Think about the following questions as you watch the video

1. 04:16 What are the Goldilocks Conditions for life?
2. 04:51 What makes rocky planets ideal locations for the appearance of life?
3. 05:07 Why do many scientists believe that life may have originated deep in the oceans around oceanic vents?

00:12: How many different species of living organisms
00:15: do you think exist on our tiny planet?
00:17: The truth is we don't really know.
00:20: Estimates range from perhaps five million
00:23: to perhaps as many as 30 million,
00:24: and it could be a lot more than that.
00:26: That's staggering variety.
00:29: And that's only a tiny fraction of all the species
00:31: that have existed in the history of life
00:33: which extends over almost four billion years.
00:37: Yeah, life really is mysterious,
00:41: but there's actually quite a lot we know about it.
00:43: We've seen that...
00:44: we know some of the main characteristics of life,
00:48: and we also have a pretty good idea
00:50: of how and why life changes over time.
00:54: Now, what we're going to do in this unit
00:55: is we're going to survey the history of life
00:58: over almost four billion years.
01:00: We'll begin with the origins of life.
01:03: That, remember, is our first...
01:05: fifth major threshold in this course.
01:08: And then what we're going to do is we're going to look
01:09: at a series of smaller turning points.
01:12: We call them mini-thresholds.
01:14: These are times when something new appears
01:16: that seems to be slightly more complex
01:19: than the things that existed before.
01:21: And all of this, of course, is pointing to the creation
01:24: of our own species, Homo sapiens.
01:27: We begin with the origins of life.
01:29: Now remember, this is the fifth major threshold
01:33: of increasing complexity in our course,
01:35: and let me remind you what we mean by thresholds
01:37: of increasing complexity.
01:39: At each of these thresholds,
01:41: something new seems to appear in the universe,
01:43: something with entirely new qualities.
01:46: Now, each time we've crossed these thresholds,
01:48: we've asked similar questions.
01:50: So when we talked about the first threshold,
01:52: the creation of the universe, or the creation of stars
01:55: or the creation of new chemical elements,
01:57: or the creation of planets, we asked,
01:59: "What were the Goldilocks conditions
02:01: that made it possible to cross that threshold?"
02:05: So let's ask the same question about life.
02:08: Now, with life, there's a problem
02:10: because biologists suspect that there's life
02:14: all through the universe,
02:16: but the truth is we don't know.
02:18: The only place in which we're sure life appeared
02:21: is on our planet.
02:22: So that's the only place we can really study it.
02:25: So let's rephrase the question.
02:26: What were the Goldilocks conditions
02:29: for the origins of life on Earth?
02:32: Now, we can start with the fact that living organisms
02:37: consist of very, very complex chemicals.
02:40: They're not just large;
02:41: they're also organized in very precise structures,
02:44: whereas non-living things
02:45: consist of very simple molecules.
02:48: So to get life,
02:49: you need environments in which you can do
02:51: really exotic,
02:52: really interesting,
02:54: really elaborate chemistry.
02:57: So where do you find conditions
03:00: such that atoms can combine in all sorts of exotic forms?
03:05: Let's recall that in space, you can do simple chemistry--
03:08: atoms can combine to form molecules
03:11: with perhaps ten, 20, 30,
03:13: never more than 100 atoms.
03:15: But rocky planets like our Earth, it turns out,
03:18: are wonderful environments for good chemistry.
03:21: There are three reasons for this.
03:22: The first is that they contain a great diversity
03:25: of different elements.
03:27: And above all, they contain those elements
03:30: that you need for organic life.
03:32: The crucial ones are carbon...
03:34: There's lots of hydrogen, of course.
03:35: There's also oxygen, nitrogen.
03:37: These are all elements that were formed in dying stars,
03:40: and also a bit of phosphorous and sulfur.
03:43: The second Goldilocks condition is energy.
03:45: But this is subtle.
03:47: You mustn't have too much.
03:49: If there's too much, you blast complex molecules apart.
03:53: But you mustn't have too little.
03:55: If there's too little, there's not the energy
03:56: for atoms to combine.
03:58: The Earth was perfect.
04:00: It was near a star so it had energy,
04:02: but not too much.
04:03: And it also had energy coming up from its hot,
04:06: molten core.
04:08: Now, the third Goldilocks condition
04:11: is slightly subtler.
04:12: It's the presence of liquids
04:15: and, above all, of water.
04:17: Why?
04:18: Well, think about it.
04:19: In gases, atoms are moving around incredibly fast
04:24: and it's very hard for them to link up.
04:26: But in solids, atoms are stuck.
04:29: They're stuck in a grid, like bad traffic,
04:32: like a traffic jam.
04:34: But in liquids, they can cruise past each other
04:38: so it's much easier for them to hitch up
04:40: in all sorts of complex forms.
04:42: So here are our three Goldilocks conditions.
04:45: The early Earth was almost perfect
04:47: for elaborate chemistry.
04:48: We've seen that all these Goldilocks conditions
04:51: existed on the early Earth.
04:53: Probably the ideal place for elaborate chemistry
04:56: was deep beneath the oceans at cracks in the Earth's crust,
05:00: mid-oceanic vents.
05:02: These were ideal because you've got
05:04: lots of chemicals seeping up from the mantle
05:06: and you've also got lots of energy.
05:08: And we know now that under these conditions,
05:11: it's fairly simple to create
05:13: the simplest organic molecules
05:15: that appear in all living organisms.
05:17: I'm talking about molecules with just ten,
05:18: 20, 30 atoms in them such as amino acids,
05:22: which are the basis of all proteins,
05:24: or nucleotides, which are the basis of DNA.
05:29: We also know that it's not too hard
05:31: under these conditions
05:34: to string those simple molecules together in huge chains
05:38: to form proteins and nucleotide molecules.
05:43: What gets tricky is the next stage.
05:45: How, with lots of these large molecules,
05:48: to bring them together to form cells with membranes--
05:51: they're like skins--
05:52: and also with DNA at their center.
05:55: But most biologists are pretty confident
05:57: that though there's still some mystery here,