Difference between revisions of "Beta-Plus Radiation"
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===About Beta-Plus Radiation=== | ===About Beta-Plus Radiation=== | ||
*[[Beta-Plus Radiation|Beta-plus radiation]] is [[emit]]ted during beta-plus [[Radioactive Decay|decay]] when a [[proton]] [[Transmutation|transmutes]] into a [[neutron]], [[positron]], and [[neutrino]]. | *[[Beta-Plus Radiation|Beta-plus radiation]] is [[emit]]ted during beta-plus [[Radioactive Decay|decay]] when a [[proton]] [[Transmutation|transmutes]] into a [[neutron]], [[positron]], and [[neutrino]]. | ||
| − | *[[ | + | *[[Beta-Plus Radiation|Beta-plus radiation]] travels no further than about 2 mm in [[solid]]s or [[liquid]]s before being [[Annihilation|annihilated]]. |
| − | *[[ | + | *[[Beta-Plus Radiation|Beta-plus]] [[Emit|emission]] results from [[proton]] to [[neutron]] conversion in the [[Atomic Nucleus|nucleus]]. |
*Produces [[Gamma-ray|gamma rays]] upon [[annihilation]] with [[electron]]s. | *Produces [[Gamma-ray|gamma rays]] upon [[annihilation]] with [[electron]]s. | ||
| − | *[[ | + | *The [[positron]]s that make up [[Beta-Plus Radiation|beta-plus radiation]] are the [[antimatter]] counterparts of [[electron]]s. |
*[[Beta-Plus Radiation|Beta-plus radiation]] helps in studying nuclear structures and particle interactions. | *[[Beta-Plus Radiation|Beta-plus radiation]] helps in studying nuclear structures and particle interactions. | ||
| + | |||
===Examples=== | ===Examples=== | ||
*Used in [[PET Scan|Positron Emission Tomography (PET scans)]] for medical imaging. | *Used in [[PET Scan|Positron Emission Tomography (PET scans)]] for medical imaging. | ||
*Studied in [[Particle Physics|particle physics]] to understand [[antimatter]]. | *Studied in [[Particle Physics|particle physics]] to understand [[antimatter]]. | ||
Latest revision as of 12:47, 22 May 2024
Key Stage 5
Meaning
Beta-plus radiation consists of positrons (β⁺) emitted by unstable proton-rich nuclei.
About Beta-Plus Radiation
- Beta-plus radiation is emitted during beta-plus decay when a proton transmutes into a neutron, positron, and neutrino.
- Beta-plus radiation travels no further than about 2 mm in solids or liquids before being annihilated.
- Beta-plus emission results from proton to neutron conversion in the nucleus.
- Produces gamma rays upon annihilation with electrons.
- The positrons that make up beta-plus radiation are the antimatter counterparts of electrons.
- Beta-plus radiation helps in studying nuclear structures and particle interactions.
Examples
- Used in Positron Emission Tomography (PET scans) for medical imaging.
- Studied in particle physics to understand antimatter.