Statement-1: After ten half life lives, the amount of a radioactive element reduces to about `1//1000` part.
Statement-2: `N=N_(0)(1/2)^(n)=N_(0)(1/2)^(10)`
`=(N_(0))/1024 ~~(N_(0))/1000`

Statement-1: Half life of tritium is 12.5 yr. The fraction of tritium that remains after 50 yr is 6.25% Statement-2: N/(N_(0))=(1/2)^(n)=(1/2)^(t//T) =(1/2)^(12.5//50) =1/16=6.25% .

Statement-1: Half life of a certain radioactive element is 100 days . After 200 days , fraction left undecayed will be 25% . Statement-2: (N)/(N_(0)=((1)/(2))^(n) , where symbols have standard meaning.

Radioactive decay follows first-order kinetic. The mean life and half-life of nuclear decay process are tau = 1// lambda and t_(1//2) = 0.693//lambda . Therefore are a number of radioactive elements in nature, their abundance is directly proportional to half life. The amount remaining after n half lives of radioactive elements can be calculated using the relation: N = N_(0) ((1)/(2))^(n) Amount of radioactive elements (activity) decreases with passage of time as

Radioactive decay follows first-order kinetic. The mean life and half-life of nuclear decay process are tau = 1// lambda and t_(1//2) = 0.693//lambda . Therefore are a number of radioactive elements in nature, their abundance is directly proportional to half life. The amount remaining after n half lives of radioactive elements can be calculated using the relation: N = N_(0) ((1)/(2))^(n) Which "is"//"are" true about the decay cosntant?

Radioactive decay follows first-order kinetic. The mean life and half-life of nuclear decay process are tau = 1// lambda and t_(1//2) = 0.693//lambda . Therefore are a number of radioactive elements in nature, their abundance is directly proportional to half life. The amount remaining after n half lives of radioactive elements can be calculated using the relation: N = N_(0) ((1)/(2))^(n) Half life of .^(60)Co is 5.3 years, the time taken for 99.9% decay will be

Radioactive decay follows first-order kinetic. The mean life and half-life of nuclear decay process are tau = 1// lambda and t_(1//2) = 0.693//lambda . Therefore are a number of radioactive elements in nature, their abundance is directly proportional to half life. The amount remaining after n half lives of radioactive elements can be calculated using the relation: N = N_(0) ((1)/(2))^(n) The rate of radioactive decay is

Radioactive decay follows first-order kinetic. The mean life and half-life of nuclear decay process are tau = 1// lambda and t_(1//2) = 0.693//lambda . Therefore are a number of radioactive elements in nature, their abundance is directly proportional to half life. The amount remaining after n half lives of radioactive elements can be calculated using the relation: N = N_(0) ((1)/(2))^(n) Select the correct relation.

Statement 1: If is a sequence such that a_(1)=1 and a_(n+1)=sin a_(n), then lim_(n rarr oo)a_(n)=0. Statement 2:sin cex>sin x AA x>0

If N_(0) =1 gm then after how many half lives N t will be 0.25 gm ?

Prove that ^nC_(0)^(n)C_(0)-^(n+1)C_(1)^(n)C_(1)+^(n+2)C_(2)^(n)C_(2)-...=(-1)^(n)