In emission spectra `n_(2) to ,n_(3) to n_(1) n_(4) to n_(1) ,n_(5) to n_(1)` tansition are respectively for energy `E_(1) ,E_(2) ,E_(3) ,E_(4) ` So what is the order of energy ?

Let E_(1), E_(2), E_(3), ....,E_(n) be independent events with respective probabilities p_(1), p_(2), p_(3), ....,p_(n) . The probability that none of them occurs is ……….

Find the integral solution for n_(1)n_(2)=2n_(1)-n_(2), " where " n_(1),n_(2) in "integer" .

Let n_(p) and n_(e) be the number of holes and conduction electrons respectively in a semiconductor. Then

Three perfect gases at absolute temperature T_(1), T_(2) and T_(3) are mixed. The masses f molecules are m_(1), m_(2) and m_(3) and the number of molecules are n_(1), n_(2) and n_(3) respectively. Assuming no loss of energy, the final temperature of the mixture is

Prove that .^(n-1)C_(3)+.^(n-1)C_(4) gt .^(n)C_(3) if n gt 7 .

If N_(t) = N_(o)e^(lambdat) then number of disintefrated atoms between t_(1) to t_(2) (t_(2) gt t_(1)) will ve :-

For all ngt=1 , prove that , (1)/(1.2) + (1)/(2.3) + (1)/(3.4) + ……+ (1)/(n(n+1)) = (n)/(n+1)