JR Wakefield said:The size of the ship is an issue. It would include travelers and the food required to sustain them. Then their gear, and fuel. Closest I can think of would be a submarine for example. What I'm looking for is what the energy would be compared to a nuke reactor or oil equiv. The time of just 4 years is theoretical only (seems the CBR would cook them), what is the practical limit of speed attainable? Which then affects the time big time.
This page gives Tsiolkovsky’s equation for the relation between change in velocity, payload mass and initial fuel mass:
Mpayload/mrocket = exp(-delta v/exhaust velocity)
This equation is a classical one which would need to be modified if delta v were close to the speed of light, but it can give you a sense of the huge amount of fuel needed if you just figure out the mass needed to get to some small fraction of light speed, like 0.01c, where the relativistic correction shouldn't be too big. They give the exhaust velocity for a chemical rocket as 4000 m/sec, and the exhaust velocity for a fission rocket as "12,000 m/sec (for solid-core nuclear thermal with oxygen augmentation), 40,000 m/sec (for nuclear electric propulsion), 100,000 m/sec (for more exotic and theoretical forms)". Using the 40,000 m/sec figure, to accelerate from being at rest wrt Earth to traveling at 0.01c relative to Earth (again, just calculating the answer using Newtonian physics without taking into account relativity, since the time dilation factor is very small at this speed), the equation tells us the mass of the rocket would have to be about e^75 times greater than the mass of the payload, which is about 3.5 * 10^32. If you want the answer in terms of acceleration, this thread gives the equation:
accleration* time = specific impulse * ln(mass ratio)
with each type of rocket having its own specific impulse (wikipedia's relativistic rocket page mentions that specific impulse is the same as exhaust velocity)...rearranging, this should mean the mass ratio needed to accelerate at 1G for some time t would be:
e^(9.8 m/s^2 * t / specific impulse)
If we again use 40,000 m/s for the specific impulse, this becomes:
e^(t * 0.000245/s)
So, to accelerate at 1G for 3 days (259200 seconds) would require a mass ratio of e^63.5, or a total initial rocket mass about 3.8 * 10^27 greater than the payload mass. This page mentions that for an antimatter rocket you might have an exhaust velocity of 10,000,000 m/s, so plugging that into the equation would give the mass ratio as:e^(t * 0.00000098/s)
This would make 1G acceleration for a few days much more manageable, but to accelerate for 1 year (31536000 seconds) you'd need a mass ratio of e^(30.9), so the rocket would have to be about 26 trillion times more massive than the payload--that's a lot of antimatter!
Nabeshin said:Yes. Cutting down on acceleration does reduce power consumption, to a certain point. However, you suffer diminishing returns as the voyage becomes exponentially longer as you begin to lose the benefits of time dilation. Reducing acceleration from 1g to .1g helps, and to .01g helps a bit more. Beyond this, there's almost no point (you're talking travel times in the centuries by then anyways).
I'm not going to double check your specific numbers, but if you got 3*10^23 that's close enough to a yottajoule, we're in the same ballpark. Good.
Yes, power consumption is a HUGE problem for this kind of travel. If you want more info, I have an article you might want to read.
JesseM said:This would make 1G acceleration for a few days much more manageable, but to accelerate for 1 year (31536000 seconds) you'd need a mass ratio of e^(30.9), so the rocket would have to be about 26 trillion times more massive than the payload--that's a lot of antimatter!
Nabeshin said:Yes, power consumption is a HUGE problem for this kind of travel. If you want more info, I have an article you might want to read.
JR Wakefield said:I'm having a bit of a debate on traveling to AC. I was wondering if someone can post calculatons to show how long it would take traveling at 1g accelaration, and how much energy would be needed including any relativistic influences.
JesseM said:calculating the energy in terms of nuke plants for a 38:1 fuel-to-payload mass ratio is kind of silly from a realistic point of view, because any civilization that can build photon drives that convert mass into photons with optimal efficiency (which would require something like a matter/antimatter drive) is probably going to have much better sources of power than fission-based nuclear power. If you want to assume technology not too far advanced beyond our own, you should probably assume some more feasible propulsion method like an ion drive or nuclear/electric propulsion...here's something I wrote about different propulsion methods on another thread:
uniqueland said:I heard that there was some theoretical propulsion method that grabbed the material necessary for fuel from space as you went along.
But as noted in that article, later analysis led to the consensus that drag would outweigh forward propulsion, though this would work as a braking mechanism so you wouldn't need fuel to decelerate as you approached your destination.jtbell said:
The duration of travel to Alpha Centauri depends on the technology used and the speed of the spacecraft. With current technology, it would take approximately 100 years to reach Alpha Centauri, which is about 4.37 light years away.
It is currently not possible for humans to survive the journey to Alpha Centauri due to the long duration and harsh conditions of space. However, with advancements in technology and space travel, it may be possible in the future.
Scientists use telescopes and other instruments to study and gather information about Alpha Centauri. They can also analyze data from previous space missions to estimate the resources that may be available on the planet.
The main challenges faced by astronauts during a trip to Alpha Centauri include long duration in space, exposure to radiation, and the psychological effects of isolation. Additionally, the spacecraft would need to be self-sustaining for the entire journey.
Currently, it is not possible to travel at the speed of light due to the limits of physics. However, with advancements in technology, it may be possible in the future. This would significantly decrease the travel time to Alpha Centauri, making it a more feasible option for space exploration.