(a) Find the maximum wavelength `lambda_90)` of light which can ionize a hydrogen atom in its ground (b) light of wavelength `lambda_(0)` is inclined on ahydrogen atom which is in its first excited state find the kinrtic energy of the electron coming out

The first excited state of hydrogen atom is 10.2 eV above its ground state. The temperature is needed to excite hydrogen atoms to first excited level is

To excite the hydrogen atom from its ground state to second excited state…. eV energy is required.

An electron, in a hydrogen like atom , is in excited state. It has a total energy of -3.4 eV , find the de-Broglie wavelength of the electron.

Hydrogen atom from excited state comes to the ground state by emitting a photon of wavelength lamda , then what is the quantum number of excited states ?

The ground state energy of hydrogen atom is - 13.6 eV. When electron is in excited state its excitation energy is ......

The potential energy of the orbital electron in the ground state of hydrogen atom is -E What is its kinetic energy ?-

A prism of refractive index n_(1) & another prism of reactive index n_(2) are stuck together without a gap as shown in the figure.The angle of the prisms are as shown. n_(1)&n_(2) depend on lambda ,the wavelength of light according to n_(1)=1.20+(10.8xx10^(4))/(lambda^(2)) & n_(2)=1.45+(1.80xx10^(4))/(lambda^(2)) where lambda is in nm. (i)Calculate the wavelength lambda_(0) for which rays incident at any angle on the interface BC pass through without bending at that interface. (ii) for light of wavelength lambda_(0) ,find the angle of incidencei on face AC such that the deviation produced by the combination of prism is minimum.

The time period of revolution of an electron in its ground state orbit in a hydrogen atom is 1.6xx10^(-16) s. The frequency of the electron in its first excited state (in s^(-1) ) is :