A Hall effect thruster (HET) is a type of electric propulsion system used in spacecraft propulsion. It operates on the principle of the Hall effect, which is a phenomenon observed when an electric current flows through a conductor placed in a magnetic field. The Hall effect causes the flow of charged particles to deviate in a specific direction, which can be harnessed for propulsion.
Here's how a Hall effect thruster works:
Basic setup: The Hall effect thruster consists of three main components: the discharge chamber, the magnetic field system, and the exhaust nozzle.
Ionization: A propellant gas, typically xenon, is injected into the discharge chamber. Inside the chamber, electrons are emitted by a cathode and accelerated towards an anode. The accelerated electrons collide with the propellant atoms, ionizing them by removing one or more electrons. This results in the creation of positively charged ions and negatively charged electrons.
Magnetic field: A magnetic field is generated in the thruster by a set of magnets or electromagnets. This magnetic field is oriented perpendicular to the direction of the ion flow.
Hall effect: Due to the magnetic field and the flow of charged particles, the Hall effect comes into play. The Lorentz force, which is the force experienced by a charged particle moving in a magnetic field, acts on the charged ions created in the ionization process. The Lorentz force causes the ions to move in a spiraling path around the magnetic field lines.
Acceleration and exhaust: The positively charged ions, now spiraling in the magnetic field, are accelerated by an electric field towards the thruster's exit orifice. As they leave the thruster, they pass through a narrow throat, which further accelerates them to high velocities.
Exhaust velocity: The Hall effect thruster is capable of achieving very high exhaust velocities, typically in the range of tens of kilometers per second. This high exhaust velocity results in a high specific impulse, which is a measure of the propulsion efficiency.
Electric power: The Hall effect thruster requires electric power to ionize the propellant gas and produce the magnetic field. This power is typically provided by onboard solar panels or nuclear power sources.
Continuous operation: Hall effect thrusters are generally capable of continuous operation and are used for long-duration missions, such as station-keeping for satellites or interplanetary spacecraft propulsion.
The Hall effect thruster is valued for its high specific impulse, which allows spacecraft to achieve significant velocity changes with a relatively small amount of propellant. However, it produces relatively low thrust compared to chemical rockets, so it is more suitable for missions that require efficiency and steady acceleration over long periods rather than rapid acceleration.