A rocket propellant is a
mass that is expelled from a vehicle, such as a rocket, in such a way as to create a
thrust in accordance with
Newton's third law of motion, and "propel" the vehicle forward. The engine that expels the propellant is called a
reaction engine. Although the term "propellant" is often used in
chemical rocket design to describe a combined fuel/propellant, propellants should not be confused with the
fuel that is used by an engine to produce the energy that expels the propellant. Even though the byproducts of substances used as fuel are also often used as a reaction mass to create the thrust, such as with a chemical rocket engine, propellant and fuel are two distinct concepts. In
electrically powered spacecraft, electricity is used to accelerate the propellant. An
electrostatic force may be used to expel positive ions, or the
Lorentz force may be used to expel negative ions and electrons as the propellant.
Electrothermal engines use the
electromagnetic force to heat low molecular weight gases (e.g. hydrogen, helium, ammonia) into a plasma and expel the plasma as propellant. In the case of a
resistojet rocket engine, the compressed propellant is simply heated using
resistive heating as it is expelled to create more thrust. In chemical rockets and aircraft, fuels are used to produce an energetic gas that can be directed through a
nozzle, thereby producing thrust. In rockets, the burning of
rocket fuel produces an exhaust, and the exhausted material is usually expelled as a propellant under pressure through a
nozzle. The exhaust material may be a
gas,
liquid,
plasma, or a
solid. In powered aircraft without propellers such as
jets, the propellant is usually the product of the burning of fuel with atmospheric oxygen so that the resulting propellant product has more mass than the fuel carried on the vehicle. The propellant or fuel may also simply be a compressed fluid, with the potential energy that is stored in the compressed fluid used to expel the fluid as the propellant. The energy stored in the fluid was added to the system when the fluid was compressed, such as
compressed air. The energy applied to the pump or thermal system that is used to compress the air is stored until it is released by allowing the propellant to escape. Compressed fluid may also be used only as energy storage along with some other substance as the propellant, such as with a
water rocket, where the energy stored in the compressed air is the fuel and the water is the propellant. Proposed
photon rockets would use the
relativistic momentum of photons to create thrust. Even though photons do not have mass, they can still act as a propellant because they move at relativistic speed, i.e., the speed of light. In this case Newton's third Law of Motion is inadequate to model the physics involved and
relativistic physics must be used. In chemical rockets, chemical reactions are used to
produce energy which creates
movement of a fluid which is used to expel the products of that chemical reaction (and sometimes other substances) as propellants. For example, in a simple hydrogen/oxygen engine, hydrogen is burned (oxidized) to create and the energy from the chemical reaction is used to expel the water (steam) to provide thrust. Often in chemical rocket engines, a higher molecular mass substance is included in the fuel to provide more reaction mass. Rocket propellant may be expelled through an expansion nozzle as a cold gas, that is, without energetic mixing and combustion, to provide small
changes in velocity to spacecraft by the use of
cold gas thrusters, usually as maneuvering thrusters. To attain a useful density for storage, most propellants are stored as either a solid or a liquid. Propellants may be energized by chemical reactions to expel solid, liquid or gas. Electrical energy may be used to expel gases, plasmas, ions, solids or liquids. Photons may be used to provide thrust via relativistic momentum.
Chemically powered Solid propellant •
Composite propellants made from a solid
oxidizer such as
ammonium perchlorate or
ammonium nitrate, a
synthetic rubber such as
HTPB,
PBAN, or
Polyurethane (or energetic polymers such as
polyglycidyl nitrate or
polyvinyl nitrate for extra energy), optional high-explosive fuels (again, for extra energy) such as
RDX or
nitroglycerin, and usually a powdered
metal fuel such as
aluminum. • Some
amateur propellants use
potassium nitrate, combined with
sugar,
epoxy, or other fuels and binder compounds. •
Potassium perchlorate has been used as an oxidizer, paired with
asphalt,
epoxy, and other binders. Propellants that explode in operation are of little practical use currently, although there have been experiments with
Pulse Detonation Engines. Also the newly synthesized bishomocubane based compounds are under consideration in the research stage as both solid and liquid propellants of the future.
Grain Solid fuel/propellants are used in forms called
grains. A grain is any individual particle of fuel/propellant regardless of the size or shape. The shape and size of a grain determines the burn time, amount of gas, and rate of produced energy from the burning of the fuel and, as a consequence, thrust vs time profile. There are three types of burns that can be achieved with different grains. ; Progressive burn: Usually a grain with multiple perforations or a star cut in the center providing a lot of surface area. ; Degressive burn: Usually a solid grain in the shape of a cylinder or sphere. ; Neutral burn: Usually a single perforation; as outside surface decreases the inside surface increases at the same rate.
Composition There are four different types of solid fuel/propellant compositions: ; Single-based fuel/propellant: A single based fuel/propellant has nitrocellulose as its chief explosives ingredient. Stabilizers and other additives are used to control the chemical stability and enhance its properties. ; Double-based fuel/propellant: Double-based fuel/propellants consist of nitrocellulose with nitroglycerin or other liquid organic nitrate explosives added. Stabilizers and other additives are also used. Nitroglycerin reduces smoke and increases the energy output. Double-based fuel/propellants are used in small arms, cannons, mortars and rockets. ; Triple-based fuel/propellant: Triple-based fuel/propellants consist of nitrocellulose, nitroguanidine, nitroglycerin or other liquid organic nitrate explosives. Triple-based fuel/propellants are used in
cannons. ; Composite: Composites do not utilize nitrocellulose, nitroglycerin, nitroguanidine or any other organic nitrate as the primary constituent. Composites usually consist of a fuel such as metallic aluminum, a combustible binder such as synthetic rubber or
HTPB, and an oxidizer such as ammonium perchlorate. Composite fuel/propellants are used in large rocket motors. In some applications, such as the US SLBM Trident II missile, nitroglycerin is added to the aluminum and ammonium perchlorate composite as an energetic plasticizer.
Liquid propellant In rockets, three main liquid bipropellant combinations are used: cryogenic oxygen and hydrogen, cryogenic oxygen and a hydrocarbon, and storable propellants. ;
Cryogenic oxygen-
hydrogen combination system: Used in upper stages and sometimes in booster stages of space launch systems. This is a nontoxic combination. This gives high
specific impulse and is ideal for high-velocity missions. ; Cryogenic oxygen-hydrocarbon propellant system: Used for many booster stages of space
launch vehicles as well as a smaller number of
second stages. This combination of fuel/oxidizer has high density and hence allows for a more compact booster design. ; Storable propellant combinations: Used in almost all bipropellant low-thrust, auxiliary or
reaction control rocket engines, as well as in some in large rocket engines for first and second stages of ballistic missiles. They are instant-starting and suitable for long-term storage. Propellant combinations used for
liquid propellant rockets include: •
Liquid oxygen and
liquid hydrogen •
Liquid oxygen and
kerosene or
RP-1 •
Liquid oxygen and
ethanol • Liquid oxygen and
methane •
Hydrogen peroxide and mentioned above alcohol or
RP-1 •
Red fuming nitric acid (RFNA) and
kerosene or
RP-1 • RFNA and
Unsymmetrical dimethylhydrazine (UDMH) •
Dinitrogen tetroxide and UDMH,
MMH, and/or
hydrazine Common monopropellant used for
liquid rocket engines include: • Hydrogen peroxide •
Hydrazine • Red fuming nitric acid (RFNA)
Electrically powered Electrically powered reactive engines use a variety of usually ionized propellants, including atomic ions, plasma, electrons, or small droplets or solid particles as propellant.
Electrostatic If the acceleration is caused mainly by the
Coulomb force (i.e. application of a static
electric field in the direction of the acceleration) the device is considered electrostatic. The types of electrostatic drives and their propellants: •
Gridded ion thruster – using positive ions as the propellant, accelerated by an electrically charged grid •
NASA Solar Technology Application Readiness (NSTAR) – positive ions accelerated using high-voltage electrodes •
HiPEP – using positive ions as the propellant, created using microwaves •
Radiofrequency ion thruster – generalization of HiPEP •
Hall-effect thruster, including its subtypes Stationary Plasma Thruster (SPT) and Thruster with Anode Layer (TAL) – use the Hall effect to orient electrons to create positive ions for propellant •
Colloid ion thruster – electrostatic acceleration of droplets of
liquid salt as the propellant •
Field-emission electric propulsion – using electrodes to accelerate ionized liquid metal as a propellant •
Nano-particle field extraction thruster – using charged cylindrical
carbon nanotubes as propellant
Electrothermal These are engines that use electromagnetic fields to generate a
plasma which is used as the propellant. They use a nozzle to direct the energized propellant. The nozzle itself may be composed simply of a magnetic field. Low molecular weight gases (e.g. hydrogen, helium, ammonia) are preferred propellants for this kind of system. •
Resistojet – using a usually inert compressed propellant that is energized by simple
resistive heating •
Arcjet – uses (usually) hydrazine or ammonia as a propellant which is energized with an
electrical arc •
Microwave – a type of
Radiofrequency ion thruster •
Variable specific impulse magnetoplasma rocket (VASIMR) – using microwave-generated plasma as the propellant and magnetic field to direct its expulsion
Electromagnetic Electromagnetic thrusters use ions as the propellant, which are accelerated by the
Lorentz force or by magnetic fields, either of which is generated by electricity: •
Electrodeless plasma thruster – a complex system that uses
cold plasma as a propellant that is accelerated by
ponderomotive force •
Magnetoplasmadynamic thruster – propellants include xenon, neon, argon, hydrogen, hydrazine, or lithium; expelled using the Lorentz force •
Pulsed inductive thruster – because this reactive engine uses a radial magnetic field, it acts on both positive and negative particles and so it may use a wide range of gases as a propellant including water, hydrazine, ammonia, argon, xenon and many others •
Pulsed plasma thruster – uses a Teflon plasma as a propellant, which is created by an electrical arc and expelled using the Lorentz force •
Helicon Double Layer Thruster – a plasma propellant is generated and excited from a gas using a helicon induced by
high frequency band radiowaves which form a magnetic nozzle in a cylinder
Nuclear Nuclear reactions may be used to produce the energy for the expulsion of the propellants. Many types of nuclear reactors have been used/proposed to produce electricity for electrical propulsion as outlined above.
Nuclear pulse propulsion uses a series of nuclear explosions to create large amounts of energy to expel the products of the nuclear reaction as the propellant.
Nuclear thermal rockets use the heat of a nuclear reaction to heat a propellant. Usually the propellant is hydrogen because the force is a function of the energy irrespective of the mass of the propellant, so the lightest propellant (hydrogen) produces the greatest
specific impulse.
Photonic A photonic reactive engine uses
photons as the propellant and their discrete relativistic energy to produce thrust. ==Projectile propellants==