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Because space isn't about going high; it's about going fast! For example, in a 400 km orbit (like ISS) you need a speed of about 27,500 km/h or 7.66 km per second.

So if you would extend a pole, winch or anything else into the lower parts of the atmosphere, it would also move at about 27,500 km/h (if we ignore atmospheric drag and all other influences). Try to catch that hook! If you can, you might as well go straight into orbit yourself.

As an alternative to DarkDust's answer, if you start higher, at the classic altitude for space elevators, the end of your cable is indeed stationary to the air. But your cable needs to reach from geostationary orbit to the upper atmosphere, something like 35,700 km. The clipping off the last 20-60 km does not make a big difference in the overall monumental cost and complexity.

It is also worth noting that as you climb the cable, you will also pull the cable and station down. So your elevator will need to burn similar amounts of fuel to keep in orbit as if you had flown there (though possibly in a more efficient engine), unless you can balance things with loads coming down and being dropped as you go up.

Have you ever flown a kite with a tail? The tail flies almost horizontally, kept up by the wind. It would hang at a steeper angle if you made it heavy, but what would then happen to your kite?

Now imagine that wind to be Mach 20 or so. Even if you had a rope made of unobtainium and hence able to withstand the heat created by atmospheric compression it would always "skim" on top of the atmosphere, the end being horizontal.

The concept is unviable in almost all aspects.

The end of the cable would be destroyed by the heat of reentry from a low orbit when reaching the height where planes may fly.

But if you try to drop a cable from a low orbit it would not drop, it would stay in orbit. There is no dropping of things in zero gravity.

Pulling up a load to the spacecraft in low orbit would slow down the spacecraft. It would lose height and fuel is needed to maintain orbit.

As written in the other answers, a plane is much too slow to catch the hook. Without a heatshield, the plane would be destroyed by the necessary speed. With a heatshield the plane would need a lot of fuel to maintain that speed.

There's plenty of answers discussing the problems with having a cable hanging into the Earth's atmosphere - the drag, the heat, the resistence on the orbiting craft, etc. However, I don't see much consideration of the orbital mechanics of the scenario, which would be an issue even if there were no atmosphere.

Simply put, once a craft is in orbit, all that keeps it there is its speed. If you had a craft that could somehow catch the bottom end of the cable at ground level (as it zips by at around twenty-something times the speed of sound), then you have a massive difference in speeds to resolve. If your cable was somehow strong enough (and/or stretchy enough) to bring the lower craft up to speed without breaking the cable, and the contents of each craft were somehow protected from accelerations that would turn cargo and crew into paste, you're now about to run into conservation of momentum. As the cable speeds you up, you're slowing the upper craft down... which means that it will stop orbiting and fall back down.

Even if you put your upper craft in geostationary orbit^* (and lengthen the cable considerably to still reach the ground), as you climb up the cable, you're still pulling the upper craft down. Precisely how this works out depends on your relative masses; if you're about the same mass then you'd meet somewhere in the middle. Theoretically you could then push the upper craft down, perhaps by extending a massive pushrod, to continue on your way to orbit, at which point you've invented a rudimentary space elevator. Indeed, some space elevator concepts involve having something very massive (like a captured asteroid) in geostationary orbit^*, with a huge tether to the ground - the huge mass means huge momentum and inertia, which mean that its position isn't affected as much by things climbing up to it; an effect that can be further minimised by sending something back down to balance out each thing that comes up.

* Actually, it would have to be a little above geostationary, so that when the mass of the cable is taken into account, the centre of mass is at geostationary altitude. There's also challenges to overcome with regards to the tendency of the whole system to want to rotate relative to the Earth, so that the tether breaks away and drifts out into space, but that's tangential to the question.

If the shuttle is at 100 km, and planes fly at say 20 km, that would mean the cable would have to be 80 km in length. Such a long cable would produce so much atmospheric drag that the shuttle would need to constantly burn to counter it, otherwise it would de-orbit pretty quickly.