosphere

www.astrobio.net/oxygen

www2.astro.psu.edu

www.reference.com

www.seasky.org

mollusks.weebly.com

Image Credit:  riaus.tv

 

 

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Life In A Bubble


There are many different reasons to be interested in the science of climate change. Maybe you are a lover of nature, like the gringa. Maybe you are a doomsday prepper, anticipating worldwide failures of critical natural resources necessary for humanity’s survival. Perhaps you are a problem solver, interested in creating solutions to help us all survive. Or you could be an author of science fiction and fantasy and the realities of climate change provide a plethora of creative resources. Whatever the reason, then you will find the possibility of life in a bio-sphere bubble interesting to ponder.

Tucson, Arizona was recently host to an environmental event sponsored by One Young World, a group of leaders in innovative climate change survival solutions, particularly Biosphere 2 (Earth is #1).  The event featured experts in science, international diplomacy, political science and commercial industry who are all interested in humanity’s need for sustainable sources for food and energy. The speakers whom event attendees were, perhaps, most interested in were probably the former astronaut and individuals who have been living in Biosphere 2.

If a person was to take a tour of Biosphere 2, you might be expecting a sterile, technical, enclosed life support environment like the International Space Station. However, you will probably be pleasantly surprised to find a faux ocean the size of an Olympic swimming pool surrounded by a bamboo forest. As you continue exploration, you will stumble across a desert recreation complete with species of ants and cockroaches.

The Biosphere idea was birthed more than two decades ago. In 1991 the dream was realized when eight individuals, four women and four men, donned their uniforms and entered the three acre terrarium smack dab in the middle of an Arizona desert where they would live confined for twenty-four months.

The habitat was constructed thanks to the generosity of a wealthy Texan who wants a place of safe retreat when the Apocalypse crashes down around our ears. He shelled out about $150 mill to recreate miniaturized versions of South America’s rainforest, the African Savannah, and a single ocean. The Biosphereans worked for two years to determine if this earthly microcosm would interconnect, survive and become a self-sustaining world producing oxygen and food.

Beneath the multiple geodesic domes of steel, glass and plastic transplanted nature began to fail the moments the doors were sealed. Precious oxygen was leaking and making its escape to the outside world. Despite the threat of suffocation, the Biosphereans soldiered on. They planted crops near the ocean. A sophisticated underground bellows system created wind. But small crops of oxygen producing plants and man-made breeze were not enough to make the habitat a survivable, much less pleasant, environment. For the sake of science the Biosphereans persevered through two years of oxygen deprivation yet finally called it quits when survival was only possible by pumping in outside-sourced oxygen.

But was this experiment really a failure? Of course not. It was a very valuable learning experience. Think of all the research that was accomplished on learning how vegetation, geography, water and air movement, and fresh water sources can all be successfully recreated and the knowledge of certain mistakes not to repeat in the process.

The Biosphere 2 is not a total physical loss either. The University of Arizona will continue studies on how to succeed in a biosphere lifestyle. Part of the property will be open to the public and re-christened “Land Evolution Observatory”. The university will launch a project that, over the span of a decade, will attempt to perfect the methods the Biosphereans began. The gringa considers these self-sacrificing and brave Biosphereans to be the pioneers of the Millennia.

The Biosphere story also has a romantic twist. The gringa, madly in love with her caveman, loves a good romance and is happy to learn that two of the individuals fell in love during their confinement together and married as soon as they had regained their freedom to the outside world. The couple, speaking to the Tucson audience, explained how profound their sense of inter-connectedness to their environment became. Daily they tracked carbon and oxygen levels, strongly aware that their survival depended on the right balance.  They felt aware, moment by moment, of each breath they took and each CO2 exhalation they made. The reality of the co-dependence the humans, plants, animals and insects all had with one another was always at the forefront of their mind.

When former astronaut Ron Garan addressed the audience, he discussed his six month stint enclosed in the self-sustained environment of the International Space Station. It was a profound experience that increased his environmental awareness and how tiny, fragile and singular our Earth is. His individual life perspective was completely changed as he worked beside the two Russian cosmonauts he shared duties with. Upon his return to Earth, he dedicated himself to collaboration with projects that will promote the survival of humans and the planet we call home. The only planet, mind you, that we have.

He recounted one of his most poignant experiences. It was the moment he returned to Earth. He peeked out the window of the capsule, saw a landscape of rocks, flowers and grass. His immediate mental and emotional response was, “I’m home” despite the fact that this American was actually in Kazakhstan. Once you’ve been off world, any square inch at any spot on the globe is home, regardless of politics, religion, nationality or ethnicity. The gringa finds this philosophy beautiful and inspirational. And I hope that we all figure it out together, how to save our home.

Source & Image Credit:  www.newsweek.com

 

 

Cosmic Spas & Outer Space Mineral Mines


Are NASA and other international space agencies interested in creating colonies on the Moon and various other exotic, cosmic locales? Most certainly. However, not for the nefarious purposes of whisking away the highly educated and financial elite in order to preserve the human race from extinction. What they really want to do is exploit the natural resources of these places.

Humans are a hungry species and their appetites include all sorts of stuff from fruits and vegetables to minerals and ores. Many minerals and ores are not only rare, with few deposits in sundry places around the world, but are also finite in their supply. Once diminished, humans will have to find another source. That’s where asteroids and the Moon come into play.

Asteroids are like one of those grab bags you get as a party favor. You never know what’s inside. Although primarily chunks of ice, tar and dust, they also contain scare minerals and metals. For astronaut mining crews, outer space is full of opportunity, kind of like a mechanic entering an auto junkyard the size of Earth. Best estimates to date believe there are hundreds of thousands of asteroids, some nearly five billion years old, of assorted sizes and shapes from the size of a coffee table to hundreds of miles in diameter (Earth, in comparison, is about 8,000 miles in diameter). With such abundance, if humans can overcome the technological and economical obstacles, we may have a seemingly limitless supply of raw materials available.

The gringa wonders what will happen when that occurs? Will space become filled with flag waving asteroids? Considering even a small asteroid could be valued at many millions of dollars in potential minerals, will countries be zipping about space, hither and yon, planting flags on as many asteroids as possible in a territory game of, “Mine! I found it first!”? The gringa is hoping it will be much more civilized than that.

For mining purposes, asteroid’s are classified according to three groups based on light reflection (spectral) analysis. Since mankind cannot yet land on an asteroid and physically take a geological sample or do so with a robotic satellite, scientists evaluate how light reflects off the surface of an asteroid to determine its primary mineral component.

C-type asteroids are dark and carbon based. They are comprised of clay based minerals that have lots of water trapped within the clay. The gringa thinks these could, perhaps become cosmic spas if we could find a way to generate some kind of thermal reaction within the asteroid. Think of it, “Come visit asteroid XP-247 for its relaxing steam baths and mineralized clay body and facial wraps. Just don’t forget your oxygen mask.”

But what about the carbon and other stuff in the clay? Is that any good for anything? Yep. It makes a garden grow lush, thick and plentiful. C-type asteroids rich in carbon, phosphorous and other elements in the fertilizer spectrum could be very valuable as future garden spots. The gringa can now see the cosmic version of the “Hanging Gardens of Babylon” where visitors can also get a soak in the hot springs and a beautifying and detoxifying mineral rich clay body wrap.

I mean, really, we have plenty of clay and carbon and water here on Earth but surely there will be an eager entrepreneur who will see the same potential. Or do we really have plenty of clay, minerals and water on Earth?

The water reserves could very well come in handy. The gringa can see it now – a gravity beam lassos a water rich C-type asteroid and hauls it near Earth’s atmosphere. It then uses transporter technology that has finally been perfected to zap it through the atmosphere, avoiding a friction filled entry that would evaporate up all that precious water. Then, as it approaches fatefully close to a desert region, just before impact a precision laser beam goes, “ZIP, ZAP, ZOOM!” and a lovely shower of water rains down upon the desert with all the pulverized clay and carbon providing rich fertilizer. The desert is soon a fertile oasis. Hey, it could happen. Stranger things already have.

But NASA thinks the real value of water rich asteroids is in using the resource in outer space. By finding a way to mine the water in flight, crews could save billions of dollars by not having to pack this life-support necessity. Interestingly enough, the very thing that humans need to survive, consisting of two molecules of hydrogen and one of oxygen, are the very elements of rocket fuel. (Wow, humans are 60% rocket fuel, or, water, depending on your perspective!). So, astronauts dock their spaceship at a galactic version of Exxon to fill up the tank and top off the water reserves. And while the service station is checking the engine’s oil level and cabin’s air pressure, the crew is freshening up at the nearby spa. Interesting.

So, C-type asteroids can either be Desert-to-Eden conversion sources, hot spring spas, water wells, or rocket fuel depots. Or all three at the same time.Take your pick.

S-type asteroids shine a little brighter than dark, carbon based C-types. That’s because they are rich in reflective metals like cobalt, iron and nickel. If a mining crew is really lucky they could find one with deposits of rhodium, platinum or gold. Scientists estimate that an asteroid about the size of an average bedroom could be packed with well over one million pounds of metals, a tiny fraction being the exceedingly valuable rare ones. Even if mining crews could extract just one hundred pounds of platinum, at about $1000 an ounce, a $100,000 load of platinum would just be the gravy on top of the wealth accumulated from the remaining predominant minerals.

But it may be the M-class asteroids that wars end up being fought over. The wars for oil that we have raging now could very well become wars for M-class asteroids in the future. These asteroids are expected to contain at least ten times the mineral content of S-types.

To make space mining a reality, the mission has to be profitable. With current missions costing in the hundreds of millions, some even billions, an asteroid would have to be massively rich in raw materials. The other option is to develop technologies that are more economical.

Before any of that even matters, current asteroid knowledge needs to be vastly broadened and fine-tuned. We need cosmic cartographers to accurately map the hundreds of thousands of asteroids in outer space. The world needs space geologists that have the technology and knowledge to analyze what minerals each asteroid actually contains. Young students now, who have an interest in a cosmic career, could really have a geology or cartography degree pay off by landing them their dream job.

NASA’s first effort to test their scientific mettle for determining present mineral resources within an asteroid lie with their OSIRIS-REx mission. The goal of “Origins, Spectral Interpretation, Resource Identification, Security and Regolith Explorer” is to return with a geological sample from asteroid Bennu. It is set to launch in September and arrive at the asteroid almost two years later. If all goes according to plan, Earthlings can expect an authentic piece of Bennu to arrive on planet Earth around 2020. (Of course, the gringa is reminded of her favorite piece of motherly advice given regularly to her children in efforts to cultivate a more relaxed approach to life, “The plan is that nothing goes according to plan.”)

In addition to geological studies of Bennu’s raw materials, asteroid re-direction technologies will also be studied. The spacecraft is scheduled to perform an interesting experiment. It is going to give Bennu a gentle, solar nudge. Scientists want to know if sunlight can be used to affect the path of travel of asteroids. I guess the reasoning is that asteroids are too valuable to simply blast into oblivion if Earth happens to be in the way. They would rather nudge them aside then attempt to exploit the wealth they contain.

The most important goals of the mission, however, are to further the development of space mining technologies. They plan to scrape together a two ounce and 4.4 pound geological sample. The spacecraft will then use its state-of-the-art instruments to map the surface of Bennu and analyze its composition. These are the on-board technologies and their purposes:

  • OVIRS (OSIRIS-REx Visible and Infrared Spectrometer) – analyzes visible and near-infrared light to detect minerals, compounds and chemicals within the asteroid.
  • OTES (OSIRIS-REx Thermal Emission Spectrometer) – analyzes infrared light to detect surface minerals of Bennu, determine surface temperature and map the location of water-rich clay mineral deposits.
  • REx (Regolith X-ray Imaging Spectrometer) – analyzes X-ray aura of Bennu’s surface in sunlight to calculate amounts and locations of elements like: iron, magnesium, silicon and sulfur.

To find out if sunlight can be used as an asteroid diversion technique OVIRS and OTES will combine their abilities to study what is known as the “Yarkovsky effect”. When an asteroid absorbs sunlight much of the heat radiates outward and provides a propelling effect. Observations will be made to see if a “man-made” solar heat saturation could result in changing an asteroid’s trajectory.

Most of what will be recorded by the different spectrometers will only reflect what is on Bennu’s surface and within a shallow depth (about half a millimeter). They are not capable of reaching deep within the asteroid’s core. To get a deeper look the spacecraft has a tool that blows nitrogen gas onto the surface that will force minerals up from a depth of about two inches. Even so, it’s pretty obvious that much about Bennu will remain unknown even if the mission is successful in achieving all of its goals.

But, a successful mission will at least tell the world one thing: can mining asteroid’s work? The gringa believes if great wealth is at stake there will be movers and shakers in this world who will make it work one way or another while pocketing a healthy profit in the process.

Source & Image Credit:  www.nasa.gov

 

 

 

 

 

Breaker One-Nine, SOS, FRB’s & ETs


Dot dot dot-dash dash dash-dot dot dot. Dear readers, do you know what that is? It is SOS in Morse Code. All radio operators know this. It is an understood code that crosses all language barriers. The gringa, fascinated with all things space, then has to ask, does this include extra-terrestrials? Well, who knows?!

Now, the SETI Institute (Search for Extra-Terrestrial Intelligent Life) doesn’t really make it a practice to emit signals in their search for ETs, rather, they listen to outer space “noise”. NASA’s search for extra-terrestrial life isn’t so much for little green men to have a conversation with, but, rather, the origins of life such as amino acids, ribonucleotides (RNA) and certain gases such as oxygen, methane, ammonia, hydrogen, and, of course, water.

However, Earthlings have been inadvertently sending out all sorts of signals into space for over five decades. As technological devices fill the Earth, transmission signals fill the heavens: radio broadcasts, television signals, radar blips and bleeps, etc. So, why do we not purposely send a message designed to create a favorable first impression rather than let all this mish-mash represent humankind? Does NASA and SETI believe that no one exists, thus no one is listening or do they believe there may be inherent danger in seeking out contact? Evidently the reason is because there is no consensus, yet, within the scientific community. The professionals are ARGUING. Hmph.

Douglas Vakoch, a researcher with SETI, thinks that it may be time to have an international discussion on the subject and let the public’s opinion on the matter be heard. He is on the pro-sending signals side of the argument. He proposes transmitting radio signals to hundreds of stars within eighty-two light years of our home planet. This can be accomplished with the radio telescope at Arecibo Observatory in Puerto Rico.

Renowned physicist, Stephen Hawking, on the other hand, thinks this is a bad idea. By sending out so many signals to every Tom, Dick and Harry alien out there, we could communicate with the good, the bad and the ugly. He believes we should be much more cautious in our approach.

So, it seems that, although there is no consensus within the scientific community on whether or not we should initiate communication, there is a consensus that somewhere out there is intelligent life that would not only receive the signals, but would be capable of responding, perhaps in person. The gringa says, “Hmmm.”

Now, the telescope at Arecibo has already sent a space message back in 1974. Consisting of an intricate code, it was transmitted to a cluster of stars 25,000 light years away.

The Crimeans sent out four messages to the cosmos from 1999 until 2008. They were transmitted from the Yevpatoria RT-70 radio telescope at Crimea’s Center for Deep Space Communications. Their ET messages were entitled: “Cosmic Call”, “Teen Age Message”, “Cosmic Call 2”, and “A Message From Earth”. The messages were made up of binary code, repeating signals, musical compositions, photographs, whale songs, etc.

Scientists believed that it is important to purposely beam thoughtful messages into deep space rather than let ETs believe all Earthlings are like the Kardashians, or the Zodiac killer, or Archie Bunker. Although Earthlings have been flooding outer space with signals since the beginning of the television era, most of our daily technologies do not have signals that are sufficiently strong enough to be picked up by our nearest living ET neighbors’ light years away. Although, if they are advanced enough, they have probably detected something by now.

So, if SETI and the Crimeans have already sent out some transmissions, the gringa then wonders, “What’s the big deal about sending more?” And, if our own daily barrage of digital signals and radio waves have the possibility of already being detected, what’s the point of “laying low”? If an ET civilization is super advanced to the point they could easily dominate us, yet they haven’t shown up and taken over, why be so worried? It seems they could care less.

The gringa thinks the real reason why the scientists can’t stop arguing and just get to the business at hand is an age old reason. Power struggle. Tsk, tsk. How disappointing. The gringa believed that surely, of all human beings, scientists were above such nonsense. As scientists consider the possibility of the most ground-breaking and historical event EVER playing out, they eye one another suspiciously and wonder just who is going to get the credit. Yes. Exactly who gets to devise the message, approve it and send it as the representative of the entire Earth?!

So, although there are researchers who want to open up the subject to public debate, that also opens it up to the general host of problems that goes along with human nature. Venturing into the area of communicating with an alien race would mean the establishment of protocols. Who gets to decide who we Earthlings talk to and what we talk about?

Although SETI wants to actively transmit in hopes of communicating with extra-terrestrials, the official policy of the institute is that the final decision belongs to the people of Earth. Such a decision affects all humans. It could be the single-most life affecting decision for mankind. Therefore, it should be left in the hands of all the people and not just a few “experts”.

Many other leaders in the space exploration community are in agreement, such as former Senior Scientist for Astrobiology in NASA’s planetary protection office, John Rummel and SpaceX founder, Elon Musk. Pioneering American astronomer, Geoff Marcy, who has discovered many “extrasolar” planets, believes it is important that every culture, even deep jungle indigenous peoples, upon Earth have the opportunity to have their voices heard in such a decision that will affect every person worldwide.

The discussion on this issue will probably continue to heat up because, recently, some interesting radio signals have been detected by astronomers who have been left scratching their heads and wondering if they could, perhaps, be a signal from intelligent beings, seeing that, like one of our own repeated signal transmissions, this signal also repeated itself.

If a repeating signal has been detected in deep space, could it have other origins than intelligent beings purposely transmitting? Canadian scientist Paul Scholz finds the mystery rather exciting and believes this to be an important discovery and wants to know if the signals originated with living, breathing ETs or if a star just went “kaplooie” and it’s just a “coincidence” that it created a shockwave noise that mimics a man-made (or little green man-made) artificial, repeating signal.

Until the signals began repeating, scientists theorized the rapid bursts of radio signals resulted from a star that went supernova and exploded or, perhaps, a neutron star collapsing into a black hole. But, now that the signals are identical and repeating, the same scientists don’t quite know what to think.

In addition to a repeating pattern, there are other singular differences that set the signals apart from other space “noise”. When studied further, the signals are “brighter” and in a different “spot” on the “spectrum” of other fast radio burst signals (FRBs). These details are all well and good, but all the gringa wants to know is, “Are we alone or not?”

The closest I can get to a straight answer is what a Cornell University astronomy professor has to say. According to Professor James Cordes, whatever charge is powering the signal, it is powerful enough to repeat the signal cycle within minutes. The energy packed behind the transmission must be impressive because they are extraordinarily bright, thus enabling us to see them from very, very, very, very, far away. And, the power source must also be incredibly secure and amazingly strong and durable because it is not destroyed by the transmission of an exploding-star-scale blast and is capable of repeating the exploding-star-scale blast.

To put all of this in a nutshell, five fast radio burst signals were captured by the Parkes radio telescope in New South Wales, Australia. Rather than just be a single burst of energy, these are double bursts, two bursts separated by 2.4 milliseconds, consistently. They repeated five times. The origins of the signals could be as far away as several billion light years beyond the Milky Way Galaxy, our home turf in the cosmos.

The gringa has no answer and remains intrigued. And my vote is that we send our own signals.

 

 

Sources: http://www.ewao.com, http://www.seti.org, http://www.nasa.gov

Image Source:  www.dailymail.co.uk

 

 

 

 

Warming Lakes & Rivers = Trouble


It’s pretty easy to find climate change articles discussing the changes that are taking place in the world’s oceans. But, the gringa asks, what about the lakes and rivers of the Earth?

I grew up on a river. I love rivers. I love canoeing and floating down rivers on tubes and camping out alongside the banks of a river. What’s happening with these rivers I love? And what about lakes? Every summer we take a traditional three day weekend family trip to one of the most beautiful lakes in Texas. What’s happening to this fabulous lake? Unfortunately, the research shows that these are all changing as well.

NASA’s response to this change is to create a “global water cycle budget”. It covers a ten year period of the Earth’s freshwater concerns. This will be the baseline by which future “global water cycle budget’s” will be compared.

The water cycle involves the entire environmental process of how water moves, in all forms, around this big, blue planet. As depicted in the image posted it is easy to trace how water evaporates from the surface of the Earth. As it rises into the atmosphere it cools, condenses into clouds, then returns to the Earth as precipitation (rain, snow, hail,  or sleet). This is the kind of science the gringa learned in elementary school but it is, perhaps, the most critical environmental cycle for the continuation of life on Earth.

From the year 2000 until 2010 NASA collected satellite data  to estimate how much energy from the sun was required to move water. Hotter days means more evaporation of water within the soil. More evaporation means more moisture in the winds that transport this moisture throughout the world. Because the Earth is a closed system, any water that evaporates from its surface can be accounted for in the water vapor that eventually accumulates in the atmosphere. It’s kind of like taking a jar of pennies to the bank and getting dollars in return. It’s an even exchange of the same thing, money, but it exists in two different forms, pennies or bills. Water on Earth is the same. It’s either here on Earth as water or in the atmosphere as a form of precipitation.

However, the water model is a bit more complicated. Consider that each penny represents a different data set concerning where the water is specifically located, formed, or used. Such as: ocean, lake, evaporation from soil and plants, streams, rivers, human consumption. To help scientists manage all of this data they divide the Earth into seven land masses (Eurasia, South America, North America, Africa, Antarctica, Mainland Australia, Oceania/New Zealand/Tasmania) and nine ocean basins (North Pacific, South Pacific, Indian, North Atlantic, South Atlantic, Caribbean, Mediterranean, Arctic, Black Sea).

Over two dozen satellites provide scientists with data concerning precipitation and evaporation over the land masses and oceans. Researchers can track the movement of atmospheric water vapor, river runoff, groundwater reservoirs, soil moisture and snowpacks.

These important studies have already determined that lakes around the world are warming. This warming trend is affecting the ecosystems they are a part of as well as threatening the security of adequate freshwater supplies.

To come to the conclusion that lakes are warming, NASA used a twenty-five year compilation of data of ground measurements of over 200 lakes on six separate continents. On average, the lakes are warming about half a degree Fahrenheit every decade. Some lakes, the ones at higher latitudes, are warming even faster, one whole degree Fahrenheit per decade. That means that freshwater lakes are warming faster than the oceans.

As lakes warm, algal blooms increase. These rob the oxygen in the water from the fish. NASA’s models predict a twenty percent increase in these toxic algal blooms over the next century. Not only will this result in a chain reaction within the ecosystem wiping out the fish, as well as the wildlife and fauna that depend on those fish, but the blooms will also increase greenhouse gas emissions. Algal blooms are expected to produce methane emissions that will increase four percent over the next decade unless we Earthlings come up with a solution.

Solving the lake warming problem is a very important component of solving the climate change problem because methane emissions are 25 times more powerful than carbon emissions. A massive worldwide increase of algal blooms in freshwater lakes is a disaster we cannot allow to happen.

If the world’s lakes become a casualty of climate change, it won’t just be an environmental disaster, it will be a humanitarian disaster. These are important sources for drinking water, crop irrigation, and the production of food fish that are an important protein source for vulnerable populations around the world. Some researchers are already detecting evidence that productivity in warming lakes is already declining.

Out of the 37 largest aquifers on Earth, 21 are already past the sustainability tipping point and are being depleted. Another 13 are classified as “significantly distressed”. Eight are classified as “overstressed”. “Distressed” and “overstressed” means that these water sources have no natural replenishment to offset consumption. Five more were classified as “extremely stressed”, being depleted but with some replenishment occurring.

These were the conclusions of NASA’s study of ten years of data from the GRACE satellites. The GRACE satellites measure how Earth’s gravity is affected by existing masses of water. What NASA reports is alarming and difficult for the gringa to swallow, even with a glassful of water. That means that almost one third of our world’s groundwater is rapidly disappearing. And what’s even scarier is there is no reliable data that can predict just exactly when these wells will run dry. Yet, we continue to consume rather than conserve.

One of these overstressed reservoirs is the Arabian Aquifer System. It sustains over 60 million people. If we think there’s trouble in the Middle East right now over regional power struggles and the global fight to dominate the oilfields for profit, what the heck can we expect to see when these people have nothing left to drink? What kind of mass exodus will occur when that happens? This is a problem that must be solved. When climate change deniers scoff at the idea that climate change is the single most issue that threatens the national security of all peoples, they have no idea what they are talking about.

If Americans thought the California and Texas droughts were painful, consider what could occur in India and Pakistan, home to the second-most overstressed aquifer, the Indus Basin. Then there’s the third most overstressed water source, the Murzuk-Djado basin in north Africa. These regions are home to almost two billion people! Think about the Syrian refugee crisis. We ain’t seen nothin’ yet.

While working toward a solution, scientists cannot agree on any projected timeline of “time to depletion”. And when the gringa says they cannot agree, I’m talking about discrepancies of warnings of ten years to twenty-one THOUSAND years! However, one thing that these scientists DO agree on is that in a water-scarce society that is water dependent, this kind of ignorance is intolerable. Well, the gringa is glad to hear that.

Because groundwater reservoirs are so deep beneath the surface of the Earth, the only method to accurately measure just how much is down there is to drill, baby, drill. It’s gonna cost a lot of money, but the experts say it has to be done. NASA is committed to using its technology, personnel and data to help secure mankind’s future and improve lives around the world. By sharing knowledge freely with scientists around the world, the agency hopes to increase understanding that will lead to solutions.

The gringa waits to hear NASA’s announcement of a challenge like “Dig A Hole, Save The Planet”. The gringa has every confidence that NASA will continue to lead the charge to save us Earthlings from ourselves and the messes we continue to make. These challenges are simply a way for us to redeem ourselves after making such awful messes.

Source & Photo Credit: www.nasa.gov