1. Hello.Copy !req
2. My name is Stephen Hawking...Copy !req
3. physicist, cosmologist...Copy !req
4. and something of a dreamer.Copy !req
5. Although I cannot move...Copy !req
6. and I have to
speak through a computer...Copy !req
7. in my mind, I am free.Copy !req
8. Free to tour the universeCopy !req
9. and tell the ultimate story...Copy !req
10. the story of everything
there ever was...Copy !req
11. from the moment
the cosmos began...Copy !req
12. to the creation of our world
and everything in it...Copy !req
13. and beyond,
to the far, far futureCopy !req
14. and the end
of the universe itself...Copy !req
15. a journey through all
of space and all of time.Copy !req
16. Check it out.Copy !req
17. I spend a lot of time
thinking about the universe,Copy !req
18. but I never get bored.Copy !req
19. After all, it's
a pretty extraordinary place.Copy !req
20. This is the cosmos...Copy !req
21. at a very large scale.Copy !req
22. Each tiny point of light
is an entire galaxy,Copy !req
23. each a cluster of as many
as 400 billion individual stars.Copy !req
24. This view of the universe
is only possibleCopy !req
25. due to the latest
supercomputers.Copy !req
26. I find it
indescribably beautiful...Copy !req
27. uncountable billions of galaxies
forming a vast webCopy !req
28. stretching away
in all directions.Copy !req
29. What's more,
I never get over the factCopy !req
30. that within
this massive universeCopy !req
31. lies one perfectly ordinary
spiral galaxy.Copy !req
32. Inside that galaxy exists
a commonplace yellow star...Copy !req
33. orbited by eight planets.Copy !req
34. On one of those planets
lives a speciesCopy !req
35. that has only just worked outCopy !req
36. what a remarkable place
the universe is.Copy !req
37. Us.Copy !req
38. We've discovered more about
the cosmos in the last centuryCopy !req
39. than in all previous
human history.Copy !req
40. Finally, we are solving
the basic mysteriesCopy !req
41. that have perplexed
our ancestorsCopy !req
42. for at least 200,000 years.Copy !req
43. What I like above all
is that the facts themselvesCopy !req
44. are both breathtakingly elegant
and surprising.Copy !req
45. We're living
just as it dawns on usCopy !req
46. that the Earth
and everything around usCopy !req
47. was made by the stars.Copy !req
48. Boiling furnaces of hydrogen gas
like our sunCopy !req
49. made even the atoms
in your eyelashes.Copy !req
50. We've worked out
that the universeCopy !req
51. is almost
unimaginably ancient...Copy !req
52. about 14 billion years old...Copy !req
53. and that it will continue
to existCopy !req
54. for at least twice that long.Copy !req
55. But without a doubt,
the most remarkable fact of allCopy !req
56. is that the entire
enormous universe,Copy !req
57. all the innumerable galaxies,Copy !req
58. even time and space and
the forces of nature themselves,Copy !req
59. simply materialized out of...Copy !req
60. nothing.Copy !req
61. So now is a good time
to be alive, I think.Copy !req
62. We may only be
an advanced breed of monkeyCopy !req
63. living on a small planet,Copy !req
64. but we are able to contemplate
the universe as a whole,Copy !req
65. which makes us very special.Copy !req
66. My goal has always
been simple...Copy !req
67. to work out
how the universe worksCopy !req
68. and why it exists at all.Copy !req
69. Luckily,
there are clues everywhere,Copy !req
70. and the most important one
is right above our heads.Copy !req
71. Examine any patch
of the night sky,Copy !req
72. even one as small
as the head of a pin,Copy !req
73. and this is what you'll find.Copy !req
74. A tiny part
of the vast web of galaxies.Copy !req
75. It's less than a millionthCopy !req
76. of what we can see of the cosmos
from our little planet.Copy !req
77. But even this tiny sample
is enough to find a clue,Copy !req
78. the key to the past,
the present,Copy !req
79. and perhaps the future, too.Copy !req
80. The clue is that,
seen from Earth,Copy !req
81. all these distant galaxies
are slightly red in color.Copy !req
82. They appear almostCopy !req
83. as if we were looking
through rose-tinted glasses.Copy !req
84. It's this very rednessCopy !req
85. that reveals
how the universe was born.Copy !req
86. And to show you why,Copy !req
87. I need a straight road
and a noisy car.Copy !req
88. Listen to the sound
as it passes by.Copy !req
89. As the car approaches,
the pitch of its engine rises.Copy !req
90. As it goes away,
the pitch of its engine...Copy !req
91. falls.Copy !req
92. This phenomenon
is called a Doppler shift,Copy !req
93. and the exact same thing
happens with light.Copy !req
94. If our eyes were
more sensitive to color,Copy !req
95. we could see that the car
is actually very slightly blueCopy !req
96. as it approaches...Copy !req
97. and very slightly red
as it goes away.Copy !req
98. The same rules apply in space.Copy !req
99. All distant galaxies
are slightly red in color,Copy !req
100. so by the exact same piece
of basic physics,Copy !req
101. they must all
be moving away, too.Copy !req
102. In fact, the whole universe
is expanding in all directions,Copy !req
103. getting bigger and bigger,
like a balloon inflating.Copy !req
104. I admit this sounds strange,Copy !req
105. but to cosmologists,
it's like winning the lottery,Copy !req
106. because, to work out
where the universe came from,Copy !req
107. all we need to do
is to stop timeCopy !req
108. and make it run in reverse.Copy !req
109. Rewind far enough, and
everything gets closer together.Copy !req
110. A lot closer together.Copy !req
111. All the galaxies,Copy !req
112. in fact, every single thing
converges to a single point,Copy !req
113. the start of everything,Copy !req
114. 13.7 billion years ago.Copy !req
115. So it's quite simple, really.Copy !req
116. Follow the clues,Copy !req
117. and we can deduce
that a very long time ago,Copy !req
118. the universe simply burst
into existence,Copy !req
119. an event called the big bang.Copy !req
120. But I'm afraid
we have to stop a momentCopy !req
121. before we get carried away
by fire and noise.Copy !req
122. At the very beginning,Copy !req
123. the big bang actually happened
in total darkness,Copy !req
124. because light didn't exist yet.Copy !req
125. To see it, we'd have needed some
kind of cosmic night vision.Copy !req
126. But even this, a view from
the outside, is impossible.Copy !req
127. Again, it sounds strange, but
space didn't exist then, either.Copy !req
128. So there was no outside.Copy !req
129. The only place there was,
was inside.Copy !req
130. This early universe was
a very strange thing, indeed.Copy !req
131. There's still much I'd
dearly love to know about it,Copy !req
132. but standard concepts of time
or space don't really apply.Copy !req
133. It was just a very tiny,
ultra-hot fog of energy.Copy !req
134. Then it expanded...Copy !req
135. with a tremendous flash
of radiationCopy !req
136. from smaller than an atom
to about the size of an orangeCopy !req
137. in less than a trillionth
of a second,Copy !req
138. almost no time at all.Copy !req
139. The universe simply inflated
into existence,Copy !req
140. unfolding, unfurling,Copy !req
141. getting bigger and cooler
with every passing moment.Copy !req
142. Within 100 seconds, it was
as big as our solar system,Copy !req
143. trillions of miles across.Copy !req
144. While this was happening,Copy !req
145. the pure energy of the cosmos
began to cool and create matterCopy !req
146. in the form
of countless trillionsCopy !req
147. of subatomic particles.Copy !req
148. The first stuff there ever was.Copy !req
149. Half these particles
were made of matter,Copy !req
150. the same kind of stuff
which makes us.Copy !req
151. The rest were made
of the opposite of matter,Copy !req
152. stuff called antimatter.Copy !req
153. When the two meet, they destroy
each other in a flash of energy.Copy !req
154. It seems as if
building a universeCopy !req
155. is a pretty wasteful process.Copy !req
156. Fortunately, there was
just a bit more matterCopy !req
157. than antimatter.Copy !req
158. Just one in a billion particles
of stuff survived.Copy !req
159. Which was lucky for us,
because that residueCopy !req
160. is what our present-day universe
is made of.Copy !req
161. You could say we are made
of the smoke of the big bang.Copy !req
162. By the time the cosmos
was 10 minutes old,Copy !req
163. it was already thousands
of light-years in diameter.Copy !req
164. After that,
everything spread out and cooledCopy !req
165. for about 330,000 years,Copy !req
166. when, finally, the fog cleared
and the universe became visible.Copy !req
167. So, that's how everything
got going,Copy !req
168. which I think is
a pretty fantastic storyCopy !req
169. and probably much strangerCopy !req
170. than anything our ancestors
came up withCopy !req
171. by way of an explanation.Copy !req
172. But the next thing
that happened,Copy !req
173. well, that's
pretty spectacular, too.Copy !req
174. This is the universe
seen in extreme fast-forward,Copy !req
175. all 14 billion years
in less than a minute.Copy !req
176. It shows how the universe
changed from a cloud of gasCopy !req
177. into a place filled with perhaps
100 billion galaxies,Copy !req
178. swirling
in a vast chaotic dance.Copy !req
179. What I love to get people
thinking aboutCopy !req
180. is that all this
had to be built atom by atom,Copy !req
181. celestial engineering
on a spectacular scale.Copy !req
182. So, what drove
this cosmic clockwork?Copy !req
183. I'd say it was
the force of gravity.Copy !req
184. The idea of gravity was worked
out by Sir Isaac Newton...Copy !req
185. who had the same job as me
here at Cambridge UniversityCopy !req
186. back in the 17th century.Copy !req
187. It supposedly dawned on him
when an apple fell on his head.Copy !req
188. The apple helped him realizeCopy !req
189. that all objects
attract each other.Copy !req
190. And the greater the mass,
the stronger the pull.Copy !req
191. These apples
are attracted to the Earth,Copy !req
192. and although you can't see it,Copy !req
193. the Earth moves very slightly
up towards the apples.Copy !req
194. All things come together
through the power of gravity.Copy !req
195. Gravity was created
in the big bangCopy !req
196. and has been at work
ever since.Copy !req
197. It's what keeps you, me,
and apples stuck to the Earth.Copy !req
198. In the early universe, gravity
had a much bigger role to play.Copy !req
199. Right after the big bang,Copy !req
200. the universe was just gas,Copy !req
201. almost perfectly spread out
throughout space.Copy !req
202. Over the next 200 million years,Copy !req
203. gravity began to pull the gas
back togetherCopy !req
204. to produce
the very first structuresCopy !req
205. from which everything else
would grow.Copy !req
206. But even this
very nearly didn't happen.Copy !req
207. If it weren't for another stroke
of cosmic luck,Copy !req
208. there would be no you, no me,Copy !req
209. no stars or planets
or anything at all.Copy !req
210. We know this because, in 1982,Copy !req
211. a group of scientists,
including myself,Copy !req
212. spent three solid weeks
working it out.Copy !req
213. Although the calculations
were hard,Copy !req
214. demonstrating what we discovered
is easy.Copy !req
215. First, I need a nice flat floor,
like this one, for example.Copy !req
216. This is the dining room
in my college.Copy !req
217. I'm going to fill the place with
lots and lots of ball bearings.Copy !req
218. These balls represent the matter
of the early universe,Copy !req
219. a thin gas spread out evenly
across the vast cosmos.Copy !req
220. Here's where luck comes in.Copy !req
221. If they're all
the same distance apart,Copy !req
222. gravity pulls each ball the
same amount in all directions.Copy !req
223. They stay perfectly aligned,
and precisely nothing happens.Copy !req
224. Fortunately, one of
the basic rules of the universeCopy !req
225. is that nothing's perfect.Copy !req
226. Perfection simply doesn't exist.Copy !req
227. The early universe
had a tiny unevennessCopy !req
228. that can be simulatedCopy !req
229. by removing
just five ball bearings.Copy !req
230. It may not look
like much has changed,Copy !req
231. but to gravity,Copy !req
232. those missing balls
create a giant opportunity.Copy !req
233. Gravity now pulls more stronglyCopy !req
234. on one side
of some of the bearings.Copy !req
235. The tiny irregularities
in the sea of ball bearingsCopy !req
236. have given gravity something
to sink its teeth into.Copy !req
237. And this
is exactly what happenedCopy !req
238. back where we left
the young universe.Copy !req
239. Parts of the sea of early gasCopy !req
240. were ever so slightly thinner
than others.Copy !req
241. The less dense areasCopy !req
242. were like the gaps
between the ball bearings.Copy !req
243. The denser parts
of the sea of gas,Copy !req
244. where gravity was having
its way, clumped together.Copy !req
245. And it was in these areasCopy !req
246. that all the stars and galaxies
would fall.Copy !req
247. The cosmos had taken
its first stepCopy !req
248. towards the beautiful place
it is today,Copy !req
249. all thanks to irregularity,
imperfection, a lack of order.Copy !req
250. So next time someone complains
that you have made a mistake...Copy !req
251. tell him,
"That may be a good thingCopy !req
252. because without imperfection,
neither you nor I would exist."Copy !req
253. 13.5 billion years ago,Copy !req
254. the universe
was mostly hydrogen gas,Copy !req
255. with gravity doing
what gravity does,Copy !req
256. which is to slowly pull it
into vast clouds.Copy !req
257. Hydrogen is the simplest
of gases,Copy !req
258. but it has
a very special property.Copy !req
259. It's a tremendous
source of power.Copy !req
260. Heat hydrogen
to around 10 million degrees,Copy !req
261. and it begins to produce
the energyCopy !req
262. that makes the stars shine.Copy !req
263. And supplies the universe
with warmth and light.Copy !req
264. To see how this works,Copy !req
265. let's imagine we can make
a small star here on Earth.Copy !req
266. First, we need plenty
of hydrogen gas.Copy !req
267. About a sports stadium full
would be perfect.Copy !req
268. Next, we need to imagineCopy !req
269. squishing
this hydrogen together,Copy !req
270. just as gravity does in space.Copy !req
271. As the hydrogen compacts,Copy !req
272. the atoms of gas start
bouncing off each other.Copy !req
273. And the temperature
begins to rise.Copy !req
274. By the time it's compressed down
to the size of a soccer ball,Copy !req
275. the hydrogen reaches
the critical 10 million degrees.Copy !req
276. And a process
called nuclear fusion begins.Copy !req
277. The hydrogen starts
to fuse together,Copy !req
278. making a new, heavier material.Copy !req
279. Helium.Copy !req
280. With every step
of this tiny bump and grind,Copy !req
281. some matter gets converted
into pure energy.Copy !req
282. We have created
a miniature star.Copy !req
283. Of course,
if this was a real experiment,Copy !req
284. you wouldn't want to go
anywhere near it.Copy !req
285. The energy given off
even from a star this smallCopy !req
286. would be devastating.Copy !req
287. Back in the early universe,Copy !req
288. the same process happened
for the first timeCopy !req
289. on a much, much bigger scale.Copy !req
290. Gravity compressed
the hydrogen gas cloudsCopy !req
291. over millions of years,
until, deep in the center,Copy !req
292. the hydrogen became hot enough
for fusion to occur.Copy !req
293. The first star
burst into life...Copy !req
294. pouring its energy
into the vast universe,Copy !req
295. a product of the laws of natureCopy !req
296. and the raw materials left over
from the big bang.Copy !req
297. It was almost 1,000 times bigger
than our own sunCopy !req
298. and burned a deep blue.Copy !req
299. What's more,
this star soon had company.Copy !req
300. The stars were turning on.Copy !req
301. This same process still happens
in our sun,Copy !req
302. which is where we get
the energy we need to live.Copy !req
303. But there was still
a long way to goCopy !req
304. to get from this
to where we are today.Copy !req
305. You can't build
a world like oursCopy !req
306. from simple gases
such as hydrogen and helium.Copy !req
307. You need all sorts
of other elements.Copy !req
308. You need elements like oxygen
and carbon and ironCopy !req
309. and many more.Copy !req
310. But we got lucky yet again,Copy !req
311. because the very same process
that causes the stars to shineCopy !req
312. also just happens
to make materialsCopy !req
313. like oxygen and carbon and iron.Copy !req
314. Stars, simply by accident,
are giant factories.Copy !req
315. To see a star in action,Copy !req
316. let's imagine
I can split one in half.Copy !req
317. Just as in the soccer-ball star,Copy !req
318. the hydrogen atoms
are fusing together,Copy !req
319. creating helium, which produces
the star's energy.Copy !req
320. But helium is slightly heavier
than hydrogen,Copy !req
321. so it sinks
to the center of the star.Copy !req
322. And now the helium atoms
take center stage.Copy !req
323. As they fuse together,
they produce even more energyCopy !req
324. and form yet another
new element.Copy !req
325. Carbon...Copy !req
326. a vital building block
of every living thing.Copy !req
327. The process repeats itself
over and over,Copy !req
328. and the star becomes layered,
like an onion.Copy !req
329. A really big onion.Copy !req
330. The closer to the center,
the heavier the elements,Copy !req
331. like neon, oxygen,
and last of all, iron.Copy !req
332. Now things change.Copy !req
333. Iron doesn't produce energy
when it fuses,Copy !req
334. so the fire begins to go out.Copy !req
335. More and more iron builds up
in the star's coreCopy !req
336. until almost all
the remaining fuel runs out.Copy !req
337. Now gravity takes over and
squashes the star in on itself.Copy !req
338. As its core gets
more and more compressed,Copy !req
339. its temperature soarsCopy !req
340. until it's over 100 times hotter
than the core of our own sun.Copy !req
341. Finally, the star collapses
and explodes.Copy !req
342. This is a supernova.Copy !req
343. The death of a star
and the birth of something new.Copy !req
344. In these brief microseconds,Copy !req
345. a massive shock wave
passes through the star.Copy !req
346. The blast is so powerful
that it forces some of the ironCopy !req
347. to fuse
into even heavier elements.Copy !req
348. And that's how heavy elements,Copy !req
349. such as gold or platinum
or lead,Copy !req
350. are made, forged in the heart
of an exploding star.Copy !req
351. So, if you have a gold ring,
make sure you appreciate it.Copy !req
352. The metal was made
in a blinding flash of lightCopy !req
353. billions of years ago,
the finale of the processCopy !req
354. that produced the elements
all around us today.Copy !req
355. It never ceases to amaze me...Copy !req
356. that our bodies
are constructedCopy !req
357. of the stuff of starsCopy !req
358. and that our hearts beat
because of the energyCopy !req
359. given off
as those materials are made.Copy !req
360. But as magical as the star is,Copy !req
361. there are even more fascinating
and powerful thingsCopy !req
362. in our enormous cosmos.Copy !req
363. Around 300 million
years after the big bang,Copy !req
364. the early stars
began to form galaxies,Copy !req
365. which slowly took onCopy !req
366. a bewildering variety
of shapes and sizes.Copy !req
367. Our galaxy, the Milky Way,Copy !req
368. is thought to be
one of the oldest,Copy !req
369. having started
to assemble itselfCopy !req
370. some 13 billion years ago.Copy !req
371. It's roughly
6,000 billion miles in diameterCopy !req
372. and contains something like
200 billion individual stars.Copy !req
373. Nobody's quite sure
exactly how many,Copy !req
374. since they can't all be seen
from Earth,Copy !req
375. and, anyway, it would take
a long time to count them.Copy !req
376. Because all these stars
were built by gravity,Copy !req
377. you could say gravity's
the hero of the universe.Copy !req
378. After all, it turned
a meaningless soup of gasCopy !req
379. into something of beauty
and power.Copy !req
380. But like all interesting heroes,
gravity has its dark side.Copy !req
381. Right in the center
of our galaxyCopy !req
382. lies an example of what happens
when gravity rules unchallenged.Copy !req
383. A black hole.Copy !req
384. When I was in my 20s...Copy !req
385. I did some of the basic
mathematics of black holes,Copy !req
386. but few people shared
my fascination.Copy !req
387. These days,
they are a popular subject.Copy !req
388. Physicists all over the worldCopy !req
389. are studying
black-hole behavior.Copy !req
390. We now know that black holesCopy !req
391. are not only fascinating
in their own right,Copy !req
392. but that they play
a fundamental roleCopy !req
393. in the formation of galaxies.Copy !req
394. They also give us a glimpse
of how the universe may end.Copy !req
395. A black hole forms
when a large star...Copy !req
396. one, say, 20 times
the mass of our sun...Copy !req
397. comes to the end of its life.Copy !req
398. Such a star looks
nothing like our sunCopy !req
399. because it's become unstable,Copy !req
400. convulsing violently
as its death throes begin.Copy !req
401. Finally, it runs out of fuel
and begins to shrink,Copy !req
402. getting denser and denser,
hotter and hotter.Copy !req
403. But with a star this massive,Copy !req
404. there is no force
in the universeCopy !req
405. capable of stopping
the collapse.Copy !req
406. The core is so heavyCopy !req
407. that it just keeps on
falling in on itself.Copy !req
408. Gravity is running wild.Copy !req
409. In just 15 seconds or so,Copy !req
410. the unstoppable force
crushes the starCopy !req
411. from millions of miles
in diameterCopy !req
412. to as little
as 12 miles in diameter.Copy !req
413. All the mass that was
in the star is still there,Copy !req
414. but its own weight
keeps forcing it downCopy !req
415. smaller and smaller still.Copy !req
416. The temperature of the core
soars to 100 billion degrees.Copy !req
417. The outer layers are blasted
away in a massive supernova.Copy !req
418. But deep in the center,Copy !req
419. the core falls down what we call
a gravitational well.Copy !req
420. It crushes itself
into a single point.Copy !req
421. A black hole is born.Copy !req
422. Nothing nearby can escape
its pull, not even light.Copy !req
423. It's hard to imagine just
how dense a black hole can be.Copy !req
424. But I'll try and put it
into perspectiveCopy !req
425. using something familiar.Copy !req
426. The Earth.Copy !req
427. Imagine, piece by piece,
I could compress our planetCopy !req
428. and crush it
until gravity took over...Copy !req
429. and it became a black hole.Copy !req
430. How small would it have to beCopy !req
431. to vanish down
its own gravitational well?Copy !req
432. From 8,000 miles in diameter,Copy !req
433. I'd have to crush it
to the size of a pea.Copy !req
434. In my years
studying black holes...Copy !req
435. one of my most
unexpected discoveriesCopy !req
436. was that a black hole
cannot be perfectly black.Copy !req
437. For much the same reason...Copy !req
438. as the early universeCopy !req
439. could not have been
perfectly spread out.Copy !req
440. There is no such thing
as perfection.Copy !req
441. Black holes
must give off radiation.Copy !req
442. The smaller the black hole,
the greater the radiation.Copy !req
443. An even tinier black hole,Copy !req
444. with only the mass
of a mountain range,Copy !req
445. would actually shine.Copy !req
446. Out in space, most black holes
are much larger.Copy !req
447. The smaller ones have around
four times the mass of our sunCopy !req
448. and are 15 miles in diameter.Copy !req
449. Some are much larger,Copy !req
450. containing the mass
of thousands of suns.Copy !req
451. And then there are
the really big ones...Copy !req
452. supermassive black holes...Copy !req
453. that exist at the centers
of galaxies like our own.Copy !req
454. This black holeCopy !req
455. is thought to have the mass
of 4 million sunsCopy !req
456. and a diameter
of 11 million miles.Copy !req
457. Black holes like these
are the heavy hubsCopy !req
458. around which many galaxies,
including the Milky Way, rotate,Copy !req
459. a kind of stabilizer
that gives them form and shape.Copy !req
460. So, 8 billion years
after the big bang,Copy !req
461. after a long and remarkable run
of good luck,Copy !req
462. we have stars
and we have galaxiesCopy !req
463. slowly rotating
around giant black holes.Copy !req
464. Now the scene is set for
something close to our hearts...Copy !req
465. the formation of our sun,
the Earth, and, ultimately, us.Copy !req
466. Our solar system,
the place we call home,Copy !req
467. lies about 26,000 light-years
from the center of our galaxy,Copy !req
468. the Milky Way.Copy !req
469. Or around 2/3 of the way out.Copy !req
470. The story of how
these huge planetsCopy !req
471. came to be orbiting
an average yellow starCopy !req
472. is 6 billion years long.Copy !req
473. And since we don't have
that much time,Copy !req
474. I'll speed it up a bit.Copy !req
475. It starts with a bang.Copy !req
476. Long ago,
an ancient star exploded,Copy !req
477. littering space
with swirling cloudsCopy !req
478. of the materials
it had made while it livedCopy !req
479. and the heavier metals
it created as it died.Copy !req
480. We know this because we can see
similar fields of dustCopy !req
481. out in space today.Copy !req
482. They are called nebulae.Copy !req
483. And they are very beautiful.Copy !req
484. Every nebula is different,
and in our case,Copy !req
485. the clouds contained nitrogen
and oxygen and iron and silicaCopy !req
486. and all the other stuff needed
to build a world like ours.Copy !req
487. Then the tireless force
of gravityCopy !req
488. started to pull it all
back together,Copy !req
489. and the heavy engineering
that produces planets began.Copy !req
490. Vast spirals of dust
began to form,Copy !req
491. and at the center
of one of these,Copy !req
492. a rocky planet called Earth
started to take shape.Copy !req
493. Built of stardust
and assembled by gravity.Copy !req
494. Fast-forward 100 million years,Copy !req
495. and it had grown
into a giant ball,Copy !req
496. sweeping up billions of tons
of celestial debris.Copy !req
497. This is where
the Earth came fromCopy !req
498. and, therefore,
how you and I began.Copy !req
499. But our planet would have
remained a large, sterile ballCopy !req
500. of rock and metals
and minerals foreverCopy !req
501. were it not for one more event,Copy !req
502. one more expression
of the forces of nature.Copy !req
503. 93 million miles away,Copy !req
504. at the heart
of the giant nebula,Copy !req
505. the pressure and temperature
of a ball of hydrogen gasCopy !req
506. had become so great that the
atoms were beginning to fuse.Copy !req
507. A new star, our sun,
was coming to life.Copy !req
508. As the sun ignited,Copy !req
509. it gave off a huge blast
of solar wind...Copy !req
510. a radioactive gust of energy.Copy !req
511. This blew all
the remaining dust and gasCopy !req
512. that was left over
from the nebulaCopy !req
513. out to the edge
of the solar system,Copy !req
514. which is why everything
is nice and orderly today.Copy !req
515. In the outer reaches
of the solar system,Copy !req
516. we have the huge gas planets...Copy !req
517. Jupiter...Copy !req
518. Saturn...Copy !req
519. Uranus, and Neptune.Copy !req
520. Further in are the denser,
rockier planets...Copy !req
521. Mercury...Copy !req
522. Venus...Copy !req
523. Mars...Copy !req
524. and, of course, the Earth.Copy !req
525. Lucky for us, the sun
is 865,000 miles in diameter,Copy !req
526. or just the right size
to burn consistentlyCopy !req
527. for a very long time...
8 billion years...Copy !req
528. long enough to allow the next
development to take place.Copy !req
529. Life.Copy !req
530. Life is one of
the strangest phenomena known.Copy !req
531. In my opinion,Copy !req
532. it shows that the universe
is capable of almost anything.Copy !req
533. Yet it amazes me
that we can know so muchCopy !req
534. about how the universe began
many billions of years ago,Copy !req
535. but we have yet to discover
how life itself began.Copy !req
536. The most likely explanationCopy !req
537. is probably
that we are an accident.Copy !req
538. Just by chance,Copy !req
539. some molecules
bumped into each other at randomCopy !req
540. until, finally, one formed
that could copy itself.Copy !req
541. Then began the slow process
of evolutionCopy !req
542. that led to all
the extraordinary diversityCopy !req
543. of life on Earth.Copy !req
544. Life seems to be
simply what matter does,Copy !req
545. given the right conditions
and enough time.Copy !req
546. I think that lifeCopy !req
547. is probably quite common
throughout the universe,Copy !req
548. but that's another tale
altogether.Copy !req
549. As life developed, it changed
the planet on which it was born,Copy !req
550. altering the very fabric
of the Earth.Copy !req
551. After 41/2 billion years,Copy !req
552. the human race
arrived on the scene.Copy !req
553. But one thing
often troubles people...Copy !req
554. when they hear this story.Copy !req
555. How could such
an astounding chain of events,Copy !req
556. which resulted in us,
be an accident?Copy !req
557. Perhaps science has revealedCopy !req
558. there is some higher authority
at work,Copy !req
559. setting the laws of natureCopy !req
560. so that our universe
and we can exist.Copy !req
561. On the face of it,
life does seemCopy !req
562. to be too unlikely
to be just a coincidence.Copy !req
563. Think about it.Copy !req
564. The Earth lies at exactly
the right distance from the sunCopy !req
565. to allow liquid water
to exist on its surface.Copy !req
566. And the sun just happens
to be the right sizeCopy !req
567. to burn for billions of years,Copy !req
568. long enough for life
to have evolved.Copy !req
569. The solar system is litteredCopy !req
570. with all the elements
needed for life.Copy !req
571. These elements themselves
are only possibleCopy !req
572. because of older stars
that have burned up.Copy !req
573. These older stars only existedCopy !req
574. because of a tiny unevenness
in the early primordial gas...Copy !req
575. that was itself produced
by a one-in-a-billion imbalanceCopy !req
576. in the sea of particles
that came from the big bang.Copy !req
577. So is there a grand designerCopy !req
578. who lined up
all this good fortune?Copy !req
579. In my opinion, not necessarily.Copy !req
580. Look at it this way.Copy !req
581. What if there were
other universes,Copy !req
582. ones not as lucky as ours?Copy !req
583. Each of these universesCopy !req
584. could have come
from its own big bang,Copy !req
585. with different laws of physics
and different conditions.Copy !req
586. In some,
gravity might not exist,Copy !req
587. and there could be no life.Copy !req
588. In others,
hydrogen might not fuse,Copy !req
589. so there would be no stars
and, again, no life.Copy !req
590. And for any number of reasons,Copy !req
591. universes could have
come and goneCopy !req
592. without producing
anything at all.Copy !req
593. So perhaps we should not
be too surprisedCopy !req
594. to find ourselves
in a perfect universeCopy !req
595. orbiting a perfect sun
on a perfect planet,Copy !req
596. because such perfect placesCopy !req
597. are the only ones
where life like us can exist.Copy !req
598. We are one of the many products
of the universe,Copy !req
599. the result of an ancient
and elegant mechanism.Copy !req
600. But even this
remarkable discoveryCopy !req
601. is only just the beginning
of what physics can tell us.Copy !req
602. We can find out what human kind
will face in the distant future.Copy !req
603. And, ultimately,Copy !req
604. we might discover the fate
of the universe itself.Copy !req
605. One reason I love cosmologyCopy !req
606. is that it tells us
not only whereCopy !req
607. the vast web of galaxies
in our universe came from,Copy !req
608. but also what lies in storeCopy !req
609. for both the universe
and for us.Copy !req
610. I think it's pretty excitingCopy !req
611. to be among the first human
beings able to look forwardCopy !req
612. for hundreds
and even billions of years,Copy !req
613. maybe as far
as the end of time itself.Copy !req
614. What I see
is not only the futureCopy !req
615. of the cosmos we inhabit...Copy !req
616. but also
the enormous challengesCopy !req
617. our species will face.Copy !req
618. After all,
we are puny organismsCopy !req
619. compared to the mighty universe
that made us.Copy !req
620. Even the Earth
that gave us lifeCopy !req
621. will not always be
the blue sanctuary it is today.Copy !req
622. The continents
of our planet are drifting.Copy !req
623. Fast-forward 75 million years,Copy !req
624. and they will be clustered
towards the South Pole.Copy !req
625. No one knows if the Earth
will still be habitable then,Copy !req
626. but the sad truth isCopy !req
627. that we may not last long enough
to find out.Copy !req
628. As we gaze into the future,Copy !req
629. it turns out that the universe
is a pretty dangerous place.Copy !req
630. Just look at our neighborhood.Copy !req
631. It's littered
with billions of asteroids,Copy !req
632. ancient remnants left overCopy !req
633. from the process
that built the solar system.Copy !req
634. The possibility of one of these
wiping us outCopy !req
635. isn't just the stuff
of Hollywood disaster movies.Copy !req
636. The threat from asteroids
is real.Copy !req
637. We've even given
some of them names.Copy !req
638. This one is called Apophis,
after a mythical Egyptian demon,Copy !req
639. a god of darkness
and destruction.Copy !req
640. Discovered in 2004,Copy !req
641. Apophis is the size
of a 100-story skyscraper.Copy !req
642. It weighs about 20 million tons.Copy !req
643. Speeding through space
at 28,000 miles an hour,Copy !req
644. 10 times as fast as a bullet,
it carries almost as much energyCopy !req
645. as all the world's
nuclear weapons combined.Copy !req
646. And we know roughly
where it's headed.Copy !req
647. The precise path
is not yet fully known.Copy !req
648. But on April the 13th, 2029,Copy !req
649. this huge rock is likely to pass
within 23,000 milesCopy !req
650. of the planet's surface,Copy !req
651. close enough
to pass beneath satellitesCopy !req
652. in orbit around the Earth
and give us all a scare.Copy !req
653. Luckily,
there's very little chanceCopy !req
654. that Apophis
will actually hit us,Copy !req
655. but the problem for humanity
is that in space...Copy !req
656. there's always a bigger rock.Copy !req
657. There are thousands of really
large asteroids out here.Copy !req
658. Some are over 10 miles long,
the size of Manhattan.Copy !req
659. An asteroid this size
hits the EarthCopy !req
660. every 100 million years or so.Copy !req
661. The last one struck the Earth
65 million years agoCopy !req
662. and probably was responsible
for wiping out the dinosaurs.Copy !req
663. We don't know when
the next asteroid will strike,Copy !req
664. but if it was big enough,
it could sterilize our planet.Copy !req
665. That would be the endCopy !req
666. of the 5 billion-year-long story
of life on Earth.Copy !req
667. But even if we avoid
such a natural catastrophe,Copy !req
668. we could all too easily end up
destroying ourselves.Copy !req
669. In the last 10,000 years,Copy !req
670. humans have come
to dominate the planet.Copy !req
671. We're so successfulCopy !req
672. that it's tempting to think
we are evolution's grand prize.Copy !req
673. But I believe intelligence
is probably overrated.Copy !req
674. It's not necessarily a good
thing for a species' survival.Copy !req
675. Bacteria have managed without it
for over 3 billion years.Copy !req
676. Intelligence, at least in
our case, leads to technology.Copy !req
677. And there are many ways
technology could wipe us out.Copy !req
678. The most obvious, of course,
the threat from nuclear weapons.Copy !req
679. Even if the risk of a nuclear
war happening in one yearCopy !req
680. is miniscule...
say only one in a million...Copy !req
681. if we run those odds
over 100,000 years,Copy !req
682. the chance of catastrophe
falls to 1 in 10.Copy !req
683. Personally, I worry that even
this might be overoptimistic.Copy !req
684. Although we are clever enough
to have designed such weapons,Copy !req
685. I'm not sure we are
clever enough not to use them.Copy !req
686. As time marches relentlessly
into the future,Copy !req
687. the universe has
other surprises in store.Copy !req
688. There are some powerful things
out there.Copy !req
689. Some of which
could destroy the EarthCopy !req
690. without any help from us.Copy !req
691. As the universe continues
to dance to its ancient rhythm,Copy !req
692. stars will come and go
in a relentless cycle.Copy !req
693. And because there are
hundreds of billions of stars,Copy !req
694. there's always one dying
in a supernova somewhere.Copy !req
695. In our galaxy, for instance,Copy !req
696. a star dies
every 50 years or so.Copy !req
697. Which is but the briefest
of moments to the universe.Copy !req
698. It's just about conceivableCopy !req
699. that a supernova
could damage the Earth,Copy !req
700. if you consider the likelihood
over a long enough time scale.Copy !req
701. One kind of supernova,
discovered entirely by accident,Copy !req
702. is thought to be
particularly dangerous.Copy !req
703. In 1967, when the Cold War
was at its height,Copy !req
704. U.S. military satellites
picked up a massive burstCopy !req
705. of something called
gamma radiation.Copy !req
706. Gamma radiationCopy !req
707. is the most dangerous type
of radiation known.Copy !req
708. It's also the telltale sign
of an atomic weapon.Copy !req
709. Were the gamma rays detectedCopy !req
710. evidence of a new
and powerful Soviet bomb?Copy !req
711. Thankfully, the answer was no.Copy !req
712. After careful analysis
of the data,Copy !req
713. they discovered that
the sudden bursts of gamma raysCopy !req
714. were actually coming from space.Copy !req
715. Not even the Russians
had that kind of technology.Copy !req
716. Decades later,
we still don't have proofCopy !req
717. of what causes
the bursts of radiation.Copy !req
718. But there's
a well-respected theoryCopy !req
719. that they are produced
by a special kind of supernovaCopy !req
720. called a gamma-ray burster.Copy !req
721. What's more,
there might be one quite nearby.Copy !req
722. Hidden within this massive
spiral plume of plasma,Copy !req
723. 8,000 light-years from Earth,
is a star called WR 104.Copy !req
724. Deep inside the star itself
is a bright sphereCopy !req
725. throwing off a shell of hot gas
as it nears its end.Copy !req
726. If this star is what we think
it is, then as it dies,Copy !req
727. it will produce two tightly
focused beams of radiation,Copy !req
728. one from each pole.Copy !req
729. The star destroys itself
as it produces these beams,Copy !req
730. which contain more energyCopy !req
731. than our sun will produce
in its entire life.Copy !req
732. The brightest known phenomena
in the entire universe.Copy !req
733. No one is sure if WR 104
will do thisCopy !req
734. or if the beam
would strike the Earth.Copy !req
735. But if so, we could be bathed
in high-intensity radiation.Copy !req
736. With some devastating
consequences.Copy !req
737. The beam would cause
spectacular auroras,Copy !req
738. stripping the ozone
from the atmosphere,Copy !req
739. allowing deadly radiation from
the sun to strike the Earth.Copy !req
740. It may sound like
science fiction,Copy !req
741. but this could be
the second time skies like theseCopy !req
742. have been seen on our world.Copy !req
743. 450 million years ago,Copy !req
744. over half
of all living creaturesCopy !req
745. were wiped out
in a great extinction.Copy !req
746. One explanation
is that a gamma-ray bursterCopy !req
747. irradiated the planet so badlyCopy !req
748. that Earth's ecosystem
virtually collapsed.Copy !req
749. I don't want to worry anyone,Copy !req
750. but I think
it's definitely a good ideaCopy !req
751. for the human race
to venture far beyond the Earth.Copy !req
752. We would be wise
to keep our eggs...Copy !req
753. in as many baskets
as possible.Copy !req
754. Thankfully, that process
has already begun.Copy !req
755. In my opinion,
the launch of Apollo 11Copy !req
756. is probably the most important
moment in human history.Copy !req
757. It was a turning point
for the universe, too.Copy !req
758. Life, in the form of us,
escaped its home planet...Copy !req
759. and stepped
on another surface.Copy !req
760. The astronauts' footprints
stand preserved to this day.Copy !req
761. A testament to the beginning
of what I thinkCopy !req
762. could be the next chapter
in the story of the cosmos...Copy !req
763. the spread of life
to other parts of the universe.Copy !req
764. As the universe gets older,
we will have to get wiser.Copy !req
765. I think we'll have to go
much further than the moon...Copy !req
766. at the very least, to Mars.Copy !req
767. The red planet is likely to playCopy !req
768. an important part
in our evolution,Copy !req
769. and maybe even
in the story of the cosmos.Copy !req
770. It's the secondCopy !req
771. and possibly the most important
stepping-stoneCopy !req
772. on humanity's journey
to the stars.Copy !req
773. Robot missions to MarsCopy !req
774. have revealed
a spectacularly beautifulCopy !req
775. yet dangerous
and desolate place.Copy !req
776. I imagine that being
a human pioneer hereCopy !req
777. would be an exciting business.Copy !req
778. For a start, it's cold.Copy !req
779. It's 50 million miles further
from the sun than the Earth,Copy !req
780. and so it receives
half as much warmth,Copy !req
781. and the temperatures
fluctuate wildly,Copy !req
782. from 80 degrees...Copy !req
783. to minus 200
in a matter of minutes.Copy !req
784. If the cold doesn't get you,
the low gravity will.Copy !req
785. Mars is just
half the size of the EarthCopy !req
786. and has just 38% of its gravity.Copy !req
787. Over time,
explorers' bones would weaken,Copy !req
788. and their muscles
would waste away.Copy !req
789. Spend long enough on Mars,Copy !req
790. and you could find yourself too
weak to safely return to Earth.Copy !req
791. The low gravity also meansCopy !req
792. Mars struggles to hold on
to an atmosphere.Copy !req
793. Here, there's nothing more than
a thin wisp of carbon dioxideCopy !req
794. at just 1/100 the pressure
of our air.Copy !req
795. Mars is also bathed in harmful
radiation from the sun.Copy !req
796. Even though it's further away,Copy !req
797. unlike Earth,
it has no magnetic fieldCopy !req
798. and no ozone layer
to protect it.Copy !req
799. Early explorers
would have to be carefulCopy !req
800. to minimize their exposure.Copy !req
801. Perhaps they'd even
have to live underground.Copy !req
802. But one day,
I think it'll be possibleCopy !req
803. to drastically alter
conditions on Mars,Copy !req
804. perhaps using
space-borne mirrorsCopy !req
805. to supply warmth and power.Copy !req
806. With perfectly foreseeable
technology,Copy !req
807. much more could become possible.Copy !req
808. If we could erect giant domes
made of glass and plasticCopy !req
809. to block out the radiation,Copy !req
810. inside them,
we could enrich the atmosphere.Copy !req
811. 500 years from now...Copy !req
812. which really is
a very short time indeed...Copy !req
813. I think Mars will have
its own language,Copy !req
814. its own currency,
it's own cuisine.Copy !req
815. Although I'll bet youCopy !req
816. you'll still be able
to get a hamburger somewhere.Copy !req
817. But it's clear that as
the universe continues to age,Copy !req
818. even advances like these
will not be enoughCopy !req
819. to guarantee humanity's
existence for a very long time.Copy !req
820. Look further into the future,Copy !req
821. and ultimately our solar system
will follow the same pathCopy !req
822. as countless billions
of solar systems before itCopy !req
823. and cease to exist.Copy !req
824. Right now, the sun is
in the middle of its life cycle.Copy !req
825. During this phase,Copy !req
826. it is getting gradually
hotter and brighter all the timeCopy !req
827. by about 6% every billion years.Copy !req
828. In about 5 billion years,Copy !req
829. the sun's temperature
will have grownCopy !req
830. to nearly 200 billion degrees.Copy !req
831. At this point, the EarthCopy !req
832. will be an unrecognizable ball
of molten rock,Copy !req
833. all life
having long since perished.Copy !req
834. This is our planet's
unavoidable destiny,Copy !req
835. but that's not all
the sun has in store.Copy !req
836. As it runs out of fuel,
the sun will start to expand,Copy !req
837. turning into what's called
a red giant.Copy !req
838. It will change from being
the object that gave us lifeCopy !req
839. to the one that annihilates it.Copy !req
840. In about 7 billion years, the
sun will be 200 times bigger,Copy !req
841. about 200 million miles across.Copy !req
842. So vast, it will obliterate
the inner planetsCopy !req
843. one after the other.Copy !req
844. Mercury, Venus, and most
probably the lifeless Earth.Copy !req
845. But as the universe
continues to evolve...Copy !req
846. at its own relentless pace,Copy !req
847. new opportunities
will present themselves to us,Copy !req
848. if we are able to preserve
the life that the cosmos made.Copy !req
849. This is Gliese 581d.Copy !req
850. It's a large, rocky, earthlike
planet, the nearest known.Copy !req
851. It's just possible
that this world or one like itCopy !req
852. could, in the future,
become home to the human race,Copy !req
853. a second sanctuary against the
unforgiving blackness of space.Copy !req
854. Discovered in 2007, it's
seven times bigger than Earth.Copy !req
855. It orbits a star smaller
and redder than our own,Copy !req
856. but it lies at just
the right distance from its sunCopy !req
857. to allow water to exist
on the surface.Copy !req
858. But even if this is
the perfect home away from home,Copy !req
859. there is a fundamental problem
we will have to overcome.Copy !req
860. Gliese is a very,
very long way away.Copy !req
861. More than 20 light-years
from Earth.Copy !req
862. That's 120 trillion miles.Copy !req
863. To get some idea
of this extraordinary distanceCopy !req
864. and the challenge it presents,Copy !req
865. I'm going to imagine
that we could hitch a rideCopy !req
866. on the fastest man-made object
in existence.Copy !req
867. Voyager 1 was launched in 1977.Copy !req
868. Now over 30 years old,Copy !req
869. it's traveled
more than 13 billion miles.Copy !req
870. Its mission so far has taken it
to Jupiter and Saturn.Copy !req
871. By using their gravity
to boost its speed,Copy !req
872. the little spacecraft
has entered the record books.Copy !req
873. It might not look fast,Copy !req
874. but Voyager is racing through
space at 11 miles a second.Copy !req
875. On Earth, 11 miles a second
looks like this.Copy !req
876. It's 39,000 miles an hour.Copy !req
877. At this speed,Copy !req
878. we could circle the globe
11/2 times in an hour.Copy !req
879. So, how long
would it take a spaceshipCopy !req
880. traveling at Voyager's speedCopy !req
881. to get to the nearest
earthlike planet, Gliese?Copy !req
882. The answer reveals
the true scale of the cosmos.Copy !req
883. For even traveling
at 11 miles a second,Copy !req
884. the journey to Gliese would
still take over 350,000 years.Copy !req
885. I think we have a chanceCopy !req
886. to become a lasting part
of the ever-changing universeCopy !req
887. and to discover what
other wonders it might hold.Copy !req
888. But to do this, we will have to
develop new technologyCopy !req
889. on an enormous scale.Copy !req
890. And that's going to take
some serious engineering.Copy !req
891. There are many
in the field of cosmologyCopy !req
892. who believe, as I do,Copy !req
893. that finding ways
to travel great distancesCopy !req
894. will be essentialCopy !req
895. to keeping humankind alive
in an aging universe.Copy !req
896. If we could build a machineCopy !req
897. capable of traveling
to other solar systems,Copy !req
898. we'd open up
a fascinating possibility...Copy !req
899. the survival of the human race
for billions of years.Copy !req
900. Present-day engineers
have begun thinkingCopy !req
901. about the principals
of building such a ship.Copy !req
902. This is what it might look like.Copy !req
903. It could use atomic energyCopy !req
904. or perhaps more exotic fuel,
such as antimatter,Copy !req
905. supplying it
with enormous amounts of power.Copy !req
906. Yet I think the main challenges
won't be technical.Copy !req
907. The first will be financial.Copy !req
908. The cost of constructing
an interstellar spacecraftCopy !req
909. would be huge.Copy !req
910. And for the society
that made it,Copy !req
911. there would be little payback.Copy !req
912. They would never see it again.Copy !req
913. So constructing such a machineCopy !req
914. will either be the greatest act
of generosity in history,Copy !req
915. or it will have to be funded
by the travelers themselves.Copy !req
916. And that raises
the second problem.Copy !req
917. Even if it could travel
mind-numbingly fast...Copy !req
918. say 1,000 times faster
than Voyager,Copy !req
919. 11,000 miles a second...Copy !req
920. a journey to the nearest
star system would still take...Copy !req
921. 73 years.Copy !req
922. Such a long trip meansCopy !req
923. that at least one whole
generation of humansCopy !req
924. would have to live
their entire lives in space,Copy !req
925. and we couldn't exactly say they
had volunteered for the mission.Copy !req
926. The ethics of sending
a human cargo on such a voyageCopy !req
927. would have to be
carefully considered.Copy !req
928. Unless we could extend
human life-spansCopy !req
929. to long enough
to make such massive journeys.Copy !req
930. And that, I think, is what
we will ultimately end up doing.Copy !req
931. The process has already begun...Copy !req
932. as I know
from personal experience.Copy !req
933. My muscles no longer function,Copy !req
934. although my eyes and my brain
are still working pretty well.Copy !req
935. But technology helps me
to move and communicate.Copy !req
936. In the future,Copy !req
937. technology will do much more
than that for all of us.Copy !req
938. Within the next 1,000 years,Copy !req
939. we will see
unprecedented changesCopy !req
940. in our physical capabilities.Copy !req
941. Genetic engineering
will give us longer life-spansCopy !req
942. and greater intelligence.Copy !req
943. Modifying our genes
could give us skinCopy !req
944. that protects us from radiation.Copy !req
945. The ability to breathe
poisonous atmospheres.Copy !req
946. Resistance to infection.Copy !req
947. We may even developCopy !req
948. sophisticated
artificial life-forms,Copy !req
949. using synthetic DNA,Copy !req
950. custom-designed for
the challenges of space travel.Copy !req
951. These advances would allow us
to survive long journeysCopy !req
952. and inhospitable worlds.Copy !req
953. I imagine a time
when our descendantsCopy !req
954. spread to planets orbiting other
stars all over our galaxy...Copy !req
955. and perhaps further still,
carrying their biological cargoCopy !req
956. to solar systems
we have yet to discover.Copy !req
957. Ships like this oneCopy !req
958. could be designed
to split up and spread out.Copy !req
959. A true diaspora of life
that would have started with us.Copy !req
960. As we journey
across interstellar space,Copy !req
961. I'm sure that we will unlock
nature's deepest secrets.Copy !req
962. My great hope
is that we will discoverCopy !req
963. how the universe will end
and solve the ultimate mystery.Copy !req
964. Why the universe
ever existed at all.Copy !req
965. I once gave a lecture in JapanCopy !req
966. where I was asked not to mention
the end of the universeCopy !req
967. in case it affected
the Japanese stock market.Copy !req
968. Well, I don't know if or when...Copy !req
969. the universe will end,Copy !req
970. but for those of you who are
nervous about your investments,Copy !req
971. I think it's a bit early
to sell.Copy !req
972. At 13.7 billion years old,Copy !req
973. our universe
is still in its youth.Copy !req
974. The earliest date we
cosmologists think it could endCopy !req
975. is 30 billion years from now.Copy !req
976. There's still
plenty of action to come.Copy !req
977. Even long after our sun has
died, new stars will be born,Copy !req
978. some of which will have
new planets around themCopy !req
979. made of the same atoms
that make you and me.Copy !req
980. Maybe we'll end up as part
of some future alien ecosystem,Copy !req
981. although that's probably
a bit of a long shot.Copy !req
982. What's true is that we are
only the temporary custodiansCopy !req
983. of the particles
which we are made of.Copy !req
984. They will go on to lead
a future existenceCopy !req
985. in the enormous universe
that made them.Copy !req
986. Certainly, gravity will continue
its tireless, incessant work.Copy !req
987. It will go on shaping
the vast strings of galaxiesCopy !req
988. as it has
ever since the big bang.Copy !req
989. Using supercomputers, we can
simulate how gravity, even now,Copy !req
990. causes galaxies
to be attracted to one another,Copy !req
991. resulting in vast,
slow collisions.Copy !req
992. Our galaxy will merge
with its nearest neighbor,Copy !req
993. the Andromeda galaxy,
in around 3 billion years,Copy !req
994. a slow-motion collisionCopy !req
995. that will take place
over 2 billion years.Copy !req
996. The same process is happening
all over the cosmos.Copy !req
997. Entire clusters of galaxiesCopy !req
998. are constantly colliding
and reforming...Copy !req
999. giant collisions as trillions
of stars pull on one another,Copy !req
1000. their vast masses
causing them to spin and dance.Copy !req
1001. Gravity is driving
the cosmic clockworkCopy !req
1002. as it has done
ever since the big bang.Copy !req
1003. This is what
the universe looks likeCopy !req
1004. when we are released
from time on a human scale.Copy !req
1005. But will this cosmic whirlpool
go on forever...Copy !req
1006. as an endless maelstrom
of mass and energy,Copy !req
1007. space and time?Copy !req
1008. What an extraordinary question
to even be able to ask.Copy !req
1009. I think the solution
lies back where we began.Copy !req
1010. With the big bang.Copy !req
1011. Ask yourself this.Copy !req
1012. What caused the expansion
or inflation of the universeCopy !req
1013. in the first place?Copy !req
1014. When we can answer that and
fully understand the big bang,Copy !req
1015. we will also learn
the fate of the universe.Copy !req
1016. The key to it all
is something called dark energy,Copy !req
1017. a mysterious form of energy
that pushes space itself apart,Copy !req
1018. even as gravity
is making matter clump together.Copy !req
1019. It seems as if dark energyCopy !req
1020. supplied the kick
that inflated the universe,Copy !req
1021. although
we're not quite sure how.Copy !req
1022. What is certain is that
the fate of the universeCopy !req
1023. depends on how
this dark energy behaves.Copy !req
1024. If the dark energy
slowly weakens,Copy !req
1025. then gravity
could get the upper hand,Copy !req
1026. and in 20 billion years or so,Copy !req
1027. the universe
would go into reverseCopy !req
1028. and drive everything back
to whence it came.Copy !req
1029. In a strange reversal
of the big bang,Copy !req
1030. space itself would contract.Copy !req
1031. This theory is known
as the big crunch.Copy !req
1032. In the end,
if the theory is right,Copy !req
1033. in 30 billion years from now,
all the matter of the universeCopy !req
1034. would be swallowed
by a single black hole.Copy !req
1035. The entire universe would exist
as one tiny point,Copy !req
1036. much as it was at the instant
of the big bang.Copy !req
1037. But although
that's a neat ending,Copy !req
1038. I think that it's more likely
that dark energyCopy !req
1039. will drive
the expansion of the universeCopy !req
1040. forever.Copy !req
1041. And that, ultimately, everything
will just keep spreading outCopy !req
1042. until the universe is cold and dark.Copy !req
1043. Everything will become so far apart
that even gravity will be defeated.Copy !req
1044. I think a big chill is what we've
got in store, not a big crunch.Copy !req
1045. So will this be the end of us
and life as we know it?Copy !req
1046. Or will we have figured out how to navigate
to a new universe before then?Copy !req
1047. I think we will only know
when we truly understandCopy !req
1048. why the universe exists at all.Copy !req
1049. Perhaps then, when we finally unravel
the whole cosmic puzzle,Copy !req
1050. we will become masters
not just of our universe,Copy !req
1051. but the universe next door.Copy !req