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Q&A High-Energy Exhaust Shielding for Far-Future Drive

Imagine a far-future spacecraft drive that accelerates its reaction mass to a small fraction the speed of light (say, 1,000 km/s). Say the mass flow rate to the drive were 1kg/s, and say the reacti...

1 answer  ·  posted 2y ago by Josh Hyatt‭  ·  last activity 2y ago by James McLellan‭

Question space-travel far-future
#3: Post edited by user avatar Josh Hyatt‭ · 2022-02-17T16:28:46Z (about 2 years ago)
Fix kinetic energy calculation
  • Imagine a far-future spacecraft drive that accelerates its reaction mass to a small fraction the speed of light (say, 1,000 km/s). Say the mass flow rate to the drive were 1kg/s, and say the reaction mass were hydrogen. what effect would the resulting exhaust have on humans? On other spacecraft? If fired within an atmosphere comparable to Earth's at sea level, how would these effects change? What sort of shielding would be needed to protect a spacecraft or EVA suit and the people inside from damage or injury? How far would you have to be from the nozzle to safely remain inside the exhaust jet in a vacuum? In an atmosphere comparable to Earth's at sea level? How would this change with higher exhaust velocity, say 30Mm/s?
  • Such a jet would put out 1TW of power, and assuming the jet diverges, the intensity drops with the inverse square of the distance. This question was discussed [here](https://scientific-speculation.codidact.com/posts/276617), but the provided answer deals primarily with the force exerted on spacecraft in the jet and is more focused on less powerful engines with a much lower exhaust velocity (40-100km/s). This question deals more with considerations that must be made with exhaust velocities at a significant fraction of the speed of light.
  • Imagine a far-future spacecraft drive that accelerates its reaction mass to a small fraction the speed of light (say, 1,000 km/s). Say the mass flow rate to the drive were 1kg/s, and say the reaction mass were hydrogen. what effect would the resulting exhaust have on humans? On other spacecraft? If fired within an atmosphere comparable to Earth's at sea level, how would these effects change? What sort of shielding would be needed to protect a spacecraft or EVA suit and the people inside from damage or injury? How far would you have to be from the nozzle to safely remain inside the exhaust jet in a vacuum? In an atmosphere comparable to Earth's at sea level? How would this change with higher exhaust velocity, say 30Mm/s?
  • Such a jet would put out 500GW of power, and assuming the jet diverges, the intensity drops with the inverse square of the distance. This question was discussed [here](https://scientific-speculation.codidact.com/posts/276617), but the provided answer deals primarily with the force exerted on spacecraft in the jet and is more focused on less powerful engines with a much lower exhaust velocity (40-100km/s). This question deals more with considerations that must be made with exhaust velocities at a significant fraction of the speed of light.
#2: Post edited by user avatar Josh Hyatt‭ · 2022-02-17T16:27:48Z (about 2 years ago)
Relativistic is not applicable here
  • Relativistic Exhaust Shielding for Far-Future Drive
  • High-Energy Exhaust Shielding for Far-Future Drive
  • Imagine a far-future spacecraft drive that accelerates its reaction mass to a small fraction the speed of light (say, 1,000 km/s). Say the mass flow rate to the drive were 1kg/s, and say the reaction mass were hydrogen. what effect would the resulting exhaust have on humans? On other spacecraft? If fired within an atmosphere comparable to Earth's at sea level, how would these effects change? What sort of shielding would be needed to protect a spacecraft or EVA suit and the people inside from damage or injury? How far would you have to be from the nozzle to safely remain inside the exhaust jet in a vacuum? In an atmosphere comparable to Earth's at sea level? How would this change with higher exhaust velocity, say 30Mm/s?
  • Such a jet would put out 1TW of power, and assuming the jet diverges, the intensity drops with the inverse square of the distance. This question was discussed [here](https://scientific-speculation.codidact.com/posts/276617), but the provided answer deals primarily with the force exerted on spacecraft in the jet and is more focused on less powerful engines with a much lower exhaust velocity (40-100km/s). This question deals more with considerations that must be made with relativistic exhaust velocities.
  • Imagine a far-future spacecraft drive that accelerates its reaction mass to a small fraction the speed of light (say, 1,000 km/s). Say the mass flow rate to the drive were 1kg/s, and say the reaction mass were hydrogen. what effect would the resulting exhaust have on humans? On other spacecraft? If fired within an atmosphere comparable to Earth's at sea level, how would these effects change? What sort of shielding would be needed to protect a spacecraft or EVA suit and the people inside from damage or injury? How far would you have to be from the nozzle to safely remain inside the exhaust jet in a vacuum? In an atmosphere comparable to Earth's at sea level? How would this change with higher exhaust velocity, say 30Mm/s?
  • Such a jet would put out 1TW of power, and assuming the jet diverges, the intensity drops with the inverse square of the distance. This question was discussed [here](https://scientific-speculation.codidact.com/posts/276617), but the provided answer deals primarily with the force exerted on spacecraft in the jet and is more focused on less powerful engines with a much lower exhaust velocity (40-100km/s). This question deals more with considerations that must be made with exhaust velocities at a significant fraction of the speed of light.
#1: Initial revision by user avatar Josh Hyatt‭ · 2022-02-16T02:40:02Z (about 2 years ago) 
Relativistic Exhaust Shielding for Far-Future Drive
Imagine a far-future spacecraft drive that accelerates its reaction mass to a small fraction the speed of light (say, 1,000 km/s). Say the mass flow rate to the drive were 1kg/s, and say the reaction mass were hydrogen. what effect would the resulting exhaust have on humans? On other spacecraft? If fired within an atmosphere comparable to Earth's at sea level, how would these effects change? What sort of shielding would be needed to protect a spacecraft or EVA suit and the people inside from damage or injury? How far would you have to be from the nozzle to safely remain inside the exhaust jet in a vacuum? In an atmosphere comparable to Earth's at sea level? How would this change with higher exhaust velocity, say 30Mm/s?

Such a jet would put out 1TW of power, and assuming the jet diverges, the intensity drops with the inverse square of the distance. This question was discussed [here](https://scientific-speculation.codidact.com/posts/276617), but the provided answer deals primarily with the force exerted on spacecraft in the jet and is more focused on less powerful engines with a much lower exhaust velocity (40-100km/s). This question deals more with considerations that must be made with relativistic exhaust velocities.
space-travel far-future