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以下是埃隆·马斯克今晚关于 #TERAFAB 的完整演讲，开头的等待时间已剪掉。

https://x.com/SawyerMerritt/status/2035544390593044838

中文 English

0:00 我们必须探索宇宙，这就是推动人类未来加速的动力。

0:04 未来。

0:05 理解宇宙，将意识之光延伸至星辰。

0:08 向星辰。

0:30 [音乐]

1:00 我们有一个非常重要的公告，这是迄今为止最史诗级的芯片制造工程。

1:29 这将真正把事情提升到一个新的高度。

1:39 一个大多数人现在甚至想不到的级别。

1:43 这不是他们现有认知范围内的问题。

1:48 所以我们将把认知范围提升好几个数量级。

1:54 这是共同的努力，我按了按钮，但没反应。

1:55 哦，开始了。是的，我们的目标是成为星际文明。

2:04 我认为大多数人都同意，最激动人心的未来是我们能在星辰之间自由穿梭，

2:15 不再被局限在一颗星球上，成为多星球物种，就像你读过的最棒的科幻小说，

2:28 比如《星际迷航》、巴恩斯、阿西莫夫或海因莱因的作品，

2:32 我们

2:33 想把这变成现实，不只是小说，而是把科幻变成现实。

2:39 这就是我期待的辉煌未来。

2:40 值得思考如何评估文明，有个物理学家卡尔达肖夫在60年代提出，

2:49 他想了想，

2:50 如何从高层次评判文明，他说一旦成为一型文明，就能利用行星上的大部分能量。

3:00 但我们

3:00 还差得远，目前我们只用到了到达地球的太阳能量的一小部分。

3:09 地球只接受了太阳能量的约五亿分之一。

3:10 太阳真是巨大，占据了太阳系总质量的99.8%。

3:18 有时有人问我，地球上的其它能源如核聚变如何？

3:26 不幸的是，这很微小，因为太阳系质量中太阳占99.8%。

3:31 木星占0.1%，地球属杂项。

3:33 卡尔萨根曾说地球是浩瀚黑暗中的一粒尘埃，非常非常小。

3:38 所以

3:39 要让文明规模扩大，就必须扩大太空中的能源利用。

3:47 这点必须如此，

3:48 因为地球只能捕获极小部分太阳能，

3:52 我们只是这一粒尘埃。

3:53 地球上全部文明的电力产出仅占太阳能的万亿分之一，

3:58 如果文明能量提升一百万倍，也只到太阳能的百万分之一。

4:04 想想看，真的令人敬畏。这显示了我们的渺小。

4:10 我们总是陷在地球上的琐事里，

4:13 但在宇宙宏伟面前，那些都微不足道。

4:19 因此，考虑宇宙的宏大和我们能做的伟大之事非常重要，

4:22 而不是

4:23 为地球上的小事烦恼，

4:24 没多大意义。

4:27 我们要成为一个能扩展到银河系的文明，拥有任何人随时可去任意地方的飞船，那将史诗般辉煌。

4:36 在月球、火星建城，

4:37 遍布整个太阳系，向其他星系派遣飞船。

4:42 这就是我能想象的最美好未来。

4:49 为了实现，

4:50 我们需要捕获太阳能量。

4:53 尽管一年一太瓦计算能力超大，

4:55 在文明标准上巨大，

4:58 但仍只是迈向星际文明的一个步骤。

5:05 要实现这个艰巨目标，需要SpaceX、XAI和Tesla的共同努力。

5:13 这才是

5:14 这个史诗级太瓦工厂计划的核心。

5:18 Tesla、XAI和SpaceX都创造了别人认为不可能的奇迹。

5:24 比如

5:25 Gigafactory Texas，Optimus机器人，全球超级充电网络，还有很多。

5:30 人们曾认为电动车无望，

5:31 Tesla创立时几乎无电动车出售，大家说不可能做到，现在Tesla一年造200万辆电车。

5:38 XAI是SpaceX旗下新公司，

5:39 创建了首个千兆瓦规模计算集群，速度之快让NVIDIA Jensen Wong震惊。

5:42 SpaceX的可重复使用火箭更是历史突破，曾被认为不可能或经济上不可行。

5:48 我们做到了，还让它经济可行，已回收500多次，

5:52 完成了猎鹰重型火箭，现在开发星舰。

5:56 星舰是关键，因为要扩展计算力和能量，必须进入太空，

6:03 需要大载荷发射量，

6:05 星舰将实现这一目标。

6:09 这里只给你个规模感。

6:10 Optimus机器人大约5尺11寸，展示星舰V3型号的巨大体积。

6:17 V4将更长，

6:18 让V3看起来短小。

6:25 V3载重升至200吨，

6:26 之后将启动V4型号。

6:33 这是AI微型配置示意，

6:34 约100千瓦，展示了太阳能帆板和散热器比例。

6:39 关于太空散热器也曾有奇怪争论，SpaceX发射了一万颗卫星，肯定懂太空散热。

6:46 散热器相对于太阳能板很小，

6:47 这就是“微型组”配置，仅100千瓦。

6:49 未来卫星功率预期达到兆瓦级别，

7:00 太瓦计算每年需要大约1000万吨载荷发射，

7:04 按每吨100千瓦计算。

7:12 我们确信可行，

7:13 不需新物理或不可能的事。

7:20 我有信心SpaceX

7:21 能实现每年1000万吨上轨。

7:22 接着我们积累到一年一太瓦太阳能，

7:26 解决发电问题。

7:27 接下来关键是实现一太瓦计算能力。

7:30 此次发布就是为了解决这个关键缺失。

7:38 当前AI计算年产能大约20吉瓦，

7:39 图表显示这为何需要建造太瓦级规模。

7:45 地球现有所有芯片厂产能加起来仅达需求的2%。

7:51 我们非常感谢现有供应链，三星、台积电、美光等，

7:56 希望他们能尽快扩展，我们也将买尽所有芯片。

8:02 我亲口告诉他们这话，但他们扩产速度远低于我们需求。

8:10 所以只有建设太瓦芯片厂，才能满足需求，我们必须这样做。

8:18 我们将在奥斯汀建造先进制程芯片厂。

8:26 感谢德克萨斯州州长阿博特及德州对我们的支持。

8:34 该芯片厂将拥有制造任何类型逻辑及内存芯片的全部设备，

8:40 同时配备光刻掩膜制造设备。

8:46 在一栋建筑内完成掩膜设计、芯片制造、测试，再改进掩膜，循环优化。

8:53 据我所知，

8:54 全球没有任何这样集成的芯片设计制造测试基地。

9:00 我们还将尝试非常新奇的物理计算方式，并有信心成功。

9:07 拥有快速迭代的循环，使得变更设计快速实施极为重要。

9:12 这种方式让我们改进芯片设计的速度至少领先全球一个数量级。

9:18 我们预计制造两类芯片：一种为边缘推理优化，主要用于Optimus机器人和汽车，

9:30 预计人形机器人产量将是汽车的10至100倍。

9:37 汽车年产量约一亿台，人形机器人预计为十亿至百亿台。

9:41 这是巨大数字，Tesla目标是生产其中很大一部分。

9:49 另一类芯片则高功率设计用于太空环境，考虑太空中高能粒子、光子和电子积累的严苛条件，

9:57 并且芯片需比地面运行温度高以减少散热器重量。

10:04 太空芯片设计与地面不同，有许多特殊约束。

10:10 估计太空芯片计算需求占大多数，地面受限于功率，预计年产100至200吉瓦地面芯片，

10:18 太空芯片则可能达到一太瓦规模。

10:27 太空优势在于常年光照，无需大量电池，太阳能至少是地面五倍，

10:35 且无大气衰减、昼夜交替和季节变化，且面朝太阳最大化收能。

10:41 太空太阳能成本低于地面光伏，不需厚玻璃或重型框架防极端天气。

10:48 一旦轨道发射成本大幅降低，放AI计算到太空就极具吸引力，

10:54 这将成为必然选择。

11:00 太空规模经济递增，事半功倍；而地面空间耗尽，难以扩充，

11:10 易引发居民反对，成本反而增加。

11:18 这非常重要。

11:28 接下来是你可能想的“太瓦之后怎么办？”答案是——不要局限于现状，

11:48 实现拍瓦级别需在月球建电磁质驱动器，利用机器人与人类合作发射千万瓦级计算资源至深空，

12:00 月球无大气，重力仅地球六分之一，发射无需火箭，可直接加速至逃逸速度，

12:11 大幅降低成本，能让规模扩展千倍超过一太瓦。

12:22 我希望能活着见证月球质驱动器的诞生，那将极其壮观。

12:29 这预示着我们能获取太阳能的百万分之一，是地球经济的百万倍，

12:36 从这个视角看非常可观。

12:42 从月球出发扩展到其他行星和恒星，创造我能想象的最激动人心未来。

12:48 [掌声欢呼]

12:52 这画面有点像电影《愚人国》开场，带来令人惊叹的丰盈。

12:58 实现可持续能源、太空旅行、AI与机器人，将带来惊人的丰裕。

13:11 这几乎是通往丰裕世界的唯一道路，虽然可能出错，但我相信会成功，

13:17 这是你会喜欢的未来，也是我能想象的最佳未来。

13:25 然后，我们超越月球、火星，穿越土星环。

13:32 如果能买到土星之旅，

13:33 或者干脆就去土星旅行，

13:36 那该多棒！

13:40 未来物资可能免费，

13:41 听起来疯狂，但如果AI机器人经济达到地球经济的一百万倍，

13:47 任何需求都能满足，

13:50 想得到的都能拥有。

13:54 《文化》书中描述未来不存在钱，人人丰裕，

13:59 能想到就能拥有。

14:04 任何人都能去土星旅行，不是少数特权。

14:08 加入我们，一起设计制造非凡飞船，建设一太瓦计算、一太瓦太阳能，

14:18 每年千万吨载荷发射。

14:20 谢谢大家。

0:00 You must explore the universe, and that's the motivation to accelerate humanity

0:04 's future

0:05 in understanding the universe and extending the light of consciousness to the

0:08 stars.

0:30 [Music]

1:00 Well, we have a profoundly important announcement to make, which is the most

1:29 epic chip building exercised in history by far.

1:39 This is really going to take things to the next level.

1:43 So, yeah, a level of probably people aren't even contemplating right now.

1:48 This is not in the, I'd call this sort of an out-of-context problem.

1:54 It's not in their context.

1:55 So we're going to adjust the context by a few orders of magnitude here.

2:04 It's a joint effort, I'm pressing the button, but the button's not working.

2:15 Oh, there we go, okay, so, yeah, we aspire to be a galactic civilization.

2:28 So I think the future that everyone, well, most people, I think, would agree is

2:32 the most

2:33 exciting, is one where we are out there among the stars, where we are not

2:39 forever confined

2:40 to one planet, that we become a multi-planet species, like the best science

2:49 fiction that

2:50 you've ever read, you know, Star Trek or in banks or Asimov or Heinlein, and we

3:00 want

3:00 to make that real, yeah, not just fiction, turn science to fiction to science

3:09 fact.

3:10 That's the glorious, exciting future that I certainly look forward to.

3:18 And it's worth considering sort of, like, how would you rate civilizations?

3:26 You know, there's, so there was a physicist, I think it was Russian, in the '60

3:31 s, Kardashev,

3:33 he thought about, at a high level, how would you consider any given

3:38 civilization?

3:39 And he said, well, if you're type one, you're using most of the energy of your

3:47 planet.

3:48 And we actually still have quite a ways to go to be properly a type one, we're

3:52 still

3:53 using a tiny fraction of the sun's energy that reaches our planet.

3:58 Let's see, yeah, there we go.

4:04 But the Earth only receives about half a billionth of the sun's energy.

4:10 So the sun is truly enormous.

4:13 The sun is 99.8% of all mass in the solar system.

4:19 So sometimes people will ask me, like, what about, you know, other power

4:22 sources of power

4:23 on Earth?

4:24 Like, what about fusion on Earth?

4:27 Well, that is unfortunately very small because the sun is 99.8% of mass in the

4:36 solar system.

4:37 And Jupiter is about 0.1% and Earth is in the miscellaneous category.

4:42 We are, I think it's Carl Sagan I think might have said, Earth is like a tiny

4:49 dust moat

4:50 in a vast darkness.

4:53 Very, very small.

4:55 The sun is enormous.

4:58 So the way to actually scale civilization is to scale power in space.

5:05 This is necessarily true because we actually capture such a tiny amount of the

5:13 sun's energy

5:14 on Earth because we're just this tiny dust moat.

5:18 Another way to think of it is roughly like electricity production on Earth of

5:24 all of

5:25 civilization is only about a trillionth of the sun's energy, which means if you

5:30 increase

5:31 civilizational power output by a million, you would still only be a millionth

5:38 of the sun's

5:39 energy.

5:42 I mean, it's awe-inspiring to consider that.

5:48 Just how tiny we are in the grand scheme of things.

5:52 And yeah, we often get sort of caught up in the sort of these sort of squabbles

5:56 on Earth

5:56 that are really very sort of minor things when you consider the grandness of

6:03 the universe.

6:05 And so I think it is important actually to consider the grandness of the

6:09 universe and

6:10 what we can do that is much greater than what we've done before as opposed to

6:17 worry

6:18 about sort of small squabbles on Earth type of thing, kind of not much point in

6:25 that.

6:26 Yeah, we want to be a civilization that expands to the galaxy with spaceships

6:33 that anyone

6:34 can go anywhere they want at any time, that would be epic.

6:39 And have a city on the moon, cities on Mars, populate the solar system and send

6:46 spaceships

6:47 to other star systems.

6:49 That sounds like the best possible future.

7:00 So to do that, we need to harness the power of the sun.

7:04 And so a terrafab, while it is enormous, a terrawad of compute for a year is

7:12 enormous

7:13 by our sort of civilizational standards, it is still just one step along the

7:20 way of being

7:21 even a watershed.

7:22 You still have a long way to go to even be a watershed to level civilization

7:26 and you're

7:27 not even registering as a watershed three.

7:30 So it's a very big thing by current human standards, but still small in the

7:38 grand scheme.

7:39 And it's very difficult for humans, so to accomplish this very difficult goal

7:45 really

7:46 requires a combination of efforts of SpaceX, XAI and Tesla working together to

7:53 create this

7:54 epic terrafab project.

8:02 And Tesla and XAI and SpaceX have all done amazing things that people did not

8:10 think would

8:11 be done before.

8:13 So there's the gig of Texas BAB here, there's the optimist robot that's being

8:21 built, there's

8:22 a global supercharging network, there's really quite a lot.

8:29 And it wasn't that long ago when people thought electric cars wouldn't amount

8:33 to anything.

8:34 And there were basically no electric cars for sale when Tesla started.

8:41 And people said it was impossible and now Tesla's making 2 million electric

8:44 cars a

8:45 year.

8:52 And then XAI, although it's a new company, now part of SpaceX, has also built

8:57 the first

8:57 gigawatt scale compute cluster, which in record time, Jensen Wong from NVIDIA

9:05 said he's never

9:06 seen anything built so fast in his life before.

9:08 So a great complement from NVIDIA.

9:12 And then SpaceX, well, he gets to get rid of yourself, I'm all you already know

9:18 .

9:18 I mean, the reusable rockets, people said that reusable rockets weren't

9:22 possible and

9:23 even if you did do them, they wouldn't be economically feasible.

9:26 So we did them and then we made them economically feasible.

9:30 And now we've landed over 500 times.

9:34 And then we did the Falcon Heavy, and now we're doing Starship.

9:38 And Starship is a critical piece of the puzzle because in order to scale

9:44 compute and scale

9:45 power, you have to go to space, which means that you need massive payload to

9:51 space.

9:51 And Starship will enable that.

9:57 So this gives you just a sense of scale.

10:00 We've got Optimus there, Optimus for scale.

10:07 And Optimus is about 5'11", so it gives you a sense of the size of the Starship

10:13 V3 rocket.

10:15 Starship V4 will be much longer, actually.

10:17 The Starship V4 will make Starship V3 look kind of short.

10:24 So we'll expand with Starship V3 to 200 tons of payload to orbit from 100 tons.

10:30 We'll start with V3.

10:32 And then you can see that's just a rough approximation of the AI, the mini

10:38 version of

10:39 the AI set.

10:40 So that's roughly 100 kilowatts, it's showing the solar panels and the radiator

10:47 to scale.

10:48 So for some reason there's been a bizarre debate about radiators in space.

10:54 It's safe to say SpaceX knows how to do heat rejection in space with 10,000

10:59 satellites

11:00 in orbit.

11:01 Might know a thing or two.

11:04 So you can see the radiator is actually quite small relative to the solar

11:09 panels.

11:10 And we call that the mini set since that's just 100 kilowatts.

11:15 We expect future satellites to probably go to the megawatt range.

11:24 So in order to get to the terawatt of compute per year, you need about 10

11:35 million tons

11:37 to orbit per year and at 100 kilowatts per ton.

11:41 So we're confident this is feasible, like no new physics or impossible things

11:47 are required

11:48 to get there.

11:49 So I'm confident that SpaceX will get to 10 million tons to orbit per year.

11:56 And then we're building up to a terawatt of solar.

12:00 So that solves the, we'll solve the solar problem, the power generation.

12:04 So then the key missing ingredients is therefore a terawatt of compute.

12:11 So this announcement is about solving the key missing ingredient.

12:17 To give you a sense of what we're talking about, the current output of AI

12:27 compute is

12:29 roughly 20 gigawatts per year.

12:35 This chart explains why we need to build the terawatt.

12:41 Because all of the rest of the output from Earth is about 2% of what we need.

12:49 So if you add up all the fabs on Earth combined, there are only about 2% of

12:55 what we need for

12:57 the terawatt project or terawatt project.

13:01 So you know, we certainly want our existing supply chain to be clear.

13:11 We're very grateful to our existing supply chain, to Samsung, TSMC, Micron and

13:18 others.

13:19 And we would like them to expand as quickly as they can.

13:24 And we will buy all of their chips.

13:27 I have said these exact words to them.

13:31 But there's a maximum rate at which they're comfortable expanding, but that

13:38 rate is much

13:39 less than we would like.

13:41 And so we either build the terafab or we don't have the chips.

13:48 And we need the chips.

13:49 So we're going to build the terafab.

14:00 And we're starting off with an advanced technology fab here in Austin.

14:06 And I believe that Governor Abbott is in the audience.

14:14 I'd like to thank Governor Abbott and the State of Texas for their support.

14:24 So in the advanced technology fab, we will have all of the equipment necessary

14:29 to make

14:30 a chip of any kind, logical memory.

14:32 And we will also have all of the equipment necessary to make the lithography

14:37 masks.

14:38 So in a single building, we can create a lithography mask, make the chip, test

14:44 the chip, make another

14:46 mask, and have an incredibly fast, recursive loop for improving the chip design

14:53 .

14:54 The best of my knowledge, this doesn't exist anywhere in the world, where you

14:57 've got everything

14:58 necessary to build logic, memory, and do packaging, and test it, and then do

15:05 the masks, improve

15:06 the masks, and just keep looping it.

15:10 So we're not just going to do conventional compute in this.

15:14 I think there's some very interesting new physics that is potentially -- that I

15:20 'm confident

15:21 it will work, which is a question of one.

15:24 So this is really going to push the limit of physics in compute.

15:29 And we're going to try a bunch of wild and crazy things, which you can do if

15:33 you've got

15:34 that fast iteration loop that I can't emphasize enough the importance of being

15:39 able to make

15:40 a chip, test it, and then change the design, do another one, and have that in a

15:48 single

15:49 building.

15:51 I think that our recursive improvement with that situation is probably an order

15:58 of magnitude

16:00 better than anything else in the world.

16:07 So broadly speaking, we expect to make two kinds of chips.

16:19 One will be optimized for edge inference.

16:25 So that will be used primarily in optimists and in the cars.

16:29 Especially in optimists, because I expect the human right robots to be made 10

16:37 to 100 times

16:38 more than the volume of cars.

16:41 So if vehicle production -- vehicle production is about 100 million vehicles a

16:48 year, and

16:49 I expect human right robot production to be somewhere between a billion and 10

16:52 billion

16:53 units a year.

16:54 So that's a lot.

16:58 So yeah, Tesla's going to make a very significant percentage of those is our

17:06 goal.

17:07 And then we need a high-power chip that is designed for space that takes into

17:16 account

17:17 the more difficult environment in space, where you've got high power, you've

17:23 got high-energy

17:23 ions, photons, you've got electron buildup, it's a hostile environment in space

17:28 .

17:28 So you want to design the chip, you want to optimize it for space, and you also

17:35 want to

17:35 generally run it a little hotter than you would normally run a chip on Earth to

17:39 minimize

17:40 the radiator mass.

17:41 So there's just a bunch of constraints that would -- you designed something

17:46 differently

17:46 in space than you would on the ground.

17:50 And for the space compute, my guess is that is the vast majority of the compute

17:57 , because

17:58 you're power constrained on Earth.

18:01 That's why I think it's probably 100 to 200 gigawatts a year of terrestrial

18:10 chips, and

18:11 probably on the order of a terawatt of ships in space.

18:18 Just because of power constraints on the ground, that's probably how it ends up

18:27 .

18:28 Space has this advantage that it's always sunny, it's very nice.

18:35 So I actually think that the cost of AI and deploying AI in space will drop

18:41 below the

18:42 cost of terrestrial AI much sooner than most people expect.

18:46 I think it may be only two or three years before it is actually lower cost to

18:54 send AI

18:55 chips to space than it is on the ground.

18:58 Because in space you don't need much in the way of batteries because of it's

19:04 always sunny.

19:05 And the solar power, you're going to get at least five or more times the solar

19:10 power

19:11 you get in space versus the ground, because you don't have atmospheric atten

19:15 uation or

19:15 a day/night cycle or seasonality.

19:19 And you're always normal to the sun.

19:22 So you're really maximizing the solar power at that point.

19:27 And the space solar actually costs less than terrestrial solar, because you don

19:32 't need

19:32 heavy glass or framing to protect it from extreme weather events.

19:38 So as soon as the cost to orbit drops to a low number, it immediately makes

19:45 extremely

19:46 compelling sense to put AI in space.

19:50 It becomes a no-brainer, basically.

19:53 As you go to space, you get increased economies of scale and things get easier

19:59 over time, whereas

20:00 as you try to put more and more power on the ground, you run out of space and

20:04 you start

20:05 using up the easy spots, and then you get next-level numbi.

20:11 Nobody wants the thing in their backyard.

20:13 So actually, increasing power on Earth has become harder over time and more

20:21 expensive

20:22 over time, but in space it becomes actually cheaper and easier over time.

20:28 These are very important points.

20:41 Yeah.

21:11 So, yeah.

21:41 So, yeah.

22:11 So, what you just thought there was, because of course you're asking what's on

22:34 your mind

22:35 is, "Well, what do you do after a Terafab?"

22:45 Don't think small.

22:48 Well, yeah.

22:49 Good point.

22:50 So, we -- you know, how do you get to a petawat is the obvious next question.

22:54 And you get there by having an electromagnetic mass driver on the moon with

23:01 robots, with

23:03 octomy, and obviously lots of humans, and with that you can send a petawat --

23:11 you can create

23:12 a petawat of compute and send that to deep space, because on the moon, moon has

23:18 no atmosphere

23:19 and has one sixth Earth gravity, so you can -- you don't need rockets on the

23:24 moon.

23:24 You can literally accelerate it to escape velocity from the surface.

23:32 And that dramatically drops the cost once a game of harnessing power, and

23:41 enables you

23:42 to go a thousand times bigger than a terawat.

23:49 So, for sure the future, I want to see -- I want to just live long enough to

23:54 see the mass

23:55 driver on the moon, because that's going to be incredibly epic.

24:00 [ Applause and Cheering ]

24:11 That should hopefully get us to a millionth of the sun's energy, at least, hum

24:16 bling to

24:16 think about that.

24:18 But a millionth of the sun's energy would be a million times bigger than Earth

24:22 's economy,

24:23 so it's good from that perspective.

24:29 And then, yeah, you expand beyond that to the planets, to the other stars, and

24:36 create the

24:38 most exciting possible future that I can imagine.

24:48 [ Applause and Cheering ]

24:52 This looks a bit like the opening in idiocracy with the mic judge, unlocking an

24:58 edge of amazing

24:58 abundance.

25:02 So, yeah, obviously the elements of that are sustainable energy, space travel,

25:11 and AI and

25:12 robotics that bring amazing abundance to everyone.

25:17 And it's really the only path to amazing abundance is AI and robotics, which is

25:25 not

25:25 say it can't go wrong, hopefully, but I think it'll probably go right, and it

25:30 'll be a future

25:31 that you love.

25:35 And it's the best future I can think of, at least.

25:42 And then, we go beyond the moon, beyond Mars, and we sail through the rings of

25:48 Saturn.

25:49 It wouldn't be amazing if you could buy a trip to Saturn, or frankly, if you

25:54 just have

25:55 a trip to Saturn.

25:56 I think things will be free in the future, it sounds nuts, but, you know, if

26:00 you've got

26:01 an AI robotics economy that is anywhere close to a million times the size of

26:06 the current

26:07 Earth economy, literally any need you possibly want can be met.

26:12 If you can think of it, you can have it.

26:14 But I think in banks, in its culture books, has pretty much right where there

26:19 actually

26:19 isn't money in the future, and there's abundance for everyone.

26:24 If you can think of it, you can have it, that's it.

26:28 Which means anyone could have a trip to Saturn, it won't be, you know, just a

26:32 few people.

26:33 If you want it, you can have it.

26:42 Yeah, join us on this journey, and help us design incredible ships, and make

26:50 incredible

26:52 ships, and build a terawatt of ships, a terawatt of solar, and tell million

26:59 tons to orbit per

27:01 year.

27:02 Thank you.

Moon

· 2h

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https://x.com/SpaceX/status/2035542868790558771?s=20