Propellant

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Propellant is mass which is ejected from a jet engine (of which a rocket is one possible type) to produce thrust through Newton's third law of motion.

Science Background

Note that small light molecules (ones with low molar mass), make for better propellents. The reason for this is that temperature can be thought of the average momentum of a single particle of gas. Let us look at Hydrogen gas (each molecule is made up of two hydrogen atoms) and nitrogen gas (each molecule is made up of two nitrogen atoms). Hydrogen has an approximate Gram Molar Mass (GMM) of 1 each so the H2 molecule has a GMM of 2. Nitrogen atoms has 14 GMM so N2 is 28 GMM.

The temperature is proportional of the momentum of the particles of gas and momentum is equal to mass times velocity. Hydrogen's mass is significantly (14 times) lower, so the VELOCITY of the molecules must be 14 times faster if the two gasses are held at an equal temperature. So if a rocket engine can make the fuel and oxidizer burn at a given temperature (say 1,000 C), the velocity given by the propellent to the rocket is proportional to the velocity of the ejected propellent. Thus you will get better 'fuel economy' if the GMM mass is low.

In the story "Space Cadet", the rockets in this story stored hydrogen as single atoms. (We don't know how.) The hydrogen was then triggered to combine. This made it really hot, and the exhaust gas had the lowest possible GMM of 2. All the demands of the story's plot would work if this type of fuel was available.

This makes hydrogen, H2, with a GMM of 2 an ideal propellent. However, it is not very dense, so rockets must have huge tanks to hold a lot of hydrogen, so the mass of these tanks make hydrogen less attractive. Hydrogen liquid is more dense, but it has a VERY low boiling point and the insulation to keep it cold adds to the mass of the rocket. Hydrogen is not space storable (heat leaks in and boils the liquid hydrogen) which is vented and wasted. And of course, we can't store single hydrogen atoms, so the H2, must burn with (say) O2 to produce heat.

Some examples: The most energy can be made by burning 2 hydrogen atoms for each oxygen to produce H2O (water steam) and a lot of heat. If you have extra hydrogen OR extra oxygen, some of the fuel or oxidizer is wasted and the flame is a bit cooler. But the Space Shuttle's main engines ran hydrogen rich. It was basically having hydrogen rich steam as its outflow gas. The reason for this was two fold. First, the flame temperature was a bit cooler, which is important for a reusable engine. Second the GMM of the output gas was a significantly lower which improved the efficiency of the rocket.

Another example: Let us say that you have two gasses in your atmosphere, H2 and CO2. The gasses are at a given temperature at the top of the planet's atmosphere. H2 has a GMM of 2, and CO2 has one of 44 grams per mole. At the edge of space, on average, the hydrogen is travelling 22 times faster than the CO2. Some proportion of the hydrogen will be travelling faster than the escape velocity, while virtually none of the carbon dioxide will be. So hydrogen gas is slowly lost from terrestrial planets, while almost no CO2 will be. See atmospheric loss for more details.

Another example: noble gases do not chemically combine. So a particle (molecule) of hydrogen gas H2 is made up of 2 atoms, where as noble gasses have only a single atom. He gas has an excellent GMM of 4, and Ne has 20 grams per mole. These noble gasses are easily ionized so Helium would make a great propellent for an ion thruster. Electric fields can accelerate ions to VERY high velocities. However, He and Ne are rare and expensive, so argon (Ar) with a GMM of 40 is sometimes used instead. The larger atoms can lose multiple electrons which allows the electro static field can throw the gas harder (that is to say faster) than if it had just a single ionized electron. Thus the higher GMM of the argon atoms is made up for the very high velocity of the exhaust particles. Xenon (131.3 GMM) likewise can lose multiple electrons which makes up for its poorer GMM.


Chemical propulsion

In a chemical rocket, the propellant is the reaction product of the oxidizer and the fuel. Typical liquid combinations are hydrogen and oxygen, methane and oxygen or jet fuel and oxygen, but many mixes are available. Monopropellants are also possible combining both oxidizer and fuel in a single mixtures. Solids can also be used.

Nuclear thermal propulsion

In a nuclear thermal rocket, it is normally hydrogen, since the specific impulse is dependent on the exhaust velocity of the rocket, which is higher for propellants with low molar mass. The reactor core is made as hot as practical, and then the low GMM of the hydrogen most efficiently turns that heat into thrust.

Nuclear or Solar Electric propulsion

For Ion thrusters, an easily ionized gas is preferred. Vaporized liquid metals are good candidates. As for nuclear rockets, the lower the molar mass the higher the exhaust velocity. However, as electric engines work on ionized gases, the ionization energy of the propellant adds complexity to the engine and favors elements that are easy to ionize. The nobles gases, such as Argon, Neon Krypton and Xenon are all usable, with Xenon achieving the best propulsion properties for many missions.

Other types of propulsion

A laser ablation rocket will tend to use a combination of metal and plastic (due to their optical properties).

A cold gas thruster will use compressed gas to feed small thrusters used for maneuvering. The propellant is usually nitrogen.

A steam powered rocket uses the expansion of water into steam to provide thrust. Water is the only propellant involved. The energy can come from a nuclear reactor or solar concentrators.

Mass drivers can use magnetic fields to projects magnetically suspended propellant masses to propel a vehicle, or alternatively use some form of mass driver to capture high velocity mass sent from another mass driver. The second form of mass driver can sidestep the rocket equation and can be seen as a form of externally powered propulsion.

Propellant production on Mars

On Mars, propellant can be produced in-situ from water and/or CO2. Argon and other noble gases from the atmosphere could be used for NEP or SEP.