Are you thinking of something like a focus fusion device as the neutron source?
Exhaust velocity is 10,734 km/s. Not m/s; km/s.
Quote from: sevenperforce on 03/21/2016 06:14 pmExhaust velocity is 10,734 km/s. Not m/s; km/s.That is the lovely thing about nuclear reactions in this case. Chemical bond energy is generally negligible in comparison.With an Isp of ~1.1e6 seconds, you wouldn't need much reactant mass. Given that the nuclear fragments are almost certainly going to be ionized, could you use a magnetic field for the nozzle?
The challenge would be getting neutron fluxes high enough for useful thrust. Back-of-the-envelope estimates suggest 1019 neutrons per second for a single Newton of thrust.
Quote from: sevenperforce on 03/21/2016 07:09 pmThe challenge would be getting neutron fluxes high enough for useful thrust. Back-of-the-envelope estimates suggest 1019 neutrons per second for a single Newton of thrust.So, compute the power output of a 1N thruster with 1.1e6 Isp. By comparison to ion thrusters, 1N is a huge thrust.
Well, the power output at 1N is simply 5.5e6 watts. But that is the output, not the input. The input depends on how you are generating your neutron flux.
Quote from: sevenperforce on 03/22/2016 12:10 amWell, the power output at 1N is simply 5.5e6 watts. But that is the output, not the input. The input depends on how you are generating your neutron flux. The quote that comes to mind isa reaction drive's efficiency as a weapon is in direct proportion to its efficiency as a drive -- Larry NivenSo, you've got a drive that produces 5.5 megawatts of power expressed as a beam of relativistic ions. At close range this is a weapon. I don't think you need anything like the thrust of a SuperDraco because you'll not want to use this on a planet because you'll damage things. Also the effect in atmosphere could be interesting.Probably the limiting factor is the neutron source. But even if you can only make micro-newtons of thrust, at 1.1e6 Isp you can thrust for a long time on one block of fuel. I wonder if you could build something like this into a cubesat?
To match the thrust of a single SuperDraco you would need a neutron source capable of producing 5.91e23 neutrons per second.
Lithium-6 decays exothermically into helium and tritium when irradiated with sufficiently energetic neutrons.[...]You'd need a bit of mass to give the neutron source a high enough energy
What kind of neutron source can generate a gram/sec of neutrons?What kind of power input would you need for that?Even milligrams/sec is awesome. Micrograms/sec ...
How would you avoid, or at least mitigate, chemical ignition of the lithium fuel? Lithium will chemically react with both of the fission products.
Coating the fissile material on the inside of a nozzle dose not seem practical, the neutron bombardment will penetrate into the coating even if it is fairly thick and cause fission in the whole mass of fissile material. The resultant fissile byproducts will be generated inside a solid fuel mass and will collide with neighboring atoms and cause standard thermal interactions as they slow down, the whole fuel mass will simply heat up rather then emit a surface sputtering that I think your looking for.Some form of tiny-pellet feed system inside a magnetic nozzle seems to be the only way to get a well controlled reaction that would produce manageable thrust. The pellets can also contain non-fissile materials preferably highly transparent to neutrons which will be vaporized and contribute the bulk of the reaction mass, this will lower the ISP down to usable ranges, different pellet mixtures could produce different thrust and ISP ranges for the engine allowing a kind of throttling which has been shown to improve overall trajectory planning. The neutron source would need to be pulse based and would only need to produce a single standard pulse both of which should make it simpler.
I had posted a thread about nuclear salt water rocket a few months ago.quite interesting that the proposal of your link is basically the NSWR without the hiper radioactive exhaust!
This is a significant improvement over the traditional NSWR concept which would have relied on a fuel so enriched that it will spontaneously detonate in the absence of a neutron absorbing materials. That would require a large and heavy storage tank to prevent the entire fuel mass from becoming the worlds largest bomb.
Quote from: RotoSequence on 03/22/2016 05:32 amHow would you avoid, or at least mitigate, chemical ignition of the lithium fuel? Lithium will chemically react with both of the fission products.Well, I had proposed using lithium hydride rather than pure lithium metal, as this increases the particle count and also prevents the lithium from reacting (since it has already reacted). Of course the helium won't react with anything. The monatomic hydrogen might react with itself but that's not necessarily a bad thing. Specific impulse is less important here so an increase in molecular weight is not really a bad thing.
It's forced supercriticality.. just like every other nuclear device. It's nonsense to suggest that somehow the tank can explode.
Quote from: sevenperforce on 03/22/2016 02:38 pmQuote from: RotoSequence on 03/22/2016 05:32 amHow would you avoid, or at least mitigate, chemical ignition of the lithium fuel? Lithium will chemically react with both of the fission products.Well, I had proposed using lithium hydride rather than pure lithium metal, as this increases the particle count and also prevents the lithium from reacting (since it has already reacted). Of course the helium won't react with anything. The monatomic hydrogen might react with itself but that's not necessarily a bad thing. Specific impulse is less important here so an increase in molecular weight is not really a bad thing.This is not correct; Lithium will bond with helium in sufficiently energetic conditions, and lithium fires are not pretty things. We're still talking about some violently exothermic conditions that would be very difficult to contain and chemically volatile; I can't foresee a lithium driven vehicle being anything better than a nuclear equivalent of a contemporary solid fuel rocket.
Launch pads are expensive. How can we make spaceflight cheaper if we melt a launch pad at each launch?but more seriously, can we get high thrust in this system with current tech?lower thrust systems, making it possible to reach Mars fast, but without launching from Earth... feasible with current tech?
there is probably a catch somewhere in there. If there are only pros, but no cons, it would already be in use, since as you showed yourself, another guy FRIEND with Zubrin even already came with a very similar concept.
Hey guys, I'm kind of new here. I was just curious. Wouldn't such system produce an enormous pressure inside combustion chamber?
Quote from: QuantumG on 03/23/2016 05:48 amIt's forced supercriticality.. just like every other nuclear device. It's nonsense to suggest that somehow the tank can explode.A breach or leak would cause a tank explosion just like a breach between two hypergolic. Only this is a nuclear explosion.
It is the rocket equivalent of assembling multiple critical masses of plutonium in a supercritical state with boron control rods jammed in to prevent instant nuclear detonation and then slowly removing the control rods to generate heat, hoping you don't pull them out too far and cause a multiple-kiloton detonation.
Their is nothing 'forced' about the super-criticality other then simply removing neutorn absorbers.
I added a separate coolant loop for the reactor; it can use a blend of heavy and light water to fine-tune neutron moderation. Pure heavy water and pure light water can also be added to the propellant stream as desired. The coolant loop exits around the central flow of propellant to protect the inside of the chamber and nozzle and also decreases specific impulse in exchange for increased thrust.You can't expect full expansion so this will be a pressure rocket.
Quote from: sevenperforce on 03/24/2016 04:55 pmI added a separate coolant loop for the reactor; it can use a blend of heavy and light water to fine-tune neutron moderation. Pure heavy water and pure light water can also be added to the propellant stream as desired. The coolant loop exits around the central flow of propellant to protect the inside of the chamber and nozzle and also decreases specific impulse in exchange for increased thrust.You can't expect full expansion so this will be a pressure rocket.Wrap a set of coils around the outside of this and you have a magnetic nozzle:http://alfven.princeton.edu/projects/MagneticNozzle.htmThis would allow you to get additional expansion since the fission products are going to be charged particles.I really think you want a closed loop coolant system. It could provide power for the magnetic nozzle among other things. This seems to have the most potential for use as a deep space propulsion system, where you want to be able to operate in the highest Isp mode most of the time. For the very highest Isp, store your Li6 as a solid block. Use a laser to vaporize some off the surface, then another laser to ionize it, then feed the resulting puff of plasma down the center of the magnetic nozzle into your neutron source.
That would be ideal for a deep space propulsion system that can accelerate indefinitely. However, for something I can actually use to get off the ground, I need high thrust.
I'm not sure what can be done about the release of tritium. This would be orders of magnitude less dangerous than a uranium NSWR or even Project Orion, but it is still releasing full kilograms of tritium with each launch. Tritium is not terribly nasty but it is not exactly safe either. I landed on heavy water as the combined fuel carrier + reaction mass + neutron moderator because it really simplifies the design and would allow for a lot of fine-tuning of engine performance without changing the essential configuration. Good for adjusting specific impulse and thrust and so forth. It is also intrinsically safe if your moderator is also your reaction mass, because its presence is what expels it. But a more neutron rich fissile fuel might give more options. You could also use a different comment, like liquid ammonia, with a salt carrier like ethanol.
How much fuel (of every kind) would be needed to get to Mars or Jupiter in a decent short time? And so, how big would be the spaceships with this engine? Considering the possibilities talked about in this thread, that is, high ISP and decent thrust, it would still be feasible to launch from a few Falcon Heavies. Never land it again. Every time it comes back to Earth, keep it in orbit and refuel it.
I think Tritium is just going to be a showstopper for Earth surface launch unless the rockets production of tritium is really really tiny and the amount released would not significantly raise background levels that exist naturally and are released from conventional nuclear industry activities. Can we try to estimate the quantity that might be released per unit of rocket impulse.I'm thinking that the main challenge of the engine is going to be keeping a high enough neutron flux in the combustion chamber to get an acceptable burn-up percentage of the lithium while the lithium is removing neutrons from the chain-reaction that is producing these neutrons. If you take too many neutrons and the chain reaction is quenched and the propellant will stop burning and likely can't be lit again until the lithium flow is halted so the neutron flux can recover. If the reactor is over producing neutrons then you have a potential super-critical state and explosion particularly when their is no propellant flow in the reactor. You want to have a way of shutting down the reactor and dropping the neutron flux, perhaps you really do want to propellant flow to contain most of the neutron moderators as their absence will naturally quench the reactor as fast neutrons don't absorb well and don't sustain a chain reaction as easily. Also the proposed coolant loop could contain Helium which is an efficient moderator, losing the coolant either in a breach or by intentionally changing it to a different gas such as one with boron would rapidly quench any chain-reaction.
This isn't quite torchship level
I doubt it could manage a 1g brachistochrone to Mars
Quote from: sevenperforce on 03/25/2016 07:01 pmThis isn't quite torchship levelis torchship only a sci-fi term or is there a more serious design that could be called a "torchship"?
To summarize the engine I see under discussion:- A mass of nuclear fission fuel, subcritical absent the propellant.- Introduce the propellant through coolant passages and down the reactor core, neutrons are moderated sufficiently to shift the reactor critical.- Some of the neutrons produced react to fission lithium in the propellant, producing more heat.Observations / questions:- heating the propellant will reduce density, reducing neutron moderation effect. Get the design right and the reactor will be largely self regulating.- How much heat would be produced by the fission fuel producing the neutrons relative to heat from lithium fission? The original post implicitly assumed a majority of heat being from the lithium fission, not the neutron source.
You guys must be missing something about Lithium being such a nice fission fuel, since none of the existing fission reactors or bombs use lithium in any way. If it would be usable, surely it would be used by military instead of, or as an additive to the heavy and more expensive Uranium.
Quote from: gospacex on 03/26/2016 04:33 pmYou guys must be missing something about Lithium being such a nice fission fuel, since none of the existing fission reactors or bombs use lithium in any way. If it would be usable, surely it would be used by military instead of, or as an additive to the heavy and more expensive Uranium.Hey, good questions!...Plus, it's not good to use a neutron poison as part of your reaction fuel; as it is used up, it will slowly increase criticality and could lead to a runaway chain reaction and meltdown. Adding lithium to try and increase the yield would require MORE fissile uranium or plutonium.
Quote from: sevenperforce on 03/26/2016 09:15 pm...it's not good to use a neutron poison as part of your reaction fuel; as it is used up, it will slowly increase criticality and could lead to a runaway chain reaction and meltdown. Adding lithium to try and increase the yield would require MORE fissile uranium or plutonium.Actually, this is not true that adding nuclear poisons to the fuel is a bad idea. For years, nuclear power industry is working towards making fuel campaigns longer, since each reload is a 20-30 day long reactor shutdown. 12 month power campaigns are generally replaced by 18-month ones now, and 24-month ones are in works.To that end, more enriched fuels were necessary, and by now the 5% enriched fuel is standard. But reactors were not designed to use such reactive fuel, and nuclear poisons are deliberately added (I heard about Europium), to make fuel reactivity-versus-time curve flatter, and lower.If Lithium is a nuclear poison which also exotermically fissions (unlike Europium), why is it not added to the fuel? Such fuel would be more energetic.
...it's not good to use a neutron poison as part of your reaction fuel; as it is used up, it will slowly increase criticality and could lead to a runaway chain reaction and meltdown. Adding lithium to try and increase the yield would require MORE fissile uranium or plutonium.
I think I see the flaw with the proposal. To fission Lithium, you need a neutron source to generate *one neutron for every Lithium atom*:Li-6 + n -> T + He-4 + 4.7829 MeVThen you need to avoid thermalization of fission fragments and you need to collimate them into a directional beam. How far away form 100% efficient that will be?You can save yourself a lot of trouble if you just use your neutron source as a rocket engine. Must be about the same ballpark wrt trust....Which hints that the showstopper here is that it's hard to generate that many neutrons. What do you propose to be your neutron source? What's its luminosity?
This seems to be the kind of core you would wanthttps://en.wikipedia.org/wiki/High_Flux_Isotope_ReactorAs we speculated earlier a large jacket of neutron reflector (beryllium) surrounds the core which has a 5 inch across hollow center to allow samples to be exposed to the high thermal neutron flux which is 2.5 x 10^15 neutrons per cm^2/sec, given this value it should be possible to calculate the fission rate of lithium within the reactor based on the known cross section of lithium-6.
Zubrin throws out a tank mass fraction of just 4% with no supporting evidence at all and which I find laughably small
The math looks to be a lot more complex then that sevenperforce, these links look like they provide the means to calculate it. See if they help, I'll dive into them myself tomorrow and see if I can produce an independent calculation to see if we agree.
I WANT to thermalize the fission products. I DON'T want to try and collimate relativistic ions; it is far far easier to dissolve the lithium salt in water and let the water serve both as a thermalization medium and as the pressurized reaction mass. The fuel is dissolved in water; the fuel is used to heat the water; the water and the fuel's reaction products are expelled together. Pretty simple.
Quote from: sevenperforce on 03/26/2016 11:08 pmI WANT to thermalize the fission products. I DON'T want to try and collimate relativistic ions; it is far far easier to dissolve the lithium salt in water and let the water serve both as a thermalization medium and as the pressurized reaction mass. The fuel is dissolved in water; the fuel is used to heat the water; the water and the fuel's reaction products are expelled together. Pretty simple.If you thermalize neutrons and fission products, you get a NTR and/or NSWR. If you don't thermalize them, you get a fission fragment engine (which is a good engine... if you can overcome engineering/materials challenges).
A neutron multiplier without a radioactive byproduct, if it exists it would certainly be desirable. From what I can find Beryllium dose multiply neutrons by splitting into 2 alpha particles + 2 neutrons and by transmuting into carbon + 1 neutron upon absorbing alpha particles so it seems the High Flux reactor noted earlier is likely making significant use of such multiplication.The only other elements I can identify that are good multipliers are Lead, Bismuth and at a much reduced rate Zirconium which has the advantage in a much higher melting point. All of these can expel 2 or 3 neutrons when absorbing a thermal neutron WITHOUT fission though they do form radioactive isotopes like Polonium. But all are considered inferior to Beryllium on Earth before mass has even become a concern as it would in an engine, only the toxicity of Beryllium and it's cost are an issue, and these are likely to be surmountable in a rocket engine.In addition I'm reading that carbon is considered a good neutron reflector and it's low density would be desirable in keeping the engines power to weight ratio up. I'm envisioning an engine with a conventional combustion chamber throat and funnel with one or more hollow central channel reactors injecting lithium salt into the combustion chamber.
Are there any fissionable isotopes which produce a chain reaction without nasty nucleotide products?
It's not as clean or as high-energy as pure lithium fission, but it would still be far better than a conventional NSWR, because the fuel would not be able to achieve critical mass on its own (due to the presence of lithium-6), making it safer. Plus, it would have a much higher specific energy than a NSWR due to the low mass and high energy of lithium.
Quote from: sevenperforce on 03/30/2016 01:24 pmIt's not as clean or as high-energy as pure lithium fission, but it would still be far better than a conventional NSWR, because the fuel would not be able to achieve critical mass on its own (due to the presence of lithium-6), making it safer. Plus, it would have a much higher specific energy than a NSWR due to the low mass and high energy of lithium.You are still fixated on lithium.What "high energy of lithium"? It gives you 4.78 MeV from one Z=6 nucleus fissioning, a bit below 0.8 MeV per nucleon.Fission of usual suspects U/Np/Pu gives ~200 MeV per Z~=235 nucleus, which is about the same power density, actually a bit better: 0.86 MeV per nucleon.
Neutron Induced Lithium Fission ReactionThe showstopper is, of course, the need to produce neutrons.If you have a cheap source of neutrons, you could also consider Calcium-48. If turned into Calcium-49, I think the decay chain Calcium -> Scandium -> Titanium gives a total of 12 MeV, via beta minus decay (I looked it up years ago, this is from memory). Not so good for an engine, but good as a powerplant.
I'm a little boggled at how a system that expels masses of Tritium is considered "clean"?Ok, no surplus Neutrons... BUT you need a ridiculously intense neutron source to activate it.So, where exactly does this "clean" come in?
Quote from: Pete on 11/01/2019 11:19 amI'm a little boggled at how a system that expels masses of Tritium is considered "clean"?Ok, no surplus Neutrons... BUT you need a ridiculously intense neutron source to activate it.So, where exactly does this "clean" come in?https://en.wikipedia.org/wiki/Nuclear_salt-water_rocket#LimitationsIt's "clean" only in that it's cleaner than Zubrin's NSWR, which exhausts actively fissioning uranium/plutonium salts.
Could you use this to augment thrust of a chemical rocket?
A layer of lithium-6 hydride deposited onto a beryllium bell nozzle and irradiated ...
The fuel is dissolved in water; the fuel is used to heat the water; the water and the fuel's reaction products are expelled together. Pretty simple.