Are there any greater risks of traveling significantly faster to another planet?

Question

Earlier I had thought that space ships can strike against space rocks while traveling to another planet. But I've read that space is vastly empty, it's highly unlikely that something will come in the path of space ship. It is explained here.

Now, to reach a planet like Mars, it takes around 7-8 months. So I wonder when path is clear, why can't or why don't scientists make a space ship that is significantly faster than current ones? So travel time could be reduced to 1 or 2 months.

Are there greater risks of traveling so fast or it is just matter of time (e.g. we don't have required technology) and we can expect faster space ships in future?

Answer 1

The biggest risk on a flight to Mars is cumulative exposure to radiation, so a 1-2 month flight would actually be much healthier for a crew than a 7-8 month flight. I don't know of any risks that would be increased by a shorter flight.

The limitation to making a faster spacecraft is fuel. In order to go a little bit faster, you need to fire your rocket engine for a little bit longer at the start of the flight (the spacecraft just coasts through space for the 7-8 month duration). To fire the rocket engine longer, you need to take a little more fuel into space, but the mass of that additional fuel itself requires a little more fuel to lift against Earth's gravity, and so on. The relationship between speed and fuel mass for a rocket engine is exponential, and is described by the Tsiolkovsky rocket equation.

Depending on where you're going, you might need to bring along still more fuel to slow down once you reach your destination! At Mars, it's possible to slow down by flying through Mars's atmosphere when you get there, but aerobraking in this way from a higher speed will require still more mass in heat shielding, and thus more fuel to get up to speed when leaving Earth.

Building a launching rocket large enough to get a spacecraft to Mars in 7-8 months is already a huge, expensive project, and it would be probably at least 5 or 10 times more expensive (but definitely not millions of times) to make it a 1-2 month flight.

Answer 2

The limitations, as we know it:

1. Fuel. The infamous rocket equation means we get roughly a few times more fuel for every km/s delta-v budget.

2. #1 is why we avoid braking by rocket engines. When we reach Mars, we need to be almost at the speed of Mars and then brake in its atmosphere.

If we go faster, Mars' tiny atmosphere cannot brake us enough. And even if it does, the heat and acceleration will impose quite a requirement on the payload. More protection means more mass, i.e. more fuel in the first place. And even with all the possible protection, the atmosphere can do only so much and then we risk flying back into space or reaching the surface at rather unpleasant speed.

3. So we should brake by rocket engines, expending our precious delta-v budget. The rocket equation says we need the fuel for braking and even more fuel to bring the fuel for braking to the place where we need to brake.

4. Acceleration - humans can survive 1g for quite a while, ~3g for short time (like tens of minutes) and 10g feels and hurts like a car crash. Any scientific payload is hardly 10g-safe. We can probably make it survive 10g, but it will get heavier - see the rocket equation again.

5. Ah, I forgot - a more powerful rocket will have to withstand its own acceleration, i.e. will be heavier and will carry less fuel per unit of mass. Rocket equation all the way...

So no, unless we make a great leap forward in the rocket science (and it IS a rocket science) we are not going to Mars any faster.

What we can do now is to make the travel e.g. 2 weeks shorter for like double the expense.

So the main risk is quickly going over budget for no apparent gain.

Edit: p.s.

The same factors say we don't save much if we go much slower either. We can probably use a gravity assisted acceleration near the Moon at the price of month or two more and at least 2 more burns.

And yes, engine starts are limited resource as well.

Answer 3

There are no risks, only benefits, but the laws of physics dictate that this won't happen for a loooooong time, even with the first couple generations of nuclear rockets, whenever that happens.

Earth has a minimum escape velocity, irrespective of mass and currently all space-craft just reach it and coast until they get to their destination and then burn the least possible amount of fuel to enter it's orbit. This is called the https://en.wikipedia.org/wiki/Hohmann_transfer_orbit. Currently, we have such puny engines, that even with the most efficient journey the designers of the various space-probes go through the hassle of shaving grams from any component they can.

If we can have a more powerful space-drive, like the currently proposed nuclear ones, with the same Delta V budget, we could get to their destination faster, or we can bring a lot more cargo(which is more important) and you have to get to the level of ludicrously powerful sci-fi level drives(e.g. the Epstein drive in The Expanse), before you can afford to both get their quickly and bring enough stuff with you.