If `lambda_1` and `lambda_2` are the maximum wavelength limits of Lyman and Balmer sereis of `H_2` atom, `lambda_1//lambda_2` will be

If lambda_1 and lambda_2 are the wavelengths of the first member of the Lyman and Paschen series respectively, then lambda_1 : lambda_2 is

If lambda_(1) and lambda_(2) are the wavelengths of the first members of the Lyman and Paschen series respectively, then lambda_(1) : lambda_(2) is

If alpha, beta are the roots of the equation λ (x^(2)-x)+x+5=0 and if lambda_1 and lambda_2 are two values of lambda obtained from (alpha)/(beta)+(beta)/(alpha)=(4)/(5) , then (lambda_(1))/(lambda_(2)^(2))+(lambda_(2))/(lambda_(1)^(2))=

The Rydberg constant for hydrogen is 1.097 X 10^(7) ms^(-1) . Calculate the short and long wavelength limits of Lyman series. Data: R=1.097xx10^(7)ms^(-1) For short wavelength limit of Lyman Series, n_(f)=1,n_(i)=oo, lambda_(s)=? For long wavelength limit of Lyman series, n_(f)=1, n_(i)=2, lambda_(i)=?

In Youngs double slit experiment the 7th maximum with wavelength lambda_1 is at a distance d_1 and that with wavelength lambda_2 is at distance d_2 . Then d_1//d_2=

If alpha , beta are the roots of lambda(x^(2)+x)+x+5 =0 and lambda_(1) , lambda_(2) are the two values of lambda for which alpha , beta are connected by the relation (alpha)/(beta)+(beta)/(alpha) =4, then the value of (lambda_(1))/(lambda_(2))+(lambda_(2))/(lambda_(1)) =