From the given details of the rock, age of the rock should be determined. Concept Introduction: Unstable nuclei emit radiation spontaneously to become stable nuclei by losing energy. This process of emission of radiation by unstable nuclei is known as radioactive decay. These emitted radiations may be alpha radiations( α ), beta radiations( β ) or gamma radiations( γ ) These unstable nuclei are the nuclei with more than 83 protons and which do not lie within the belt of stability. Radioactive decay are in the first order kinetics. Rate of radioactive decay at a time t is, R a t e o f d e c a y a t a t i m e ' t ' = k N k- First order rate constant and its unit is t − 1 N- number of radioactive nuclei present at time 't Suppose the number of radioactive nuclei at time zero is N 0 and at a time t is N t , l n N t N 0 = - k t Half-life of radioactive decay is the time required for a radioactive sample to decay to one half of the atomic nucleus. Half-life of the radiation, t 1 / 2 = 0 . 6 9 3 k Half-life and rate constant for radioactive isotopes vary greatly from nucleus to nucleus.

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Chapter 20.3, Problem 20.3.1SR

Interpretation Introduction

Interpretation: From the given details of the rock, age of the rock should be determined.

Concept Introduction:

Unstable nuclei emit radiation spontaneously to become stable nuclei by losing energy. This process of emission of radiation by unstable nuclei is known as radioactive decay.

These emitted radiations may be alpha radiations( α ), beta radiations( β ) or gamma radiations( γ )

These unstable nuclei are the nuclei with more than 83 protons and which do not lie within the belt of stability.

Radioactive decay are in the first order kinetics. Rate of radioactive decay at a time t is,
Rate of decay at a time 't' = k Nk- First order rate constant and its unit is t−1N- number of radioactive nuclei present at time 't

Suppose the number of radioactive nuclei at time zero is N0 and at a time t is Nt ,

ln NtN0 = -kt

Half-life of radioactive decay is the time required for a radioactive sample to decay to one half of the atomic nucleus.
Half-life of the radiation, t1/2= 0.693k

Half-life and rate constant for radioactive isotopes vary greatly from nucleus to nucleus.

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