What is the most effective way to brake from interstellar speeds?

Question

In my story, I have a slower-than-light starship (traveling at 0.6 $c$) going to Alpha Centauri A. There are several planets around the star. The target planet is a terrestrial, habitable world orbiting at 1.2 AU (since Alpha Centauri is slightly bigger than the Sun) and a gas giant 3 times the size of Jupiter at 10-20 AU.

What is the most effective way to decelerate from 0.6 $c$

1. When arriving in the Alpha Centauri System (Pollution, fallout, etc. are allowed)?
2. When returning to the Solar System (Pollution, fallout, etc. are not allowed since we have got colonies as far as in the Oort Cloud; this means radioactive sections of the starship will most likely be detached and dropped onto Jupiter or Sun to be destroyed)?

Old-school "halftime" strategy (acceleration until halfway, then brake)? Quick acceleration and then quick braking, with a coasting period in the middle? Aerobraking? Gravity assist?

Please keep it hard science fiction: no wormholes and stuff; laser propulsion is used for the big part and nuclear propulsion is used for trajectory adjustment inside the Solar or Alpha Centauri system (plane change, escape/capture burns, etc...). The crew is brought to the ship in a shuttle, lands on the planet around Alpha Centauri A in a shuttle and lands on Earth in a shuttle, so the massive ship doesn't need to be aerodynamic unless it is needed for the aerobraking part.

Answer 1

If you use laser propulsion to get them to 0.6c, odds are that's the only realistic technology for the job. If you have a better system that works halfway between the sun and Alpha Centauri on whatever power you brought with you, then why not use that to accelerate you as well?

I propose a symmetric solution. Take a small craft (the shuttle) that contains everything your settlers need to build their colony. Figure out what's needed to accelerate that to 0.6c by laser propulsion. Take the whole package (shuttle + laser), and make that your spaceship. Presumably, the majority of mass will be taken up by the laser.

Build one big-ass laser in the solar system (perhaps powered by a partial Dyson sphere) and accelerate the whole thing to 0.6c. Once it gets half way, use the onboard laser to decelerate the shuttle. The rest of the craft travels in to space at 0.6c forever (no doubt bearing a plaque with naked people on it).

To make things a little more economical, the first trip might just contain a load of robots and a second laser to be put into orbit around Alpha Centauri. After that's in place, you can send supplies and people back and forth more economically: using one laser to accelerate, and one to decelerate,

Answer 2

Use a solar sail.

Advantages:

• Solar sails are lightweight(-ish)
• They can be used for propulsion
• According to Dandouros et al., solar sails built with technology in the near future could easily travel to a nearby star system in 60 years, reaching a top speed of $0.16 c$.
• You might want to use a solar sail merely for braking, so it's good that solar sails are low-mass (see this article, especially the part about the material called CP-1) and can be folded up.

For the calculations, an interesting reference is Solar sail thrust calculation:

In Space Mission Engineering: The new SMAD, page 555, section 18.7.2, the following thrust formula is given for a solar sail: $$F=\frac{2RSA}{c}\sin^2\theta=9.113\times10^{-6}\frac{RA}{D^2}\sin^2\theta$$ Where, $F$ is the thrust; $R$ is the fraction of incident light; $D$ is the distance from the Sun in astronomical units; $S$ the solar flux in $W/m^2$; $c$ the speed of light; $A$ the sail area in $m^2$ and $\theta$ the sail tilt angle.

If we set $\theta=\frac{\pi}{2}\text{ radians}$, then we find $$F=9.113\times10^{-6}\frac{RA}{D^2}\tag{1}$$ If we're being optimistic, and saying that $R\approx 0.5$, then $$W(s)=\int_{s_0}^s F\cdot dD=\int_{s_0}^s 9.113\times10^{-6}\frac{A}{2D^2}dD$$ $$W(s)=-\left[9.113\times10^{-6}\frac{A}{2D}\right]_{s_0}^s$$ Here, $W$ is work. Be careful to also account for changes in potential energy in your calculations. Also, there should actually be a sign flip in there (i.e. the $-$ should by a $+$), but that's superficial.

We can then use $$KE=\frac{1}{2}mv^2$$ to find the speed at any given distance, assuming that $S$ is constant (which it isn't - it's a function of $D$); given that $\frac{dS}{dD}\neq 0$, that must be accounted for for long-distance calculations.

For more fun, use $v=\frac{dD}{dt}$ to find the time it will take the sail to go from one point to another.

Since solar sails don't use fuel, there won't be any pollution or fallout from their use. They're a perfectly clean propulsion and braking technique. Also, you say you're using laser propulsion. Perhaps you could create (hypothetically) a large group of lasers and fire them at the craft, creating additional thrust.

Answer 3

There are no good passive braking methods for such speeds that don't smash the mission. The key factor is that maximum mission deceleration is limited to fairly low values, which means a large braking distance.

Solar sails. Using the notation of HDE-226868's answer, the braking force is $F\simeq10^{-5}\frac{N\cdot a.u.^2}{m^2}A/D^2$. It is obvious that mission deceleration will be greatest at the minimum distance: $Mg_{max}\simeq10^{-5}\frac{N\cdot a.u.^2}{m^2}A/D_{min}^2$, where $M$ is the mission mass and $V$ will be the mission velocity. The work of the braking force, braking from infinity, will equal the mission's kinetic energy at infinity:$MV^2\simeq10^{-5}\frac{N\cdot a.u.^2}{m^2}A/D_{min}$ (the term corresponding to maximum distance vanishes). Dividing these two equations, we can obtain the relation $g_{max}D_{min}\simeq V^2$. It holds for any solar sail regardless of efficiency, material, target star &c. For interstellar but not relativistic speeds, let $V=\beta c$, then $D_{min}\simeq\beta^2\frac{c^2}{g}\frac{g}{g_{max}}\simeq10^5\,a.u.\beta^2\frac{g}{g_{max}}$ where $g$ is Earth gravity. Substituting this back into the mission deceleration equation, we see that the area density of the sail is inversely proportional to the fourth power of mission velocity: $M/A\simeq10^{-16}\,kg\,m^{-2}\frac{g_{max}}{g}\beta^{-4}$. If the mission is carrying something squishy like humans, $g_{max}$ must be on the order of $g$. Assuming a mission velocity marginally attainable with known technology $\beta=0.1$, our braking sail must weigh at most $10^{-12}\,kg\,m^{-2}$. This is quite beyond the capacity of any known reflective material. (For comparison, a one-atom-thick sheet of aluminium would be around $10^{-7}\,kg\,m^{-2}$.) A fully solid-state probe could, perhaps, sustain decelerations as high as $1000g$, but the sail would need to sustain them as well. Solar sails aren't likely to be useful for braking an interstellar mission.

Braking on interplanetary medium. Unless one is traveling to a young planetary system full of dust (which, ipso facto, will have no useful planets), IPM seems to be only dense enough to be a nuisance and many orders of magnitude away from being useful for braking a mission traveling at interstellar velocity. If we assume that IPM material simply accretes to the mission, the braking force $Mg_{max}=\rho SV^2$ where $\rho$ is IPM density and $S$ is the cross-section of the mission vehicle. Mean IPM density in the vicinity of Earth is on the order of $10^{-19}\,kg\,m^{-3}$[1], and it falls off with distance from the primary as $r^{-1.3}$[2]. For given $V$ and $g_{max}$, mission vehicle must have $M/S\lesssim\rho V^2/g_{max}$. The latter fraction is just the braking distance: $D_{brake}\sim V^2/g_{max}$, so $M/S\lesssim\rho D_{brake}$. Using again $g_{max}=g$ and $\beta=0.1$, $D_{brake}\sim10^{14}m$ and $M/S\lesssim10^{-6}\,kg\,m^{-2}$. This is much less flimsy than the solar sail, above, needs to be. However, the braking distance ($600\,a.u.$ in our case) is much larger than the effective radius within which IPM is sufficiently dense.

If hypervelocity impacts of IPM particles produce explosions and eject material, the braking force seems to be enhanced by a factor of $\sim\frac{v_e}{L}V$, where $v_e$ is the exhaust velocity of ejected material and $L$ is the specific heat of sublimation of the materials involved. For $\beta=0.1$ and $v_e\sim 3\,km\,s^{-1}$ characteristic of chemical explosions, this factor is on the order $10^2$ and the mission can be heavier, $M/S\lesssim10^{-4}\,kg\,m^{-2}$ (though it must now withstand the explosions, a daunting prospect). Nevertheless, this does not remove the tyranny of braking distance and probably precludes the use of this braking method.

Electrodynamic braking on interplanetary magnetic field does not appear to be effective [3].

Answer 4

Underused in SF is the idea of magnetic breaking.

I recall reading about the math of a Bussard ramjet that it can't work because the drag is greater than the energy produced.

But, instead of tweeking it as much as possible to reduce drag, turn the problem on its head: optimize it to maximize drag, and you have an excellent brake.

I planned on using that in a story, but lost track of the notes I took at the time. Google shows some suggestive topics, though.

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Robert L. Forward wrote about lightsails. in Flight of the Dragonfly/Rocheworld, he used a detachable ring for the main part of the sail. The earth-based laser reflects off the sail and back to the craft with its much smaller piece of the sail, slowing it down.

Answer 5

Silly answer: lithobraking - i.e. just crash whatever piece needs to stop into solid rock.

(This would in fact be very destructive, of both the crew, their vessel, and the destination. The hot Jupiter planet might not notice an aerobraking ship, but the crew sure would.)

Answer 6

A simple light sail isn't going to cut it—you're not going to brake from 60%c with one.

If you want a hard-science answer the only thing I see is to use your launch laser. This uses a light sail but it's powered by the laser beam rather than just sunlight, it can accelerate harder and longer than something simply using the central star for power.

Now, to stop you cut off a ring of your sail—this must comprise most of the sail and most of the mass of your spacecraft. The ring flips over (or more likely simply inverts and reflects off the back side of it) and focuses its energy on the inner piece. Note that this requires incredible accuracy and is almost certainly beyond current technology.

For a more detailed look at this read Robert L Forward's Flight of the Dragonfly. The numbers in that book are scary indeed—the launch laser is a facility around (not in orbit! It would push itself away from the planet in operation if it were) Mercury, the final focusing lens is in the outer solar system and is of planetary scale. Furthermore, his craft was only doing 20% of lightspeed. He ignored the accuracy problem of the ring focusing its energy on the decelerating spacecraft.

In theory the same approach could be used again to return, discarding another ring comprising most of the remaining mass to boost for home. Stopping on the launch laser won't be a problem.

The sails must be gargantuan and incredibly shiny as they will be bathed in a laser beam from hell and they can't have a cooling system, they must simply reflect off enough energy that they can radiate away whatever they absorb.

I believe a much more viable approach is to send out the first craft with only robots on board. It goes considerably slower and brakes on an unboosted sail. It then proceeds to construct a laser that's a duplicate of the launching laser. You still need huge sails but you're not discarding most of the sail so it's nowhere near as big as it would have to be using the separating sail approach and you eliminate the aiming problem.

The more I look at aerobrake the worse it gets.

1) The toughest aerobrake we have ever done was 47 km/sec—and at a cost of ½ of the weight of the probe being devoted to the heat shield, half of which burned away in the process. This is almost 4000× the energy.

2) I'm not competent to figure the actual deceleration involved but I can show that it's well above a million gravities. (Scaling up the Galileo probe gives a million g but it runs out of planet well before it's done. Thus the actual value must be considerably higher.) The toughest electronics we build are artillery shells—something around 1% of this energy.

3) At this kind of velocity air ceases to behave as a fluid, but rather as particles. Heat shields are based on deflecting away most of the energy that hits them but the particles won't be deflected. Your shield is going to absorb energies greater than a matter-antimatter explosion.

Answer 7

Best answer with currently understood technology:

Only remaining reasonable method not already discussed: use H-bombs (that is, Orion drive). Despite its dry mass, the high efficiency of the Orion drive makes it unbeatable for long flights by current technology. 0.1c is attainable this way, and trying to break with a solar sail is not feasible at this speed due to inadequate force available. We can avoid most fallout problems by using a nuclear-hydrogen rocket for a planeshift burn first.

This speed still makes a 40+ year flight though.

Look, if you wanna get up to 0.6c and back down to 0 again you're gonna need an antimatter drive, and you're still going to need > four times your rest mass in fuel. But right now, we don't have a solution for containing that much antimatter with the fuel fractions to make this remotely reasonable.

Answer 8

To be blunt: the same way it accelerated. At 0.6c, there is nothing that can be used for braking but not for acceleration.

Answer 9

You mentioned a crew. Crews are squishy.

If your ship has humans in it, it's not a good idea to submit them to accelerations much higher than Earth's gravity.

I have no suggestion on propulsion methots, but the old-school "halftime" strategy as you put it is the only way to go.

Answer 10

I don't have much to add about drive technology -- it's already been covered. (FWIW, I favor the Orion drive at 0.1c max or antimatter tech stack.)

That said, I think it's worth noting that your concerns about radiation are probably overstated. Once you get outside the earth's magnetic field, you are exposed to massive quantities of radiation from the sun. Per space.com:

...the radiation dose received by an astronaut on even the shortest Earth-Mars round trip would be about 0.66 sievert. This amount is like receiving a whole-body CT scan every five or six days.

By implication, any society that can build space habitats is capable of dealing with radiation exposure.

Answer 11

Does the main ship even need to slow down significantly? It might be beneficial to try to keep most of the main ships momentum - instead put it into a big path around the star, using whatever thrust you have to steer inwards over a long period. Meanwhile the smaller "shuttle craft" has detached from it, and its this little craft that has to then slow down. While your still stuck with the prospect of needing to slow down from 0.6C, it should be significantly easier to do with the (presumably much smaller) mass of the little craft. While its never "easy" slowing down from high speeds, the smaller the mass the less energy it will take.

You then either have the big ship slow down over a (much much longer) period using sails or a ion-drive, or try to get that little craft at least briefly upto 0.6C itself to rejoin its main craft for the trip back. (the main craft having never slowed down much at all).