Louis R wrote:This is a fairly straightforward exercise in fluid dynamics...
You are correct that you can in some cases apply fluid dynamics to the interstellar medium, but I think you're being mislead by the scales involved here. The ISM is *so* incredibly rarefied that any traditional fluid dynamics intuition is going to be very misleading on the size scale of a starship.
The first basic problem is that the mean free path for a particle at the densities of the ISM is on the order of *at least* tens of thousands of km even for denser regions (interaction cross sections of ~10^-16, particle densities lower than 1000/cm^3). And that means that any behavior which relies on particles interacting with each other (i.e. fluid dynamics) will not be apparent on any scales less than that - the ISM only acts like a fluid on scales of tens of thousands (if not millions) of km. The particles deflected by the buckler will proceed radially outwards for thousands of KM before they have any realistic chance of hitting any other particle which could redirect their motion back inwards. (Well, assuming they didn't hit the wedge, anyway, but I very highly doubt the wedge would push them *inwards*, otherwise the wedge itself would be dangerous to the ship as it swept up the ISM as it passed through.) So while yes, normally a flow around a moving disk will fill back in within a short distance relative to the size of the disk, that's only valid when the size of the disk is not many orders of magnitude smaller than the mean free path of the medium. That doesn't mean that the hollow behind the disk won't be filled up pretty rapidly in an *absolute* sense (by particles that were not hit by the buckler diffusing back into the channel), but you can't relate the depth of the hollow to the size of the disk itself.
The other main problem is that this is an *incredibly* hypersonic flow. Even in the higher temperature regions of the ISM the speed of sound isn't much above ~10 km/s (T~10,000K), meaning that a ship moving at 0.8c is travelling at something like mach 24,000! Even if the medium was dense enough for the mean free path to be comparable to the scales involved, the sheer blazing *speed* with which the buckler sweeps out its channel is going to make it very hard for any material to actually physically move back inwards in time for it to hit the ship.
Sidewalls are ~10km from the ship. A ship moving at 0.8c covers 10km in ~4e-5s! In that time, those particles moving at ~10km/s cover a whopping 0.4m. Even if you assume the shock of the impact results in them moving an order of magnitude faster (i.e. a 100-fold increase in temperature), they're still not spreading more than a few meters back inward before the ship is far, far past.
The real problem with the buckler acting as a particle shield at speeds where normal particle shields would fail is that it only will work as long as the ship's orientation *exactly* matches its vector - as soon as the ship rotates to accelerate in a different direction than the one it's currently moving, the buckler swings out of line with the flow and all those particles start smashing right through your regular particle shielding. Given that you can't maneuver at all (or even slow down!) without changing heading, it would be impossible in a practical sense to actually safely use a buckler as a shield even if it might be theoretically possible. (Barring, as munroburton mentions, the possibility of making a downwards hyper translation to bleed off speed, but even then the inability to do anything other than go in straight lines would be crippling.)
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