The number of the radioactive atoms that would remain after a decay period of 10 days , which have a half-life of 2 .0 days is to be determined. Concept introduction: The half-life of a substance is the numerical value in which the given radioactive substance is assumed to be reduced to half of its initial number. The half-life for a given substance is represented by t 1/2 . In case, the decay of a radioactive substance is exponential, it will remain constant for the life time of the substance. After each half-life period, the amount of the substance is reduced to half of the initial number. The amount (for example say number of atoms) of the substance left after the half-life period can be calculated using the formula mentioned below: ln ( N t N 0 ) = − kt In the above equation, ‘N t ’ represents the mass of the radioactive substance after a certain time interval t, ‘N 0 ’ indicates the initial mass of the radioactive material, ‘k’ represents the decay constant and ‘t’ represents the time interval for the half-life (t 1/2 ).

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Chapter 17, Problem 69E

Interpretation Introduction

Interpretation:

The number of the radioactive atoms that would remain after a decay period of 10 days, which have a half-life of 2.0 days is to be determined.

Concept introduction:

The half-life of a substance is the numerical value in which the given radioactive substance is assumed to be reduced to half of its initial number. The half-life for a given substance is represented by t_1/2.

In case, the decay of a radioactive substance is exponential, it will remain constant for the life time of the substance.

After each half-life period, the amount of the substance is reduced to half of the initial number.

The amount (for example say number of atoms) of the substance left after the half-life period can be calculated using the formula mentioned below:

ln(NtN0)=−kt

In the above equation, ‘N_t’ represents the mass of the radioactive substance after a certain time interval t, ‘N₀’ indicates the initial mass of the radioactive material, ‘k’ represents the decay constant and ‘t’ represents the time interval for the half-life (t_1/2).

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