Elon Musk

[Fake Messiah]

Elon Musk Compares His Work to Miracles Performed by Jesus Christ

Speaking by video link at an event in Israel this week, as spotted by MarketWatch, Musk complained that his brain-computer interface company Neuralink doesn’t get the credit it deserves.

“Restoring control of people who are tetraplegics and restoring sight I think are pretty big deals,” Musk boasted. “They’re sort of what I might call Jesus-level technologies.”

It’s true that Musk has hyped up the possibility of restoring vision to the blind and movement to the paralyzed through future Neuralink tech, but the company has yet to show any evidence of those type of breakthroughs. And we’re not aware of any plans by the billionaire to bring the dead back to life.

This falls into is a long pattern of braggadocio by the world’s wealthiest man, who often makes bombastic claims that elevate his actual accomplishments into outrageous mythmaking.

https://futurism.com/future-society/elon...ares-jesus

[Fake Messiah]

Are you still one of those that think Elon Musk may be a dick, but at least he's a genius engineer and scientist and that his spaceships have a promising future of delivering humans to the Moon, Mars, and to the end of the universe, instead of him just lying to everyone about his capabilities and boasting about himself just so he can pump stocks of his companies? Then you NEED to read this article.

Starship Is Going Nowhere

One of the few upsides to SpaceX’s rapidly approaching IPO is that we finally get to glimpse the murky world of its obscure finances. They are legally obligated to show us how cash moves through this beast, and the picture painted by the recent filings is not pretty. You see, from orbital data centres to Starlink, NASA missions, and even Musk’s fabled anarcho-capitalist feudal settlement on Mars, Starship is critical to unlocking SpaceX’s future. Yet, these IPO filings only highlight that it is a biblically expensive mess going nowhere fast. But I don’t think people realise just how damning this revelation is, because it proves that Starship is nothing more than a hopeless money pit.

Reuters reported that, according to SpaceX’s IPO filings, the company has spent more than $15 billion on Starship so far. That validates my previous estimate that Starship “costs are close to $10 billion, if not significantly more”. Now, in our current crazy times, that might not sound especially expensive, but it is. For some context, Falcon 9 cost just $400 million to develop, and the initial budget for Starship was $5 billion. So, Musk has already blown the budget more than two times over.

Yet, Starship isn’t even close to finished, let alone being a viable, functional launch vehicle.

The only real targets it has achieved so far are completing a suborbital flight, reaching orbital velocity (but not orbit), landing and relaunching the booster (which is much easier than the upper stage), and conducting a splashdown landing of the upper stage. For spending three times the initial budget, that is pathetic progress.

So, how far does Starship have to go?

Well, Starship has two main use cases.

The easiest and simplest is launching Starlink satellites into LEO (Low Earth Orbit). For Starship to be a viable and profitable way to launch Starlink satellites, it needs to reach LEO with its promised 100-ton payload, land both stages, and ensure both stages are rapidly reusable with virtually no maintenance costs. That way, it will be able to launch around 40 Starlink V3 satellites per launch for a nominal cost of $70 million per launch. This would reduce the cost of launching Starlink satellites by roughly over 200%, enabling Starlink to firmly operate at a profit, not just a positive EBITDA.

The much more difficult use case is for out-of-orbit flights like NASA’s Artemis missions and Musk’s Mars missions. This is because Starship can’t travel directly to these planets; it needs to use other Starships to refuel in LEO. This creates quite a complex and highly risky mission profile. First, a ‘depot’ variant of Starship is sent into orbit, then multiple ‘tanker’ variants of Starship shuttle fuel to the depot, 100 tons at a time, until the depot is full. After this, the Mars/Moon-bound Starship launches to LEO, rendezvous with the depot, fully refuels itself from the depot, and then fires off to its destination. Each Starship variant will have complex, unique systems, and each fuel transfer will carry a risk of a mission-ending catastrophic explosion. As such, this mission profile is significantly more complex than a simple Starlink launch.

So, what targets does Starship need to meet to be able to conduct Starlink launches, and how many more do they need to meet to pull off Moon/Mars missions?

In truth, there are loads of targets, and they are much harder to achieve than what SpaceX has accomplished so far.

So, let’s go through them, shall we?

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1. Reach Orbit

Starship needs to actually reach orbit. So far, the most it has achieved is take 16 tons on a transatmospheric flight at orbital velocity. ‘Transatmospheric’ means it just skimmed the upper atmosphere, so it reaches a lower altitude than ‘suborbital’, which in itself is (typically) lower than required to reach proper orbit. Transatmospheric and suborbital flights, even at orbital velocities, can’t deploy satellites into orbit. But this isn’t as simple as it might sound, given that rockets have to expend kinetic energy (speed) in order to gain altitude. So, even though Starship has reached orbital velocity, it needs to expend a lot more energy to reach orbit, which requires burning more fuel — and, crucially, Starship might not have this fuel available. The extra fuel required to take Starship from its current transatmospheric path up to LEO is roughly 20 tonnes, which suggests that Starship can currently reach only the lowest possible orbit if it carries no payload! So as it stands, just reaching orbit is a potentially difficult target to meet.

2. Increase Payload

Getting to orbit alone isn’t enough to make Starship viable; it has to actually carry stuff there, and for the economics to work out, it needs to meet its target payload-to-LEO of 100 tons. So, Starship needs to transition from a max payload of 16 tons on a non-orbital flight to 100 tons, or sixfold its current payload, on an orbital flight.

That would be a monumental leap for SpaceX. Is there any evidence in SpaceX’s past that suggests they can increase payloads to this degree? Well, not really. In other words, there is very little precedent for SpaceX, let alone the entire rocket industry, to dramatically increase the payload of a rocket without a total redesign, let alone increase it by over sixfold. I cannot overstate the size of this challenge, especially when making Starship bigger alone won’t solve it.

3. Deploy Payload To Orbit

Starship is a large, unregulated vehicle that is still suffering from engine failures during ascent. These issues can cause rockets to deliver satellites to the wrong orbit, which is simply not acceptable. So, not only does SpaceX need to get Starship into orbit and then somehow increase its payload to a colossal 100 tons, it also has to solve these reliability and accuracy issues so that it can actually be useful for delivering payloads, not just taking them on a scenic flight.

4. Land And Catch Upper Stage

To reduce weight by removing the landing legs and increase landing precision, SpaceX has opted for both of Starship’s stages to land using ‘chopsticks’. Essentially, the rocket has to come to a hovering stop just above the landing pad, and two giant arms will catch it in mid-air. It is an impressive technical feat, as you have to be pinpoint precise, and SpaceX has proven they can handle it with the Super Heavy Booster. But, if they want Starship to be a fully reusable rocket (which the economics of the rocket entirely depend upon), then they need to catch the upper stage, too.

You might think landing the booster and the upper stage are similarly difficult tasks, but that isn’t the case. The upper stage will land at three times the velocity, meaning the amount of kinetic energy that has to be scrubbed off compared to landing the booster is enormous. On top of that, it has to re-enter the upper atmosphere, which adds incredibly complex fluid dynamics to the equation. The forces involved are immense, and even a slight error could shift the landing spot by tens of metres. Despite these challenges, it seems SpaceX has nearly got this down to a tee, with recent upper-stage splashdowns being just 3m from the target landing spot. That is impressive, but potentially too inaccurate to catch the upper stage.

5. Reuse Upper Stage

It’s one thing to land a rocket and another thing to send it back up into the heavens. To do that, the rocket needs to be, at the very least, salvageable. Considering the difficulty SpaceX has experienced with the upper stage’s heat shields (with more on that topic in a second), this could be a much more troublesome issue to overcome than you might think, as critical structures and systems appear to be regularly exposed to excessive and damaging heat during landing thanks to heat shield failures.

6. Reduce Failure Rate

Starship’s latest version (V2) had a 60% failure rate, with Launches 7, 8 and 9 exploding in the sky, with the transatmospheric Launches 10 and 11 being considered ‘successful’. That is an abysmal track record. No one in their right mind, not even Elon, would use such a rocket to put even the cheapest satellite into orbit, because the risk of losing it in a fiery inferno is greater than it actually reaching its destination.

7. Rapid And Long-Term Reusability

After meeting all of these targets, Starship can begin shuttling Starlink satellites into orbit. Hurray! However, it will be excruciatingly expensive, possibly even more expensive than launching them from Falcon 9. Why? Because, as it stands, both Starship and the Super Heavy Booster will require extensive refurbishment between launches. It’s also not clear what the overall lifespan of these space frames is, whether they can last just a few launches or tens of launches before needing to be retired. Both of these factors heavily increase the cost per launch to the point where Starship might not even be a viable launch vehicle. Indeed, even with optimistic refurbishment and space frame lifespan numbers, Starship could be more expensive per kg to LEO than Falcon Heavy.

Musk wants to achieve ‘zero touch’ refurbishment, which anyone with a hint of aerospace experience knows is never going to happen in a million years.

8. Orbital Refuelling

Firstly, getting two gigantic spacecraft like this to successfully and securely dock in orbit will be a huge achievement.

Then there is the issue of transferring the cryogenic liquid oxygen and methane from one Starship to the other. The risks involved with such a procedure are astronomical. The likelihood of fuel loss, leaks, thermal damage from leaks, structural damage from pressure, and catastrophic explosions is high. This is handling liquid oxygen and flammable liquid gas at the same time in an extreme environment, after all — it is the epitome of dangerous! In fact, this technique is so dangerous that Starship has already experienced explosive refuelling failures down here on Earth.

9. Develop, Test And Deploy Depot Variant

Boil-off is exactly as it sounds. The cryogenic liquid fuel will heat up when it is exposed to the raw, unfiltered might of the Sun. Once it is exposed, it will boil. If you don’t want the pressure-vessel fuel tanks to explode, you need to vent out the evaporated fuel to control the pressure. As such, over time, fuel in the depot Starship will boil off into space.

This is a much more serious problem than it sounds. If we assume Starship can deliver 100 tons of fuel to the orbital depot once a week, and that its boil-off is reduced to just 1% per day, then it would take over 100 refuelling missions over two years to get it close to full. That would also put the price tag for a Starship Moon mission at $7.7 billion, or way more than NASA’s already operational SLS.

This issue is so challenging that, under certain circumstances, a Mars Starship mission has more than an 80% chance of exploding in LEO rather than actually making it to Mars.

10. Develop, Test And Deploy Tanker Variant

The same is true for the tanker variant. It needs to excel at in-orbit docking and transferring fuel. But it also needs to be exceptionally reusable, potentially more so than the normal Starship, as it needs near-zero turnaround time to reduce the boil-off issues (given that when there is less time between refuelling, there is less boil-off). Again, many are not convinced this is even possible. But this stage is required before a proper mission to the Moon or Mars is feasible.

11. Develop And Test Human Landing System (HLS)

The HLS has all the same problems as the depot and tanker variant turned up to 11.
Firstly, SpaceX needs to develop and test life support, docking and crew transport systems, as well as a Starship variant capable of carrying them.

But they also need to make Starship’s rocket engines durable enough to not only last for the trip to the Moon but for landing and launching from the dusty lunar surface over and over again with no maintenance. The cryogenic liquid-fuel high-power rockets that Starship uses are notoriously short-lived and difficult to reignite repeatedly, as the stress they endure is immense, and even small problems render them useless.

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Overview

Put simply, it has taken SpaceX three years, (as of writing) 11 test launches and over $15 billion to meet four of its main targets (completing a suborbital flight, reaching orbital velocity, landing and relaunching the booster, and conducting a splashdown landing of the upper stage). But it still has 11 main targets to go, each one being significantly harder than the last.

But let’s be generous. Let’s assume that the time and cost to required to meet each target will be the same as the first four — how much will it cost, and how much longer will it take for Starship to be complete? Well, if you crunch the numbers, it will take another $41.25 billion, and about 8.25 years. Remember, in late 2034, it will be nearly a decade after Starship was supposed to land on the Moon).

Let’s be honest though, the targets SpaceX has yet to reach are at least twice as difficult as those it has already achieved. So, very roughly, it would equate to another $82.5 billion and another 16.5 years, placing the total cost at $97.5 billion and a completion date of sometime in the early 2040s.

Yeah, I’m starting to think that Musk’s claim that Starship would only cost $5 billion and be fully prepared in a few years was total bullshit.

https://wlockett.medium.com/starship-is-...c0cf555de0

[Mister Agenda]

I heard Mus is really put out that Lupita Nyong'o is playing Helen of Troy in the Odyssey. Because Helen was historically white. I have a different take. Helen of Troy is mythological (fathered by Zeus in the form of a swan, hatched from an egg) and Lupita Nyong'o is one of the most beautiful women in the world.

[BrianSoddingBoru4]

I heard Mus is really put out that Lupita Nyong'o is playing Helen of Troy in the Odyssey. Because Helen was historically white. I have a different take. Helen of Troy is mythological (fathered by Zeus in the form of a swan, hatched from an egg) and Lupita Nyong'o is one of the most beautiful women in the world.

(Bold mine)

Maybe Nolan couldn’t find an actress covered with feathers…

Boru