Sure, tens to hundreds of thousands of years ago nobody was working with metals at all. And the centrifugal fan he uses is a modern invention; the oldest mention of them in the literature is less than 500 years old, in De Re Metallica.
It's really interesting to think about the "could have done this but didn't" stuff!
Silver chloride is one of the less sensitive silver halides you can use in photography, but it works; it dates to about 2500 years ago when someone (the Lydians?) figured out you could separate silver from gold by firing it with salt. So you could have done photography 2500 years ago instead of 200 years ago.
There's lots of stuff in optics that only requires a Fizeau interferometer (made of a candle flame and a razor blade, Bronze Age stuff), abrasives (Paleolithic), reflective metal (Bronze Age again; Newton's mirrors were just a high-tin bronze), abrasives, and an unreasonable amount of patience. Imhotep could have made a Dobsonian telescope and seen the moons of Jupiter 4700 years ago if he'd known that was a worthwhile thing to do.
Speaking of metrology, I've heard conflicting stories about surface plates: one story that the Babylonians knew about grinding three surfaces alternately against one another to make them all flat, and another that Maudslay originated the technique only about 220 years ago. (Or, sometimes, Maudslay's apprentice Whitworth.) This is clearly a technique you could have employed in the Neolithic.
Sorption pumps for fine vacuum (usually 1e-2 mbar) require a high-surface-area sorbent (zeolite or maybe even kieselguhr or ball-milled non-zeolite clay: Neolithic), probably glassblowing (Roman Republic era in Syria), sealed joints (apparently Victorians used sealing wax successfully up to HV though not UHV, and sealing wax is pine resin and beeswax: probably Paleolithic), and some way to heat up the sorbent (fire: Paleolithic). Fine vacuum is enough for thermos bottles (dewars) and CVD, among other things.
Conceivably you could have just luted together an opaque vacuum apparatus from glazed earthenware (which dates from probably 3500 years ago), using sealing wax to seal the joints. But debugging the thing or manipulating anything inside of it would have been an invincible challenge.
Sorption pumping works better if you can also cool the sorbent down, too; dry ice is today made by explosive decompression of carbon dioxide, similar to how puffed corn and rice can be made with a grain-puffing cannon, and regularly is by Chinese street vendors. Pure carbon dioxide is available by calcining limestone (thus the name: Neolithic) in a metal vessel (Bronze Age) that bubbles the result into water into a "gasometer", a bucket floating upside down. Compressing the carbon dioxide sufficiently probably requires the accurately cylindrical bores produced for the first time for things like the Dardanelles Gun (15th century). But possibly not; the firepiston in Madagascar is at least 1500 years old, dating back to the time of the Western Roman Empire, and I think it can achieve sufficiently high compression.
Mercury has been known all over the world since antiquity, though usually as a precious metal rather than a demonic pollutant. Mercury plus glassblowing (Roman Republic, again) is enough for a Sprengel pump, which can achieve 1 mPa, high vacuum, 1000 times higher vacuum than an ordinary sorption pump (though some sorption pumps are even better than the Sprengel pump). High vacuum is sufficient to make vacuum tubes.
The Pidgeon process to refine magnesium requires dolomite, ferrosilicon, and a reducing atmosphere or vacuum. You get ferrosilicon by firing iron, coke, and silica in acid refractory (such as silica). Magnesium is especially demanding of reducing atmospheres; in particular nitrogen and carbon dioxide are not good enough, so you need something like hydrogen (or, again, vacuum) to distill the magnesium out of the reaction vessel. As a structural metal magnesium isn't very useful unless you also have aluminum or zinc or manganese or silicon, which the ancients didn't; but it's a first-rate incendiary weapon and thermite reducer, permitting both the easy achievement of very high temperatures and the thermite reduction of nearly all other metals.
Copper and iron with any random kind of electrolyte makes a (rather poor) battery; this permits you to electroplate. The Baghdad Battery surely isn't such a battery, but it demonstrates that the materials available to build one were available starting in the Iron Age. Electroplating is potentially useful for corrosion resistance, but to electroplate copper onto iron you apparently need an intermediate metal like nickel or chromium to get an adherent coating, and to electroplate gold or silver you probably need cyanide or more exotic materials. Alternate possible uses for low-voltage expensive electricity include molten-salt electrolysis and the production of hydrogen from water.
Copper rectifiers and photovoltaic panels pretty much just require heating up a sheet of copper, I think? Similarly copper wires for a generator only require wire drawing (Chalcolithic I think, at least 2nd Dynasty Egypt) and something like shellac (Mahabharata-age India, though rare in Europe until 500 years ago), though many 19th-century electrical machines were instead insulated with silk cloth.
Vapor-compression air conditioners probably need pretty advanced sealing and machining techniques, but desiccant-driven air conditioners can operate entirely at atmospheric pressure. The desiccants are pretty corrosive, but beeswax-painted metal or salt-glazed ceramic pipes are probably fine for magnesium chloride ("bitterns" from making sea salt, Japanese "nigari"), and you can pump it around with a geyser pump.
I think the geyser pump is still under patent, but it can be made of unglazed earthenware or carved out of bamboo (both Neolithic) and driven by either a bellows (Neolithic) or a trompe (Renaissance).
Some years ago I figured out a way to use textile thread (and, say, tree branches) to make logic gates; I posted that to kragen-tol. So you probably could have done digital logic with Neolithic materials science, though only at kHz clock rates. And of course you could have hand-filed clockwork gears out of sheet copper as early as the Chalcolithic, instead of waiting until the Hellenistic period.
Have you ever heard of "The Narcissist's Prayer"? It goes like this:
That didn't happen.
And if it did, it wasn't that bad.
And if it was, that's not a big deal.
And if it is, that's not my fault.
And if it was, I didn't mean it.
And if I did...
You deserved it.
Tether defenders are really working their way through the steps here.
18 months ago, it was "That didn't happen." (Tether is 100% backed by USD cash.)
6 months ago, it "wasn't that bad." (It might not be 100% USD cash, but it's cash-equivalent assets like short-term commercial paper.)
Now that there's strong evidence the commercial paper is just fake money shuffling between Tether/Binfinex/other shady crypto investments we get "that's not a big deal." (Look at the way banks work! They only need 4% collateral! Tether's probably got at least that much...)
Next step is finding out that their actual liquidity isn't capable of holding up under a real-life stress test, and the defenders will be talking about "not my fault." (This was a once-in-a-lifetime crash, they couldn't have foreseen it, crypto's still way better than the fiat banking system!)
When thousands of people lose their retirements in a gigantic defi crash, it'll be "you deserved it." (Everyone knows crypto is risky, you shouldn't have believed Tether was the same as USD.)
Weirdly, perl. I found myself on a client site in a locked down environment with only the Windows version of GIT installed. Powershell disabled, no other programs allowed. I had to produce reports on the log files for this machine, but had to obfuscate information before taking it off the server.
I discovered that git had bash installed quite early on, so my initial automation and reporting was based on UNIX pipelines. As the data volumes became bigger and the customer requirements became more demanding, I eventually bit the bullet and started learning perl one-liners to do some gymnastics that just weren't possible or practical with just bash (first big win was adding the MD5 of the line so that I could dedupe the obfuscated data).
This lead to eventually writing full scripts in perl and now I have basically all of my reporting automated, even able to take up some 'value add' reporting that I didn't think was going to be possible.
So yeah, not a new technology but I'm now a perl convert and will almost certainly use it in the future if I'm faced with a similar situation.
I will try to help you understand. Two years ago, Peter Sims asked: "Can we trust Uber?"[24]. The answer is no.
There's just way too much awful stuff going on at Uber to ignore all of it or claim everyone's distaste is political. (It's also silly to suggest that all of the media and/or Silicon Valley have the same set of ulterior motives.)
Here's just a sampling of Uber's misconduct. Some of these items cross categories, but I've tried to roughly divide them up.
* Culture problems: The sexual harassment described by your "disgruntled employee" has been backed up and verified by others.[1][19] Its culture has been described as a constant battle between warring factions with managers openly backstabbing and abusing other managers and employees.[7] It hires executives who have ongoing harassment claims against them, then forces same executives to resign unceremoniously.[17] Its culture has been purposefully designed to cause employees to work against each other.[18] It blcoks employees from chatting on anonymous apps.[21]
* Corporate governance problems: It behaves anti-competitively in ways that are dubiously legal in order to sabotage competition.[2] It is also alleged to steal from other companies.[3] Its executives have suggested 'digging up dirt' on journalists in order to silence them, spurring a Congressional inquiry.[8] It offered drivers money to show them paystubs from competitors.[12] It also tries to prevent drivers from driving for any other company, even though it insists said drivers are 'contract employees.'[14] It has been and is being sued by numerous state governments over its business practices.[22]
* Exploiting users and ignoring privacy: It tracks/tracked one-night stands.[9] It collects users' location data in the background when the app is off.[10] It has been subject to FTC complaints over its tracking behaviors.[11] It lures drivers in with promises of big fares, then changes those fares arbitrarily to screw said drivers over and save riders money.[13] It is alleged to have mislead users by showing 'phantom cars' on its app.[16]
* Outright and attempted law-breaking: Uber breaks laws all around the world to enrich itself, including allegedly trying to deceive government officials across the world.[4] It refused to acquire a mandatory permit from the government until faced with public pressure.[5] It refuses to treat its drivers as true employees, even though legally they are considered such in many jurisdictions, and only complies when faced with court orders.[6][20] It attempted to investigate the plaintiffs in a class-action suit against it via methods that may have been illegal.[15]
All of this together helps explain why even Peter Thiel, himself not a particularly sterling gentleman, considers Uber "the most ethically challenged company in Silicon Valley."[23] I am gleefully awaiting Uber's downfall, as you say, because it is a legitimately evil company. Big companies aren't inherently evil. Uber is a big company which happens to be evil. If even a couple of the items in each category are true, Uber is engaging in a variety of illegal and morally unacceptable practices. I don't see how you can suggest, in the face of this much evidence to the contrary, that all of this is purely political.
And by the way? There's much more where this came from. This is just a smattering I could find in 20 minutes.
It's really interesting to think about the "could have done this but didn't" stuff!
Silver chloride is one of the less sensitive silver halides you can use in photography, but it works; it dates to about 2500 years ago when someone (the Lydians?) figured out you could separate silver from gold by firing it with salt. So you could have done photography 2500 years ago instead of 200 years ago.
There's lots of stuff in optics that only requires a Fizeau interferometer (made of a candle flame and a razor blade, Bronze Age stuff), abrasives (Paleolithic), reflective metal (Bronze Age again; Newton's mirrors were just a high-tin bronze), abrasives, and an unreasonable amount of patience. Imhotep could have made a Dobsonian telescope and seen the moons of Jupiter 4700 years ago if he'd known that was a worthwhile thing to do.
Speaking of metrology, I've heard conflicting stories about surface plates: one story that the Babylonians knew about grinding three surfaces alternately against one another to make them all flat, and another that Maudslay originated the technique only about 220 years ago. (Or, sometimes, Maudslay's apprentice Whitworth.) This is clearly a technique you could have employed in the Neolithic.
Sorption pumps for fine vacuum (usually 1e-2 mbar) require a high-surface-area sorbent (zeolite or maybe even kieselguhr or ball-milled non-zeolite clay: Neolithic), probably glassblowing (Roman Republic era in Syria), sealed joints (apparently Victorians used sealing wax successfully up to HV though not UHV, and sealing wax is pine resin and beeswax: probably Paleolithic), and some way to heat up the sorbent (fire: Paleolithic). Fine vacuum is enough for thermos bottles (dewars) and CVD, among other things.
Conceivably you could have just luted together an opaque vacuum apparatus from glazed earthenware (which dates from probably 3500 years ago), using sealing wax to seal the joints. But debugging the thing or manipulating anything inside of it would have been an invincible challenge.
Sorption pumping works better if you can also cool the sorbent down, too; dry ice is today made by explosive decompression of carbon dioxide, similar to how puffed corn and rice can be made with a grain-puffing cannon, and regularly is by Chinese street vendors. Pure carbon dioxide is available by calcining limestone (thus the name: Neolithic) in a metal vessel (Bronze Age) that bubbles the result into water into a "gasometer", a bucket floating upside down. Compressing the carbon dioxide sufficiently probably requires the accurately cylindrical bores produced for the first time for things like the Dardanelles Gun (15th century). But possibly not; the firepiston in Madagascar is at least 1500 years old, dating back to the time of the Western Roman Empire, and I think it can achieve sufficiently high compression.
Mercury has been known all over the world since antiquity, though usually as a precious metal rather than a demonic pollutant. Mercury plus glassblowing (Roman Republic, again) is enough for a Sprengel pump, which can achieve 1 mPa, high vacuum, 1000 times higher vacuum than an ordinary sorption pump (though some sorption pumps are even better than the Sprengel pump). High vacuum is sufficient to make vacuum tubes.
The Pidgeon process to refine magnesium requires dolomite, ferrosilicon, and a reducing atmosphere or vacuum. You get ferrosilicon by firing iron, coke, and silica in acid refractory (such as silica). Magnesium is especially demanding of reducing atmospheres; in particular nitrogen and carbon dioxide are not good enough, so you need something like hydrogen (or, again, vacuum) to distill the magnesium out of the reaction vessel. As a structural metal magnesium isn't very useful unless you also have aluminum or zinc or manganese or silicon, which the ancients didn't; but it's a first-rate incendiary weapon and thermite reducer, permitting both the easy achievement of very high temperatures and the thermite reduction of nearly all other metals.
Copper and iron with any random kind of electrolyte makes a (rather poor) battery; this permits you to electroplate. The Baghdad Battery surely isn't such a battery, but it demonstrates that the materials available to build one were available starting in the Iron Age. Electroplating is potentially useful for corrosion resistance, but to electroplate copper onto iron you apparently need an intermediate metal like nickel or chromium to get an adherent coating, and to electroplate gold or silver you probably need cyanide or more exotic materials. Alternate possible uses for low-voltage expensive electricity include molten-salt electrolysis and the production of hydrogen from water.
Copper rectifiers and photovoltaic panels pretty much just require heating up a sheet of copper, I think? Similarly copper wires for a generator only require wire drawing (Chalcolithic I think, at least 2nd Dynasty Egypt) and something like shellac (Mahabharata-age India, though rare in Europe until 500 years ago), though many 19th-century electrical machines were instead insulated with silk cloth.
Vapor-compression air conditioners probably need pretty advanced sealing and machining techniques, but desiccant-driven air conditioners can operate entirely at atmospheric pressure. The desiccants are pretty corrosive, but beeswax-painted metal or salt-glazed ceramic pipes are probably fine for magnesium chloride ("bitterns" from making sea salt, Japanese "nigari"), and you can pump it around with a geyser pump.
I think the geyser pump is still under patent, but it can be made of unglazed earthenware or carved out of bamboo (both Neolithic) and driven by either a bellows (Neolithic) or a trompe (Renaissance).
Some years ago I figured out a way to use textile thread (and, say, tree branches) to make logic gates; I posted that to kragen-tol. So you probably could have done digital logic with Neolithic materials science, though only at kHz clock rates. And of course you could have hand-filed clockwork gears out of sheet copper as early as the Chalcolithic, instead of waiting until the Hellenistic period.