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{{dambigbox|decomposition|Half-life}}
{{dambigbox|decomposition|Half-life}}


For any reactant subject to first-order decomposition, the amount of time needed for one half of the substance to decay is referred to as the '''half-life''' of that compound. Although the term is often associated with [[radioactive decay]], it also applies equally to chemical decomposition, such as the decomposition of [[azomethane]] (CH<sub>3</sub>N=NCH<sub>3</sub>) into methane and nitrogen gas. Many compounds decay so slowly that it is impractical to wait for half of the material to decay to determine the half-life. In such cases, a convenient fact is that the half-life is 693 times the amount of time required for 0.1% of the substance to decay. Using the value of the half-life of a compound, one can predict both future and past quantities.
For any reactant subject to first-order decomposition, the amount of time needed for one half of the substance to decay is referred to as the '''half-life''' of that compound. Although the term is often associated with [[radioactive decay]], it also applies equally to chemical decomposition, such as the decomposition of [[azomethane]] (CH<sub>3</sub>N=NCH<sub>3</sub>) into methane and nitrogen gas. Many compounds decay so slowly that it is impractical to wait for half of the material to decay to determine the half-life. In such cases, a convenient fact is that the half-life is 693 times the amount of time required for 0.1% of the substance to decay. Using the value of the half-life of a compound, one can predict both future and past quantities.
 
Note: The approximation <math> \ \ln(2) \approx 0.693 \ </math> is used in this article.  


== Mathematics ==
== Mathematics ==


The future concentration of a substance, C<sub>1</sub>, after some passage of time <math>\Delta</math>T, can easily be calculated if the present concentration, C<sub>0</sub>, and the half-life, T<sub>h</sub>, are known:
The future [[concentration]] of a substance, ''C''<sub>1</sub>, after some passage of time <math>\Delta t</math>, can easily be calculated if the present concentration ''C''<sub>0</sub> and the half-life ''t<sub>h</sub>'' are known:
 
:<math>C_1 = C_0 \left(\frac{1}{2}\right)^\frac{\Delta t}{t_h}</math>
 
For a reaction is the first-order for a particular reactant A, and first-order overall, the chemical rate constant for the reaction ''k'' is related to the half-life by this equation:
 
:<math>t_h = \frac{0.693}{k}</math>
 
== Average Lifetime ==
 
For a substance undergoing exponential decay, the ''average'' lifetime ''t<sub>avg</sub>'' of the substance is related to the half-life via the equation


:<math>C_1 = C_0 \left(\frac{1}{2}\right)^\frac{\Delta_T}{T_h}</math>
:<math>t_{avg} = 0.693 \ t_h</math>.


For a reaction is the first-order for a particular reactant, A, and first-order overall, the chemical rate constant for the reaction, k, is related to the half-life T<sub>h</sub> by this equation:
The average lifetime arises when using the number ''e'', rather than 1/2, as the base value in an exponential decay equation:


:<math>T_h = \frac{0.693}{k}</math>
:<math>C_1 = C_0 \ e^{-\frac{\Delta t}{t_{avg}}}</math>[[Category:Suggestion Bot Tag]]

Latest revision as of 06:00, 25 August 2024

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This editable Main Article is under development and subject to a disclaimer.
This article is about decomposition. For other uses of the term Half-life, please see Half-life (disambiguation).

For any reactant subject to first-order decomposition, the amount of time needed for one half of the substance to decay is referred to as the half-life of that compound. Although the term is often associated with radioactive decay, it also applies equally to chemical decomposition, such as the decomposition of azomethane (CH3N=NCH3) into methane and nitrogen gas. Many compounds decay so slowly that it is impractical to wait for half of the material to decay to determine the half-life. In such cases, a convenient fact is that the half-life is 693 times the amount of time required for 0.1% of the substance to decay. Using the value of the half-life of a compound, one can predict both future and past quantities.

Note: The approximation is used in this article.

Mathematics

The future concentration of a substance, C1, after some passage of time , can easily be calculated if the present concentration C0 and the half-life th are known:

For a reaction is the first-order for a particular reactant A, and first-order overall, the chemical rate constant for the reaction k is related to the half-life by this equation:

Average Lifetime

For a substance undergoing exponential decay, the average lifetime tavg of the substance is related to the half-life via the equation

.

The average lifetime arises when using the number e, rather than 1/2, as the base value in an exponential decay equation: