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Lead humanity forward. <i>Two possibilities exist:</i> <i>Two possibilities exist: either we are alone in the universe,</i> <i>Two possibilities exist: either we are alone in the universe, or we are not.</i> <i>Two possibilities exist: either we are alone in the universe, or we are not.
Both are equally terrifying.</i> <i>Two possibilities exist: either we are alone in the universe, or we are not.
Both are equally terrifying.</i>
Arthur C. Clarke <i>Two possibilities exist: either we are alone in the universe, or we are not.
Both are equally terrifying.</i>
Arthur C. Clarke
In all of time, In all of time, on all the planets of all the galaxies in space. what civilizations have risen, looked into the night, seen what we see, asked the questions that we ask? "Are we alone?" "Is Earth the only chapter in the story of life?" "The answers lie somewhere in distant space - and distant time." "For the first time, the truth is finally within our reach." "The search will reveal who we are" "and who we might become." LIFE LIFE BEYOND <b>CHAPTER I</b> <b>CHAPTER I</b>
The Dawn "In the search for life out there, we must first look inward." What we see around us is staggering complexity. How is it possible? "What does it take to create life?" "What does it take to create life?"
Living organisms are created by chemistry. Living organisms are created by chemistry. We are huge packages of chemicals. And what are the ideal conditions for chemistry? Well, first, you need energy. <b>I</b>
Well, first, you need energy. <b>I
E</b>
Well, first, you need energy. <b>I
EN</b>
Well, first, you need energy. <b>I
ENE</b>
Well, first, you need energy. <b>I
ENER</b>
Well, first, you need energy. <b>I
ENERG</b>
Well, first, you need energy. <b>I
ENERGY</b>
Well, first, you need energy. <b>I
ENERGY</b><i>
e.g </i>
Well, first, you need energy. <b>I
ENERGY</b><i>
e.g Sunlight,</i>
Well, first, you need energy. <b>I
ENERGY</b><i>
e.g Sunlight,</i> <b>I
ENERGY</b><i>
e.g Sunlight, Geothermal Heat</i> <b>I
ENERG</b><i>
e.g Sunlight, Geothermal Heat</i> <b>I
ENER</b><i>
e.g Sunlight, Geothermal Heat</i> <b>I
ENE</b><i>
e.g Sunlight, Geothermal Heat</i> <b>I
EN</b><i>
e.g Sunlight,</i> <b>I
E</b><i>
e.g</i> <b>I
E</b> <b>I</b> But not too much. What you want is just the right amount and planets it turns out are just right, because they are close to stars, but not too close. You also need a great diversity <b>II</b>
You also need a great diversity <b>II
HE</b>
You also need a great diversity <b>II
HEA</b>
You also need a great diversity <b>II
HEAV</b>
You also need a great diversity <b>II
HEAVY</b>
You also need a great diversity <b>II
HEAVY E</b>
You also need a great diversity <b>II
HEAVY EL</b>
You also need a great diversity <b>II
HEAVY ELE</b>
You also need a great diversity <b>II
HEAVY ELEM</b>
You also need a great diversity <b>II
HEAVY ELEME</b>
You also need a great diversity <b>II
HEAVY ELEMEN</b>
You also need a great diversity <b>II
HEAVY ELEMENT</b>
You also need a great diversity <b>II
HEAVY ELEMENTS</b>
You also need a great diversity <b>II
HEAVY ELEMENTS</b><i>
e.g</i>
of chemical elements. <b>II
HEAVY ELEMENTS</b><i>
e.g Oxygen,</i>
of chemical elements. <b>II
HEAVY ELEMENTS</b><i>
e.g Oxygen, Carbon,</i>
of chemical elements. <b>II
HEAVY ELEMENTS</b><i>
e.g Oxygen, Carbon, Sulfur</i>
of chemical elements. <b>II
HEAVY ELEMENTS</b><i>
e.g Oxygen, Carbon, Sulfur</i> <b>II
HEAVY ELEMENT</b><i>
e.g Oxygen, Carbon, Sulfur</i> <b>II
HEAVY ELEMEN</b><i>
e.g Oxygen, Carbon, Sulfur</i> <b>II
HEAVY ELEME</b><i>
e.g Oxygen, Carbon,</i> <b>II
HEAVY ELEM</b><i>
e.g Oxygen, Carbon,</i> <b>II
HEAVY ELE</b><i>
e.g Oxygen, Carbon,</i> <b>II
HEAVY EL</b><i>
e.g Oxygen,</i> <b>II
HEAVY E</b><i>
e.g</i> <b>II
HEAVY</b> <b>II
HEAV</b> <b>II
HEA</b> <b>II
HE</b> <b>II
H</b> <b>II</b> <b>I</b> And you need liquid, such as water. <b>III</b>
such as water. <b>III
L</b>
such as water. <b>III
LI</b>
such as water. <b>III
LIQ</b>
such as water. <b>III
LIQU</b>
such as water. <b>III
LIQUI</b>
such as water. <b>III
LIQUID</b>
such as water. <b>III
LIQUID</b>
such as water. <b>III
LIQUID</b><i>
e.g</i>
such as water. <b>III
LIQUID</b><i>
e.g Water</i>
such as water. III<b>
LIQUID</b>
e.g. water Why? Well, in gases, atoms move past each other so fast that they can't hitch up. In solids, atoms are stuck together. They can't move. In liquids, they can cruise and cuddle and link up to form molecules. Liquid water is just so good for getting evolution going. Molecules can dissolve in the water to form more complex chains. Now, where do you find such goldilocks conditions? Well, planets are great, and our early Earth was almost perfect. Earth Earth
4 Billion Years Ago It was just the right distance from its star to contain huge oceans of liquid water. And deep beneath those oceans, at cracks in the Earth's crust, fantastic chemistry began to happen atoms combined in all sorts of exotic combinations. "The exact recipe is still a mystery, but the ingredients for life
are simple - energy, organic molecules, and liquid water." "Somewhere in the seas of early Earth, basic chemistry
became biology - perhaps even more than once." "The first cells were likely born in hot volcanic waters,
in conditions once thought impossible for biology." "The closer we study life, the more extreme places we find it thriving." "The closer we study life, the more extreme places we find it thriving."
Here on our planet, Here on our planet, microbes have adapted to survive the most hostile conditions. Arid deserts, the frozen Himalayas, in trenches under thousands of tons of pressure in the ocean deeps. In the vacuum of a space simulator, life forms have been flourishing for years without oxygen. "New research suggests that life emerged over 4 billion years ago,
when Earth was an alien and deadly place." "The planet was ravaged by intense volcanism
and an asteroid storm that lasted 100 million years." "Yet even in these extreme conditions,
life quickly found a foothold." "Yet even in these extreme conditions,
life quickly found a foothold."
Very very quickly, Very very quickly, as soon as the Earth cooled off after its formation, we know that life began here. Because it happened quickly here on Earth, we think it is going to happen quickly on other planets as well. "The story of Earth gives us hope that life could be universally common." "It teaches us that life is fast acting, tenacious,
and made of basic, common ingredients." "After 4 billion years of isolation,
the search for our cosmic kin has finally begun." "Where there is water, there is life - and so our best chance
is to look for ocean worlds like Earth." "Our search for Earth-like planets has only just begun,
and the findings are tantalizing." <b>KEPLER-62F</b> <b>KEPLER-62F</b>
Distance: 1200 Light Years. <b>KEPLER-62F</b>
Distance: 1200 Light Years.
Size: 1.4x Earth. <b>KEPLER-62F</b>
Distance: 1200 Light Years.
Size: 1.4x Earth.
Temperature: ≥ -85ºF. <b>KEPLER-62F</b>
Distance: 1200 Light Years.
Size: 1.4x Earth.
Temperature: ≥ -85ºF.
Age: ~7 billion years. <b>KEPLER-62F</b>
Distance: 1200 Light Years.
Size: 1.4x Earth.
Temperature: ≥ -85ºF.
Age: ~7 billion years.
Possible Water World <b>KEPLER-62F</b>
Distance: 1200 Light Years.
Size: 1.4x Earth.
Temperature: ≥ -85ºF.
Age: ~7 billion years. <b>KEPLER-62F</b>
Distance: 1200 Light Years.
Size: 1.4x Earth.
Temperature: ≥ -85ºF. <b>KEPLER-62F</b>
Distance: 1200 Light Years.
Size: 1.4x Earth. <b>KEPLER-62F</b>
Distance: 1200 Light Years. <b>KEPLER-62F</b> <b>TRAPPIST-1D</b> <b>TRAPPIST-1D</b>
Distance: 41 Light Years. <b>TRAPPIST-1D</b>
Distance: 41 Light Years.
Size: 0.77x Earth. <b>TRAPPIST-1D</b>
Distance: 41 Light Years.
Size: 0.77x Earth.
Age: ~7.5 billion years. <b>TRAPPIST-1D</b>
Distance: 41 Light Years.
Size: 0.77x Earth.
Age: ~7.5 billion years.
Temperature: ≥ 20ºF. <b>TRAPPIST-1D</b>
Distance: 41 Light Years.
Size: 0.77x Earth.
Age: ~7.5 billion years.
Temperature: ≥ 20ºF.
Possible Water World <b>TRAPPIST-1D</b>
Distance: 41 Light Years.
Size: 0.77x Earth.
Age: ~7.5 billion years.
Temperature: ≥ 20ºF. <b>TRAPPIST-1D</b>
Distance: 41 Light Years.
Size: 0.77x Earth.
Age: ~7.5 billion years. <b>TRAPPIST-1D</b>
Distance: 41 Light Years.
Size: 0.77x Earth. <b>TRAPPIST-1D</b>
Distance: 41 Light Years. <b>TRAPPIST-1D</b> <b>TEEGARDEN-B</b> <b>TEEGARDEN-B</b>
Distance: 12 Light Years. <b>TEEGARDEN-B</b>
Distance: 12 Light Years.
Size: 1.07x Earth. <b>TEEGARDEN-B</b>
Distance: 12 Light Years.
Size: 1.07x Earth.
Age: 8 billion years. <b>TEEGARDEN-B</b>
Distance: 12 Light Years.
Size: 1.07x Earth.
Age: 8 billion years.
Minimum temperature: ≥ 20ºF. <b>TEEGARDEN-B</b>
Distance: 12 Light Years.
Size: 1.07x Earth.
Age: 8 billion years.
Minimum temperature: ≥ 20ºF.
Possible Water World <b>TEEGARDEN-B</b>
Distance: 12 Light Years.
Size: 1.07x Earth.
Age: 8 billion years.
Minimum temperature: ≥ 20ºF. <b>TEEGARDEN-B</b>
Distance: 12 Light Years.
Size: 1.07x Earth.
Age: 8 billion years. <b>TEEGARDEN-B</b>
Distance: 12 Light Years.
Size: 1.07x Earth. <b>TEEGARDEN-B</b>
Distance: 12 Light Years. <b>TEEGARDEN-B</b> <b>K2-18B</b> <b>K2-18B</b>
Distance: 111 Light Years. <b>K2-18B</b>
Distance: 111 Light Years.
Size: 2.7x Earth. <b>K2-18B</b>
Distance: 111 Light Years.
Size: 2.7x Earth.
Temperature: -100 -116ºF. <b>K2-18B</b>
Distance: 111 Light Years.
Size: 2.7x Earth.
Temperature: -100 -116ºF.
Confirmed atmospheric water vapor <b>K2-18B</b>
Distance: 111 Light Years.
Size: 2.7x Earth.
Temperature: -100 -116ºF. <b>K2-18B</b>
Distance: 111 Light Years.
Size: 2.7x Earth. <b>K2-18B</b>
Distance: 111 Light Years. <b>K2-18B</b> "We have barely scratched the surface.
Nature's trove of secrets is bottomless." "We have barely scratched the surface.
Nature's trove of secrets is bottomless."
We know that the galaxy is awash in water. We know that the galaxy is awash in water. It’s awash in organic molecules, and complex chemistry. All of the things that we know were necessary for life to begin on this planet exist on abundance throughout the galaxy. Did something similar to what happened on our own planet happen on those other planets? "Looking at the raw numbers, the existence of alien life
seems almost inevitable." "The latest data suggest that up to 1/4 of stars have rocky planets
orbiting in their habitable zone - the right distance for liquid water." "In our Milk Way galaxy alone, that's ~50 billion worlds like Earth." "In the entire universe, the possible number of habitable planets is staggering:" "In the entire universe, the possible number of habitable planets is staggering:"
100,000,000,000,000,000,000. "Imagine each flash of light represents an Earth-like planet." "You would have to watch this animation for over a billion years to view them all." "Each one with a history as rich and unique as Earth." "Trillions and trillions of chemical soups, stewing for eons." There are more habitable Earth-mass planets in the observable volume of the universe than there are grains of sand on all the beaches on Earth. "Among this abundance of worlds,
many will be deadly to life as we know it." "There will be planets in the habitable zone that are
scorched, frozen, and suffocated by poison gases." "Many will lack an atmosphere, critical for temperature regulation,
or have one that is deadly." "Venus, once thought to potentially support life,
is now sterilized by a crushing, toxic atmosphere." "But life may not be confined to the habitable zone." "Far from the warmth of their star, the moons
of giant gas planets may be hidden oases for life." "Their energy comes not from starlight, but from gravity -
the lurching push and pull of the host planet." "Icy Enceladus has it all: a huge subsurface ocean
with hydrothermal vents spewing the chemistry of life." "Titan is especially alluring - larger than Mercury
and speckled with methane lakes and organic compounds." "In 2026, NASA plans to send a drone to Titan,
seeking out signs of life in its valleys and craters." "There may be 100 trillion exomoons in our galaxy alone -
100 times the number of planets." "Some may even be Earth sized,
with atmospheres and surface water." "With so many places to find life, it seems only a matter of time
before we make a discovery." "Some think we already have." "On June 30, 1976, the Viking lander on Mars
found something that still remains unexplained." "After being injected with nutrients, Martian sol samples
expelled signature radioactive gas - just like soils from Earth." Sterilized Soil | Sterilized Soil | Sterilized Soil | Sterilized Soil | California Soil | Martian soil "Was this signal a natural phenomenon, or our first
encounter with alien biology?" The discovery of just one bacteria on Mars, or any other body of the Solar System would indicate that the whole chain of evolutions. Cosmic, chemical and biological, is at work everywhere. In that case, the creation of life anywhere in the universe would be more the rule than the exception. "If we haven't found life already, it may not be long until we do." "NASA scientists now think we are on the verge of discovery." "NASA scientists now think we are on the verge of discovery."
Within all of our lifetimes we're going to understand "NASA scientists now think we are on the verge of discovery."
that there is life on other bodies in the Solar System. that there is life on other bodies in the Solar System. We're going to understand the implications of that for evolution of life here on Earth. We're going to find planets around other stars that we can say we see potential signs of habitability in their atmospheres. That's all going to happen in the next 10 to 20 years. How exciting is that? We're on the verge of things that the people have wondered about for millennia: "Are we alone?" And here we are on the verge of finding that out. "If we do find life out there, what will we discover about ourselves?" "What chapter is Earth in the story of life?" The universe is nearly 14 billion years old. And our galaxy is something like 12 billion years old. So, there could be life out there that could be dramatically more advanced than the life that we have here on this planet. "Is Earth a latecomer on the cosmic stage?" "Just how ancient could life be?" 100 Thousand Years Ago 1 Million Years Ago 5 Million Years Ago 10 Million Years Ago 50 Million Years Ago 100 Million Years Ago 200 Million Years Ago 300 Million Years Ago 400 Million Years Ago 500 Million Years Ago 1 Billion Years Ago 2 Billion Years Ago 3 Billion Years Ago 4 Billion Years Ago 5 Billion Years Ago 10 Billion Years Ago 13.8 Billion Years Ago Event: The Big Bang "For its first few million years, the cosmos was too hot for life as we know it." "The ambient temperature would have boiled you alive." Event: The First Star "When it was finally cool enough for life, there were no stars and planets.
Only huge lumbering clouds of hydrogen." "After 70 million years, gravity took hold of these clouds
and spun them into the first generation of stars." "The first stars were massive and bright,
but there was no life to watch them rise." "Vital heavy elements were still being forged in their hot stellar cores.
Not even the Big Bang was hot enough to create them." "Vital heavy elements were still being forged in their hot stellar cores.
Not even the Big Bang was hot enoughto create them."
The only elements that were created on The Big Bang were hydrogen, The only elements that were created on the Big Bang were hydrogen, helium and a little bit of lithium. All the stuff that makes your life livable those elements weren't created on the Big Bang. The only place they were created is in the fiery cores of stars and the only way they could get into your body is if the stars were kind enough to explode. Event: Death And Rebirth "The explosive death of the first mid-sized stars
seeded the cosmos with the ingredients for life." "From their ashes rose a second generation of suns -
this time with rocky planets dancing around them." "This is the moment: the raw ingredients for life together
for the first time, ~13.7 billion years ago." "Some believe the conditions for life existed even earlier, in the warm afterglow of creation." "As the heat from the Big Bang faded,
the universe passed through a goldilocks era." "Some 15 million years after time began,
the ambient temperature reached a balmy 75º F (24º C)." "For millions of years, it was warm in all directions,
like an endless summer day on Earth." "In theory, stars and planets could have formed this early on,
in hypothesized ultra-dense regions of space." "If such regions existed, liquid water could have flowed abundantly,
even on rogue planets far from any star." "Could this have been dawn of life?
Alien beings feeding off the heat of the Big Bang?" "Somewhere out there may be a planet with life
nearly as old as the universe itself." "With a 10 billion year head start, the universe could be teeming with
life far more advanced than our own." "Despite decades of searching, no sign of alien life
has ever been confirmed, intelligent or otherwise." "So where is everybody?" "Could we really be alone?" "Maybe primitive life is common, but intelligence is exceedingly rare." "Maybe space is just too vast for feasible communication." "Or maybe we are the first." "Could we be the opening chapter in a sprawling history of life?" 13.8 Billion Years 14 Billion Years 15 Billion Years 16 Billion Years 17 Billion Years 18 Billion Years 19 Billion Years 20 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 21 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 22 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 23 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 24 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 25 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 30 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 35 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 40 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 45 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 50 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 55 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 60 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 65 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 70 Billion Years
"The universe is young, and the vast majority
of planets have yet to be born." 80 Billion Years 90 Billion Years 100 Billion Years 110 Billion Years 120 Billion Years 130 Billion Years 140 Billion Years 150 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 200 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 250 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 300 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 350 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 400 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 450 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 500 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 600 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 700 Billion Years
"The ingredients for life will be stewing
for another 100,000,000,000,000 years." 800 Billion Years 900 Billion Years 900 Billion Years
"From this perspective, we are the dawn:
the opening melody in a symphony of life." 1 Trillion Years
"From this perspective, we are the dawn:
the opening melody in a symphony of life." 2 Trillion Years
"From this perspective, we are the dawn:
the opening melody in a symphony of life." 4 Trillion Years
"From this perspective, we are the dawn:
the opening melody in a symphony of life." 8 Trillion Years
"From this perspective, we are the dawn:
the opening melody in a symphony of life." 16 Trillion Years
"From this perspective, we are the dawn:
the opening melody in a symphony of life." 32 Trillion Years
"From this perspective, we are the dawn:
the opening melody in a symphony of life." 32 Trillion Years 64 Trillion Years 70 Trillion Years 80 Trillion Years 90 Trillion Years 95 Trillion Years ~100 Trillion Years Later Event: Last Star Dies
~100 Trillion Years Later "What might come long after us?" "Red dwarf stars can live up to 10 trillion years,
bathing their planets in starlight for eons." "Life is much more probable on these time scales,
where conditions are stable for vast periods of time." "Any beings living close to these stars would have to contend
with violent solar flares that continually threaten extinction." "Many of these planets would be tidally locked - one side permanently
exposed to the sun, the other frozen in darkness." "But as Earth has taught us, life is remarkably adaptable." "What forms might life take when it has trillions of years to evolve?" "One day, somehow, the story of life will come to an end." "If we are the first chapter of that story, we have the chance
to carry the torch of life far into the future." "And if biology does persist far into the future,
then we live in a privileged moment." In later chapters, the universe will seem far different. "The expansion of spacetime will make distant stars invisible,
and the night skies will go dark." "Perhaps life in the far future will wonder:
What it was like to live in the universe's brilliant early days?" "We are lucky enough to know the answer." "All we have to do is look up." Hand Crafted By Melodysheep Hand Crafted By Melodysheep
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Featuring The Voices Of Protocol Labs
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Orson Welles Douglas Rain
Orson Welles
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Dan Werthimer
Avi Loeb Dan Werthimer
Avi Loeb
Ellen Stofan Avi Loeb
Ellen Stofan
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Lawrence Krauss
Concept, Music & Visuals By Lawrence Krauss
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An
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Production LIFE LIFE BEYOND Next on Life Beyond:
Make contect with intelligent life
Surviving the end of the universe
The physics of alien life
& more Subtitler:
Ernesryst Sautrie
Erick Soares Figueiredo
fpetras
I watched this when I woke up this morning, a very relaxing 30 minutes, for those of u checking the comments first, give this a watch, chances are you won’t regret it :)
Video is no longer available
anyway to watch it?
About to watch this. How much "woo" and speculation is this, vs sticking to facts?
Just commenting so I can find this later. Move along.