Advertisements
Advertisements
प्रश्न
Calculate the wavelength for the first three lines in the Paschen series.
(Given RH =1.097 ×107 m-1)
उत्तर
Given:
RH = 1.097 × 107 m−1,
For Paschen series, n = 3,
To find: Wavelength of first three lines of Paschen series
Formula:
For the Paschen series, `1/lambda = "R"_"H"(1/3^2 - 1/"m"^2)`
Calculation:
For the first line of the Paschen series,
From the formula,
`1/lambda = 1.097 xx 10^7 (1/3^2 - 1/4^2)`
= `1.097 × 10^7 × (7/(9 xx 16))`
= 0.05333 × 107 m−1
Using the reciprocal table,
λ1 = 1.876 × 10−6 m
For the second line of the Paschen series,
From formula,
`1/lambda_2 = 1.097 xx 10^7 (1/3^2 - 1/5^2)`
`= 1.097 × 10^7 × (16/(9 xx 25))`
= 0.075 × 107 m−1
Using the reciprocal table,
λ2 = 1.282 × 10−6 m
For the third line of the Paschen series,
From formula,
`1/lambda_3 = 1.097 xx 10^7 (1/3^2 - 1/6^2)`
= `1.097 xx 10^7 xx (27/(9 xx 36))`
= 0.0914 × 107 m−1
Using the reciprocal table,
`lambda_3` = 1.094 × 10-6 m
The wavelength of the first three lines of the Paschen series is 1.876 × 10−6 m, 1.282 × 10−6 m, 1.094 × 10-6 m, respectively.
APPEARS IN
संबंधित प्रश्न
For the hydrogen atom, the minimum excitation energy ( of n =2) is ______
The linear momentum of the particle is 6.63 kg m/s. Calculate the de Broglie wavelength.
State any two limitations of Bohr’s model for the hydrogen atoms.
Derive an expression for the radius of the nth Bohr orbit for the hydrogen atom.
Calculate the shortest wavelength in the Paschen series if the longest wavelength in the Balmar series is 6563 Ao.
How the linear velocity 'v' of an electron in the Bohr orbit is related to its quantum number 'n'?
When the electron in hydrogen atom jumps from fourth Bohr orbit to second Bohr orbit, one gets the ______.
How many moles of electrons are required for reduction of 9 moles of Cr3+ to Cr?
If the ionisation potential of helium atom is 24.6 volt, the energy required to ionise it will be ____________.
What is the de Broglie wavelength of an electron of energy 180 eV?
(Mass of electron = 9 x 10-31 kg and Planck's constant = 6.6 x 10-34 Js.)
The total energy of an electron in an atom in an orbit is -3.4 eV. Its kinetic and potential energies are, respectively ______.
If m is mass of electron, v its velocity, r the radius of stationary circular orbit around a nucleus with charge Ze, then from Bohr's second postulate, the kinetic energy `"K.E." = 1/2"mv"^2` of the electron in C.G.S. system is 2 equal to ____________.
Which of the following models was successful in explaining the observed hydrogen spectrum?
When an electron in hydrogen atom is excited from its 3rd to 5th stationary orbit, tbe change in angular momentum of electron is (Planck's constant: h = 6.62 x 10-34 Js) ____________.
Angular speed of an electron in the ground state of hydrogen atom is 4 × 1016 rad/s. What is its angular speed in 4th orbit?
In Bohr model, speed of electron in nth orbit of hydrogen atom is ______. (b = Planck's constant, n = principal quantum number, ∈0 is the permittivity of free space, e = electronic charge)
If a charge on the body is 1 nC, then how many electrons are present on the body?
If n is principal quantum number and r is the radius of the orbit in which electron revolves around nucleus, then its kinetic energy is ____________.
Using Bohr's quantization condition, what is the rotational energy in the second orbit for a diatomic molecule. (I = moment of inertia of diatomic molecule, h = Planck's constant)
Electron in Hydrogen atom first jumps from third excited state to second excited state and then from second excited state to first excited state. The ratio of the wavelengths λ1 : λ2 emitted in the two cases respectively is ______.
The electron of mass 'm' is rotating in first Bohr orbit of radius 'r' in hydrogen atom. The orbital acceleration of the electron in first orbit is ______.
(b =Planck's constant)
The relation between magnetic moment of revolving electron 'M' and principle quantum number 'n' is ______.
The triply ionised beryllium (Be+++) has the same electron orbital radius as that of the ground state of the hydrogen atom. The energy state (n) of triply ionised beryllium is ______.
(Z for beryllium = 4)
Ultraviolet light of wavelength 300 nm and intensity 1.0 Wm−2 falls on the surface of a photosensitive material. If one percent of the incident photons produce photoelectrons, then the number of photoelectrons emitted from an area of 1.0 cm2 of the surface is nearly ______.
Calculate the radius of the first Bohr orbit in the hydrogen atom.
What is the origin of spectral lines? Obtain an expression for the wave number of a line in hydrogen spectrum.
