Calculate the wavelength for the emission transition if it starts from the orbit having radius `1.3225 nm` ends at `211.6 p m`. Name the series to which this transition belongs and the region of the spectrum.

What would be the wavelength and name of series respectively for the emission transition for H-atom if it starts from the orbit having radius 1.3225 nm and ends at 211.6 pm?

Emission transition in the Paschen series end at orbit n=3 and start from orbit n and can be represented as v=3.29 xx 10^(15) (Hz) [1//3^2-1//n^2] Calculate the value of n if the transition is observed at 1285nm Find the region of the spectrum.

Emission transitions in the Paschen series end at orbit n=3 and start from orbit n and can be represented as v=3.29xx10^(15) (Hz)[1//3^(2)-1//n^(2)] Calculate the value of n if the transition is observed at 1285 nm . Find the region of the spectrum.

Hydrogen atom: The electronic ground state of hydrogen atom contains one electron in the first orbit. If sufficient energy is provided, this electron can be promoted to higher energy levels. The electronic energy of a hydrogen-like species (any atom//ions with nuclear charge Z and one electron) can be given as E_(n)=-(R_(H)Z^(2))/(n^(2)) where R_(H)= "Rydberg constant," n= "principal quantum number" Calculate the wavelength of light (nm) for the electronic transition of H-atom from the first excited state to ground state. In the model of hydrogen like atom put forward by Niels Bohr (1913) the electron orbits around the central nucleus. the bohr radius of n^(th) orbit of a hydrogen-like species is given by r= k n^(2)/Z " " where, k is constant

Determine the wavelength of the first Lymanline,the transition from n=2"to"n=1 .In what region of the electromagnetic spectrum does this line lie ?

(i) Which is highest frequency photon that can be emitted from hydrogen atom? What is wavelength of this photon? (ii) Calclate the longest wavelength transition in the Pashen series of He^(+) . (iii) Calculate the ratio of the wavelength of first and the ultimate line of Balmer sereis of Li^(2+) ?

A mu-meson ("charge -e , mass = 207 m, where m is mass of electron") can be captured by a proton to form a hydrogen - like ''mesic'' atom. Calculate the radius of the first Bohr orbit , the binding energy and the wavelength of the line in the Lyman series for such an atom. The mass of the proton is 1836 times the mass of the electron. The radius of the first Bohr orbit and the binding energy of hydrogen are 0.529 Å and 13.6 e V , repectively. Take R = 1.67 xx 109678 cm^(-1)

The electron in the hydrogen atom undergoes transition from higher orbitals to orbital of radius 211.6 pm. This transition is associated with:

The electon, in a hydrogen atom, is in its second excited state. Calculate the wavelength of the lines in the Lyman series, that can be emitted through the permisible transitions of this electron. Given the value of Rydberg constant, R=1.1xx10^(7)m^(-1))

In hydrogen spectrum L_(alpha) line arises due to transition of electron from the orbit n=3 to the orbit n=2. In the spectrum of singly ionized helium there is a line having the same wavelength as that of the L_(alpha) line. This is due to the transition of electron from the orbit: