Alpha decay: Difference between revisions
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== Alpha Decay == | |||
'''Alpha decay''' is a type of radioactive decay in which an atomic nucleus emits an [[alpha particle]] and thereby transforms into a different nucleus with a mass number reduced by four and an atomic number reduced by two. This process is a common mode of decay for heavy [[nuclei]], such as those of [[uranium]], [[thorium]], and [[radium]]. | |||
=== Mechanism === | |||
In alpha decay, the parent nucleus ejects an alpha particle, which consists of two protons and two neutrons, equivalent to a [[helium]]-4 nucleus. The emission of the alpha particle results in the formation of a daughter nucleus that is lighter and has a lower atomic number. For example, when uranium-238 undergoes alpha decay, it transforms into thorium-234: | |||
: \( ^{238}_{92}U \rightarrow ^{234}_{90}Th + ^{4}_{2}He \) | |||
The process of alpha decay is governed by the [[quantum tunneling]] effect, where the alpha particle overcomes the nuclear potential barrier despite not having enough energy to do so classically. | |||
=== Energy Release === | |||
The energy released during alpha decay is primarily carried away by the kinetic energy of the alpha particle. This energy is typically in the range of 4 to 9 [[MeV]] (million electron volts). The energy release is a result of the difference in binding energy between the parent and daughter nuclei. | |||
=== Half-Life === | |||
The half-life of a radioactive isotope undergoing alpha decay is the time required for half of the sample to decay. This period can vary widely among different isotopes, from microseconds to billions of years. The half-life is a crucial factor in determining the stability and longevity of a radioactive element. | |||
=== Applications === | |||
Alpha decay has several practical applications. It is used in [[smoke detectors]], where the alpha particles ionize air molecules, allowing the detection of smoke particles. Alpha-emitting isotopes are also used in [[radioisotope thermoelectric generators]] (RTGs) to provide power for [[spacecraft]] and remote installations. | |||
=== Health Effects === | |||
While alpha particles are not highly penetrating and can be stopped by a sheet of paper or the outer layer of human skin, they can cause significant damage if alpha-emitting materials are ingested or inhaled. Inside the body, alpha particles can cause severe damage to living cells and tissues, leading to increased risks of [[cancer]] and other health issues. | |||
== Related Pages == | |||
* [[Radioactive decay]] | |||
* [[Beta decay]] | |||
* [[Gamma decay]] | |||
* [[Nuclear physics]] | |||
* [[Radiation]] | |||
{{Nuclear physics}} | |||
{{Radioactivity}} | |||
[[Category:Nuclear physics]] | |||
[[Category:Radioactivity]] | |||
Latest revision as of 00:38, 19 February 2025
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Alpha Decay -
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Alpha Decay[edit]
Alpha decay is a type of radioactive decay in which an atomic nucleus emits an alpha particle and thereby transforms into a different nucleus with a mass number reduced by four and an atomic number reduced by two. This process is a common mode of decay for heavy nuclei, such as those of uranium, thorium, and radium.
Mechanism[edit]
In alpha decay, the parent nucleus ejects an alpha particle, which consists of two protons and two neutrons, equivalent to a helium-4 nucleus. The emission of the alpha particle results in the formation of a daughter nucleus that is lighter and has a lower atomic number. For example, when uranium-238 undergoes alpha decay, it transforms into thorium-234:
- \( ^{238}_{92}U \rightarrow ^{234}_{90}Th + ^{4}_{2}He \)
The process of alpha decay is governed by the quantum tunneling effect, where the alpha particle overcomes the nuclear potential barrier despite not having enough energy to do so classically.
Energy Release[edit]
The energy released during alpha decay is primarily carried away by the kinetic energy of the alpha particle. This energy is typically in the range of 4 to 9 MeV (million electron volts). The energy release is a result of the difference in binding energy between the parent and daughter nuclei.
Half-Life[edit]
The half-life of a radioactive isotope undergoing alpha decay is the time required for half of the sample to decay. This period can vary widely among different isotopes, from microseconds to billions of years. The half-life is a crucial factor in determining the stability and longevity of a radioactive element.
Applications[edit]
Alpha decay has several practical applications. It is used in smoke detectors, where the alpha particles ionize air molecules, allowing the detection of smoke particles. Alpha-emitting isotopes are also used in radioisotope thermoelectric generators (RTGs) to provide power for spacecraft and remote installations.
Health Effects[edit]
While alpha particles are not highly penetrating and can be stopped by a sheet of paper or the outer layer of human skin, they can cause significant damage if alpha-emitting materials are ingested or inhaled. Inside the body, alpha particles can cause severe damage to living cells and tissues, leading to increased risks of cancer and other health issues.
Related Pages[edit]
| Nuclear physics |
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| Radioactivity | ||||||||||
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This radioactivity-related article is a stub.
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