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The ground state energy of hydrogen atom is $- 13.6 eV$ . Where its electron is in the first excited state, its excitation energy is

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Important Questions on Atoms

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

To calculate the size of a hydrogen anion using the Bohr model, we assume that its two electrons move in an orbit such that they are always on diametrically opposite sides of the nucleus. With each electron having the angular momentum,

♄ = \frac{h}{2 π},

and taking electron interaction into account the radius of the orbit in terms of the Bohr radius of a hydrogen atom

a_{B} = \frac{4 π ε_{0} h^{2}}{m e^{2}}

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

A hydrogen atom is in the ground state. Then to get six lines in an emission spectrum, wavelength of the incident radiation should be

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

The magnitude of acceleration of the electron in the $n^{th}$ orbit of hydrogen atom is $a_{H}$ and that of singly ionised helium atom is $a_{He}$ . The ratio $a_{H} : a_{He}$ is,

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

The ratio of radii of the first three Bohr's orbits is

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

A particle of mass

m

moves in a circular orbit in a central potential field

U (r) = \frac{1}{2} k r^{2} .

If Bohr's quantization conditions are applied, radii of possible orbitals and energy levels vary with quantum number

n

as:

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

Both the nucleus and the atom of some element are in their respective first excited states. They get de-excited by emitting photons of wavelengths

λ_{N}, λ_{A}

respectively. The ratio

\frac{λ_{N}}{λ_{A}}

is closest to:

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

A particle of mass,

m

moves around the origin in a potential,

\frac{1}{2} m ω^{2} r^{2}

, where

r

is the distance from the origin. Applying the Bohr model in this case, the radius of the particle in its

n^{th}

orbit in terms of

a = \sqrt{\frac{h}{(2 π m ω)}}

is,

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

According to Bohr's theory, the time averaged magnetic field at the centre (i.e., nucleus) of a hydrogen atom due to the motion of electrons in the

n^{t h}

orbit is proportional to: (

n =

principal quantum number)

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

An electron makes a transition from an excited state to the ground state of a hydrogen-like atom. Then

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

In a Frank - Hertz experiment, an electron of energy

5 .6 eV

passes through mercury vapour and emerges with an energy

0 .7 eV .

The minimum wavelength of photons emitted by mercury atoms is close to:

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

If an electron in a hydrogen atom jumps from the third orbit to the second orbit, it emits a photon of wavelength

λ

. When it jumps from the fourth orbit to the third orbit, the corresponding wavelength of the photon will be

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

The energy required to remove the electron from a singly ionized Helium atom is

2.2

times the energy required to remove an electron from helium atom. The total energy required to ionize the Helium atom completely is close to

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

An electron with kinetic energy

E

collides with a hydrogen atom in the ground state. The collision will be elastic

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

Consider third orbit of ${He}^{+}$ (helium), using non-relativistic approach, the speed of electron in this orbit will be given constant $K {=9×10}^{9}$ , $Z =2$ and $h$ (Planck's Constant) $= 6 .6 \times 10^{- 34} J s$

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

An electron in a hydrogen atom jumps from second Bohr orbit to ground state and the energy difference of the two states is radiated in the form of photons. These are then allowed to fall on a metal surface having a work-function equal to

4.2 eV

, then the stopping potential is [Energy of electron in

n^{th}

orbit

= - \frac{13 .6}{n^{2}} eV

]

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

The wavelength of the first Balmer line caused by a transition from the

n = 3

level to the

n = 2

level in hydrogen is

λ_{1} .

The wavelength of the line caused by an electronic transition from

n = 5

n = 3

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

The acceleration of an electron in the first orbit of the hydrogen atom (

n = 1

) is :

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

In a hydrogen like atom electron makes transition from an energy level with quantum number

n

to another with quantum number

(n - 1)

. If

n >> 1

, the frequency of radiation emitted is proportional to :

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

As an electron makes a transition from an excited state to the ground state of a hydrogen-like atom/ion

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Physics>Modern Physics>Atoms>Bohr Model of the Hydrogen Atom

The ratio of kinetic energy to the total energy of an electron in a Bohr orbit of the hydrogen atom is

The ground state energy of hydrogen atom is –13.6 eV. Where its electron is in the first excited state, its excitation energy is

Important Questions on Atoms

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The ground state energy of hydrogen atom is $- 13.6 eV$ . Where its electron is in the first excited state, its excitation energy is