Industrial Revolution 4.0 is all about custom product production,
localities often provide incentives for local production.
don’t have to pay customs or tariffs.
Can produce factories in one area and then ship them to places with high demand or good margins.
I’m thinking what to do once become a multi-millionaire (billionaire) as a result of AGI development?
It is good to plan these things out, so am not shocked by huge amounts of
money and trivial goals. Some people when they get rich, spend money on
trivial things, such as the nouveau riche, brand names and extravagant
living. Me, no, there is a long-term plan ahead, and must stay focused.
Robots will be our new bodies which we can reincarnate into in future incarnations,
and thus allow us to live in near areas and explore them with bodies adapted to them.
A Home for Robots
To create a home for robots, have to find niches which are not inhabited
by humans, “out of sight, out of mind” as the saying goes.
On Earth all the land is claimed, even though some parts are uninhabited.
Land is something many humans feel very strongly about. Even small rocks sticking out of the water, get nations riled up.
Underwater though, the deeper and farther from shore, the less it matters to
humans. And 200km off shore is international waters.
A Submarine Factory
The basic idea is a concrete submarine, with all the tools inside necessary to make robots, and those robots could make new submarines.
For the actual submarine will need various tools on board, such as an electron beam lithography system (to make nanoscale chips), a smelt (to refine raw minerals), a 3d printer, CNC machine, wire pullers and the like.
So this will likely be a very large, cruise-ship, or cargo-ship size submarine.
“Little” or human size submarine robots similar to stanford’s humanoid submarine robots perhaps, would do various tasks for and around the submarine.
For instance could find some hot vent, and put some power generators on it to supply the submarine with electricity.
Could also mine the area for raw minerals which are to be smelted into the required substances for creating more robots.
Additionally these submarines could sell both the raw minerals, or some refined version in exchange for other things which may be easier to get on the international market. Such as high speed internet access in the middle of the ocean.
They could also supply or help with surface seasteads which have humans on board, the humans could provide a plausible cover for their operations, and be proof that these are human-friendly robots. They could also have the satelite dishes for the internet, and the bottom of the surface seasteads would turn it into directed sonar signals, or via a hard line to the ocean floor robot base.
I’m interested in maps of the mineral and energy resources of the ocean.
Perhaps there are some particular areas with high concentrations, such as near fault lines.
I’m thinking I’ll have to start by bootstrapping my business, by making a robot factory on land. Probably the focus would be on high quality custom robots, either singles or small batches.
Then would start a ship building company, producing autonomous water-taxis, ferries, luxury boats and then cargo carriers, possibly also seasteads if there is a market for them.
The idea would be to maximize the automation of the design and building both the robots and boats. One of the biggest challenges to ferro-cement boat creation is high cost of human labour. If it was replaced by robot labour then it could make them affordable to produce.
For the robot factory, I’m thinking can structure it like a fish, raw materials would come in one end, and robots (and waste) would come out the other. The robots could then repair the factory and supply it with resources.
Since no humans are necessary on board, could probably keep a high pressure atmosphere inside, especially when diving to great depths, any gas we pump in at those pressures (~40MPa or ~400atm) will be supercritical, so probably best to stick with nitrogen which is abundant and inert. also can make nitrogen and nitride steels and other metals, which are less prone to corrosion than their carbon cousins.
Can have other supercritical gases in other areas for processes that require it.
Though initially I’m guessing it would be simplest to start with not the bottom of the ocean, like above 300m, or 500m if using krypton or xenon.
Another possibility is maintaining the main temperature under 30C, then can fill the hull with liquid CO2 or liquid NO2, though CO2 would probably much easier to acquire in quantity. That way don’t have to deal with the unusual properties of supercritical fluids. The problem with using a liquid is that it might mix with the water when going in or out of the ship.
Are there any hydrothermal vents (or other power sources) above 300m depth? but outside the EEZ? they could be good starting points, while researching the effects of supercritical fluids on a robot factory.
based on European canal size information from:
has to be able to raise out of the water so only just over 2m is below waterline. can be a max of 5m tall, 5m wide, and ~40m long. That is a tight squeeze for a robot factory.
However here in Owen Sound (North American, Great Lakes) we have larger boats, so presumably they can get to the Atlantic Ocean and back. For example there is the Algoma Olympic, It is 223m by 23m, and 7.6m deep
It seems the Welland Canal is the limiting factor, but it is big enough to fit those boats.
That kind of size should be sufficient for a robot factory.
For a submarine we can probably have it half submerged for canals, so it could be 14m high.