Please assume the following:

A spaceship in the far future.

Output: The ships systems have a high base demand of energy and sometimes you need extreme amounts of Energy in a very short period of time.

Input: An advanced fusion reactor is used to provide baseline-power. There are a range of 'injections' into the system, some of them sudden, extreme energy peaks, some minor and rising/falling softly.

What would be the best way to store energy and provide the necessary flexibility?

As-always: Assume future tech, I'll accept plausible handwaves, but please keep them as minor as possible.

  • $\begingroup$ Not a duplicate but related subject wise. $\endgroup$
    – Green
    Commented Apr 22, 2016 at 12:39
  • $\begingroup$ Thanks. I've already read through that thread because it showed up when I created the question. The main difference seems to be 'far future' here. $\endgroup$
    – user6415
    Commented Apr 22, 2016 at 12:46
  • $\begingroup$ This just reminds me of the electrolytic capacitors we use to smooth out power fluctuations in electronics. Unsurprisingly, half the answers so far recommend capacitors :P. However, you don't clarify what "Energy" is, so I assume you're either handwaving it or you haven't decided what it is yet. A capacitative mechanism is definitely what you need, electric or not, but if your ship uses electrical energy then you've already got a lot of the technical stuff figured out. $\endgroup$
    – mechalynx
    Commented Apr 22, 2016 at 19:04
  • $\begingroup$ Yes, I am talking about electrical energy here. It seem to be the most easiest to handle and store, or is it? $\endgroup$
    – user6415
    Commented Apr 22, 2016 at 21:58
  • $\begingroup$ @openend Generally yes, electricity has the advantage that you can make an energy storage device without moving parts. It also works well with a reactor based on fusion since we have some proposed designs that generate electricity directly, rather than generating heat which is then converted to electricity. Currently we don't have the capability to store electricity after it is generated with as much density as most fuels, but if your storage device can muster enough energy density and can handle high currents (see superconductors and heatsinks) then yes, you should be fine using electricity. $\endgroup$
    – mechalynx
    Commented Apr 23, 2016 at 14:17

7 Answers 7


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  • $\begingroup$ Room-temperature superconducting unobtainium is quite a handwave. $\endgroup$
    – Mazura
    Commented Apr 22, 2016 at 23:45
  • 9
    $\begingroup$ @Mazura 0.1 K is not what I would consider room temperature. $\endgroup$ Commented Apr 23, 2016 at 1:02
  • $\begingroup$ Modern superconductors are either in the sub 30K range (low temp superconductor) or in the sub 138K range (high temp superconductor). FYI, room temperature is 293K, K is Kelvin. It's actually more likely that the superconductor is at a higher temperature (since cooling things actually takes a fair amount of energy) and at the moment, we can cool them with liquid nitrogen. $\endgroup$ Commented Apr 23, 2016 at 4:09
  • $\begingroup$ Breaking news, Nikola Industries products specifically kill children. $\endgroup$
    – corsiKa
    Commented Apr 23, 2016 at 5:23
  • 1
    $\begingroup$ If it's storing enough energy to meaningfully buffer a fusion reactor, I don't want to be anywhere near it when it quenches. $\endgroup$
    – MadHatter
    Commented Apr 23, 2016 at 8:56

Supercapacitors is my answer to you. A supercapacitor is essentially a big battery that discharges (or at least can discharge) a lot of energy in a short amount of time. They are used for short-term energy storage or delivering massive bursts of energy.

An example of burst-mode is KERS on racecars. You can use supercapacitors to store energy when braking and keep said energy for the next straight-away if you need a speed boost.

  • 4
    $\begingroup$ Present-day supercapacitors have very poor energy density though -- to hold the energy of a single tank of gasoline, you'd need a ~50 ton supercapacitor, and I imagine the fusion reactor would produce more power than that. (Lockheed Martin’s 2017 high-beta fusion reactor is planned to produce 100 MW, which would fill the 50-ton supercapacitor in seconds; probably the far future starship's fusion reactor is better.) $\endgroup$
    – Charles
    Commented Apr 22, 2016 at 14:51
  • 1
    $\begingroup$ @Charles Presumably, future technology could solve this problem. $\endgroup$ Commented Apr 22, 2016 at 14:53
  • 3
    $\begingroup$ I don't think that's a solution. Supercapacitors get better, but so do fusion reactors and energy requirements. Of course we can just handwave them to vastly outstrip the other two, but at that point we just have unobtanium. $\endgroup$
    – Charles
    Commented Apr 22, 2016 at 15:08
  • 1
    $\begingroup$ What about using supercaps for demand spikes, and doing the dense energy storage in very large flywheels? You have easy access to vacuum, so air resistance isn't a concern, and some fancy carbon structure lubricant (C60, anyone?) should do fine to combat sliding friction. $\endgroup$ Commented Apr 25, 2016 at 19:33
  • $\begingroup$ @realityChemist Flywheels store mechanical energy. I don't really know how efficient the system would be since you'd have to convert energy into mechanical energy and back into electricity. $\endgroup$ Commented Apr 26, 2016 at 6:42

If anti-matter is available use that, else a superconducting capacitor

The absolute energy storage that can be had within the laws of physics as we know it is in the form of anti-matter. This relies on the complete conversion of matter to energy and with the giant constant c in

$$E = m c^2$$

this makes for a very efficient energy storage mechanism. However, using antimatter leads to some tricky creation and containment issues which may have been solved. One prime challenge is how do you absolutely ensure that the antimatter never touches regular matter till you want it to? Failing to solve this challenge leaves you with a rapidly expanding cloud of super heated gas that used to be your ship. You'll have to decide whether your tech is advanced enough to handle those challenges.

The Superconducting Super-capacitor

This is the more plausible approach since we may be able to do something like this in the next 50 years. Superconductors do weird things with electricity and magnetism at very low temperatures, chief of which is very low resistance to current flow. You'll need those ultra low resistance values when you're discharging the capacitor at max discharge rates.

You'll need the following advanced tech to make these super-capacitors:

  • Ultra-high resistance dialectrics. The better a dialectric you can get, the more power you can pack into the capacitor
  • High temperature superconductors. If given the choice between the cooling requirements of 4 Kelvin or 138 K, for the superconductors to work, thr wise designer will choose the high temp superconductor.

Make sure that your dialectric doesn't become a super conductor at low temperatures. That would be bad.

  • $\begingroup$ If only your former ship were just a cloud of gas. More likely it will be a soup of subatomic particles. You might even end up with a black hole. $\endgroup$
    – Phil Frost
    Commented Apr 22, 2016 at 14:56
  • $\begingroup$ Why would you need high temperature superconductors? Aren't superconductors defined by zero resistance? If so, how could the "resistance of metal components of the superconductor may heat up enough"? $\endgroup$
    – Phil Frost
    Commented Apr 22, 2016 at 14:59
  • $\begingroup$ Awesome concept using antimatter as energy "storage"! I wonder about the possibility of putting it in orbit for safe-keeping. First thought is, "Wait, what if it somehow deorbits?" - you'd wind up with a terrible bomb falling from the sky! Not sure if unexpected deorbit is more or less likely than a horrible accident back on Earth (where normal matter is plentiful). At least on Earth you would have a say on exactly WHERE this horrible accident would potentially happen. $\endgroup$
    – loneboat
    Commented Apr 22, 2016 at 15:26
  • $\begingroup$ (cont...) Maybe you could store it as an orbiting "cloud" of antimater? Then if it falls, its effects are spread over a much larger area, and there's no need to design a complex regular-matter container to store it in. Then you could go up into orbit, gather some antimatter from the cloud with a magnetic "net", and take your load back home at your convenience. $\endgroup$
    – loneboat
    Commented Apr 22, 2016 at 15:28
  • $\begingroup$ @loneboat The OP says nothing about the kind of spaceship or where it is. Any answer I give would be rampant speculation. $\endgroup$
    – Green
    Commented Apr 22, 2016 at 15:52

They can store energy with rotational energy, in a Flywheel Energy Storage device.

Flywheel Storage Device

These store energy by using a motor to spin up a flywheel in a vacuum sealed box, with the flywheel suspended by magnetic bearings. To charge it up, power is sent into the motor, spinning up the flywheel. When it is time to power your expensive ship systems (FTL drive, giant railgun, etc) you connect the motor as a alternator or dynamo and sap power from angular momentum.

The plus side of these is that they are current day technology. No hand-wave required for your basic model! They also interact well with hand-waving miracle materials that have higher tensile strength, which would allow more energy to be stored.

For extra fun, use superconducting bearings to reduce friction further and increase efficiency!

  • $\begingroup$ But how do flywheels cope with sudden huge spikes of energy draw? I was under the impression that flywheels need similar time to spin up or down, while the OP seems to be after something that can be "charged" slowly over time and "discharged" rapidly when needed. $\endgroup$
    – user
    Commented Apr 22, 2016 at 17:14
  • $\begingroup$ @MichaelKjörling Actually flywheels are already in use for exactly that purpose, see the linked Wikipedia article. Also since similar devices - reaction wheels - are already commonly used (in satellites), flywheels seem to be a logical next step. $\endgroup$ Commented Apr 22, 2016 at 20:38
  • $\begingroup$ @DanielJour Hm, maybe I was confusing flywheels and reaction wheels then. $\endgroup$
    – user
    Commented Apr 22, 2016 at 20:44

Don't store it; shunt it. While you're at it, go big or go home.

Storing energy is dangerous: ever seen Star Trek? It'd be better if it was shunted when not called for. Oversize your reactor to be able to supply enough power to complete any conceivable task. Then give it a quadruple safety margin. The question then becomes, how do you shunt 1.21 gigawatts when, "blow it out the top," (Quora) isn't feasible?

All good warships are capable of producing their required power on-demand. So much so, that they can supply emergency power to small cites if they want: "U.S.S. Lexington provides electricity to Tacoma"historylink.org

  • $\begingroup$ How to shunt that energy really is a problem when you're in space and convective heart transfer isn't possible, except into the air where your humans are living $\endgroup$ Commented Apr 25, 2016 at 19:36

Nuclear batteries

The chosen answer is indeed, realistically, the best one. Superconducting solenoid batteries allow for the densest theoretical possible energy storage for electrical power, limited only by the chemical binding force of atoms to prevent it from flying apart from Lorentz forces. With something like aggregate diamond nanorods, you can reach energy densities of 20 MJ/kg easily. And while it doesn't look that impressive compared to, say, gasoline (one of the most energy-dense fuels out there, actually), remember that gasoline + oxygen is not as impressive, that you can extract as fast as you want, you don't need a bulky engine to extract said energy and that said bulky engine would be at best something 50% efficient anyway.

High-temperature high-power superconductors aren't that big of a handwave, nor even room-temperature, in fact, for fare future tech, if you don't want to bother with cryogenic equipment.

Also, it will turn all its stored energy into heat (aka violently explode) if damaged, heated too much or overloaded, which is always good for SF tech. Also also you can actually call it supersolenoid, which makes for nice technobabble.

But that's not enough! (After all, it never is.) We are talking about far-future tech! We don't want to be limited by weak atom bonds!

If you are OK with a bigger handwave and wants moar power! in storage, you can go for nuclear isomers. A nuclear isomer is an otherwise stable atom nucleus that is in an excited state. At some point it will decay, but unlike things like beta decay, it will only emit a gamma ray - and the process is (theoretically) reversible. And an excited nuclear isomer contains a lot of energy. Like more than a million MJ/kg. Simply put your far-future gammavoltaic cells to turn those gamma rays into electricity and you're fine.

The problem is, isomers come in two categories: the "barely existing" ones, that will revert in a nanosecond, and the "nearly stable" with an impractically long half-life. Stabilizing the former is probably impossible - but wouldn't it be nice if we could induce the latter to revert and emit that sweet, sweet high-energy photon?

Some guys pretended they had managed it with Hafnium isomers by spraying them with X-rays. Alas, this has been discredited since. Hafnium batteries have since gone the way of the Dean drive, the water engine and the EMDrive. Sigh.

But wait, not all hope is lost! Unlike those, the Hafnium battery wasn't dismissed out of hand by anyone with a modicum of knowledge in physics, because it could have worked! Which means that there may be other methods, beyond current technology, that actually work. Maybe with some exotic particle that require a brand new type of particle accelerator.

The point is, while today Hafnium batteries are bunk, they are still believable as far-future tech.

There is also the question or producing those Hafnium isomers, but if you can induce de-excitation, you should know how to induce excitation as well.

Hafnium isomers have 31 years of half-life, which is fine for short-term energy storage. If you need much longer-term, you can use Tantalum isomers instead. With 40 000 MJ/kg instead of a million, they are not nearly as dense (though still much better than supersolenoid batteries), but their half-life is much, much longer than the age of the Universe.

Those tables may be useful for comparison of storage densities, which is on of the main criteria here.


Compressed gas.


Compressed air energy storage (CAES) is a way to store energy generated at one time for use at another time using compressed air. At utility scale, energy generated during periods of low energy demand (off-peak) can be released to meet higher demand (peak load) periods.[1] This is especially important in an age where intermittent renewable energy sources such as wind and solar power is becoming more prominent energy sources. CAES systems can have a vital impact in making sure the electricity demands can be met at peak hours.

You could compress hydrogen instead of air, of course. Even in space hydrogen wants to be a gas. Hydrogen might be handy for other reasons too.


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