Difference between revisions of "Annihilation"
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==Key Stage 5== | ==Key Stage 5== | ||
===Meaning=== | ===Meaning=== | ||
− | '''Annihilation''' is the process in which [[matter]] and [[antimatter]] interact converting all their [[Rest Mass|rest mass]] into [[energy]] resulting in | + | '''Annihilation''' is the process in which [[matter]] and [[antimatter]] interact converting all their [[Rest Mass|rest mass]] into [[energy]] resulting in two or more [[Gamma-ray|gamma ray]] [[photon]]s being emitted in opposite directions. |
===About Annihilation=== | ===About Annihilation=== | ||
− | + | *'''Annihilation''' occurs when [[particle]]s of [[matter]] and [[antimatter]] interact at extremely close range. | |
− | + | *Follows the principle of [[Mass-Energy Equivalence|mass-energy equivalence]] (E=mc²). | |
− | + | *Results in the production of [[Gamma-ray|gamma rays]] or other [[Subatomic Particle|particles]]. However, for a-level physics, you only need to consider the special case of 2 [[Gamma-ray|gamma ray]] [[photon]]s being [[emit]]ted. | |
+ | *During '''annihilation''' the total [[Rest Mass|rest mass]], as well as the [[Kinetic Energy|kinetic energy]], of the [[particle]]s before the event is equal to the total [[energy]] of the products (two [[Gamma-ray|gamma ray]] [[photon]]s in a-level physics) after the event. | ||
+ | *In '''annihilation''' [[Conservation of Momentum|conservation of momentum]] is conserved due to the [[momentum]] of the [[Gamma-ray|gamma ray]] [[photon]]s travelling in opposite directions. | ||
+ | |||
+ | *[[Annihilation]] can occur in high-energy environments such as the vicinity of black holes and in particle accelerators. | ||
===Equation=== | ===Equation=== | ||
+ | Assuming both particles are at rest | ||
+ | |||
<math>2E_0 = 2hf</math> | <math>2E_0 = 2hf</math> | ||
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<math>E_0</math> = Rest Mass Energy of each particle | <math>E_0</math> = Rest Mass Energy of each particle | ||
− | <math>hf</math> = The [[energy]] of | + | <math>hf</math> = The [[energy]] of each[[Gamma-ray|gamma ray]] [[photon]] emitted |
<math>h</math> = [[Planck's Constant]] | <math>h</math> = [[Planck's Constant]] | ||
<math>f</math> = The [[frequency]] of the emitted [[photon]] | <math>f</math> = The [[frequency]] of the emitted [[photon]] | ||
+ | |||
+ | |||
+ | In the special case that one of the particles is in motion | ||
+ | |||
+ | <math>2E_0 + E_k = 2hf</math> | ||
+ | |||
+ | Where | ||
+ | |||
+ | <math>E_k</math> = The [[Kinetic Energy|kinetic energy]] of the particle | ||
+ | |||
+ | ===Examples=== | ||
+ | |||
+ | *[[Positron Emission Tomorgraph|Positron emission tomography]] ([[Positron Emission Tomography|PET]]) scans detect [[Gamma-ray|gamma rays]] from [[electron]]-[[positron]] [[annihilation]]. | ||
+ | *[[Particle Accelerator|Particle accelerators]] study [[annihilation]] events to understand [[Fundamental Particle|fundamental particles]]. |
Latest revision as of 19:11, 19 May 2024
Contents
Key Stage 5
Meaning
Annihilation is the process in which matter and antimatter interact converting all their rest mass into energy resulting in two or more gamma ray photons being emitted in opposite directions.
About Annihilation
- Annihilation occurs when particles of matter and antimatter interact at extremely close range.
- Follows the principle of mass-energy equivalence (E=mc²).
- Results in the production of gamma rays or other particles. However, for a-level physics, you only need to consider the special case of 2 gamma ray photons being emitted.
- During annihilation the total rest mass, as well as the kinetic energy, of the particles before the event is equal to the total energy of the products (two gamma ray photons in a-level physics) after the event.
- In annihilation conservation of momentum is conserved due to the momentum of the gamma ray photons travelling in opposite directions.
- Annihilation can occur in high-energy environments such as the vicinity of black holes and in particle accelerators.
Equation
Assuming both particles are at rest
\(2E_0 = 2hf\)
Where
\(E_0\) = Rest Mass Energy of each particle
\(hf\) = The energy of eachgamma ray photon emitted
\(h\) = Planck's Constant
\(f\) = The frequency of the emitted photon
In the special case that one of the particles is in motion
\(2E_0 + E_k = 2hf\)
Where
\(E_k\) = The kinetic energy of the particle
Examples
- Positron emission tomography (PET) scans detect gamma rays from electron-positron annihilation.
- Particle accelerators study annihilation events to understand fundamental particles.